PHOTOMULTIPLIER TUBESAND ASSEMBLIESPHOTOMULTIPLIER TUBESAND ASSEMBLIES
PHOTOMULTIPLIER TUBES AND ASSEMBLIES
Always been a leader in Photonic Device performance, Hamamatsu has now developed a PMT with a quantum efficiency (QE) of 43%. In all kinds of high-precision light measurements, high sensitivity and high QE are absolutely essential elements in extending detection limits and unlocking new knowledge. For Hamamatsu, however, this 43% QE is just one more step along the road. Aiming for the peak of PMT performance will open up all kinds of new possibilities.
Ultra Bialkali
Super Bialkali
Photomultiplier Tube Series
Hamamatsu"Bialkali Climbing Party"Has Now Reached
"43% QE" !
INTRODUCTION
In radiation measurements, scintillation counters which are combinations of scintillators and photomultiplier tubes are used as most common and useful devices in detecting X-, alpha-, beta-, gamma-rays and other high energy charged particles. A scintillator emits flashes of light in response to input radiations and a photomultiplier tube coupled to a scintillator detects these scintillation lights in a precise way.In high energy physics experiments, one of important apparatuses is a Cherenkov counter in which photomultiplier tubes detect Cherenkov radiations emitted by high energy charged particles passing through a dielectric material.To detect radiations accurately, photomultiplier tubes may be required to have high detecting efficiency (QE & energy resolution), wide dynamic range (pulse linearity), good time resolution (T.T.S.), high stablility & reliability, and to be operatable in high magnet-ic field environment or at high temperature condition. In addition, a ruggedized construction is required according to circumstan-ces. On the other hand, several kinds of position sensitive photomultiplier tubes have been developed and are used in these measurements.This catalog provides a quick reference for Hamamatsu photomultiplier tubes, especially designed or selected for scintillation counters and Cherenkov radiation detectors, and includes most of types currently available ranging in size from 3/8" through 20" in diameter. It should be noted that this catalog is just a starting point in describing Hamamatsu product line since new types are continuously under-development.Please feel free to contact us with your specific requirements.
Photomultiplier Tubesand AssembliesFor Scintillation Counting
and High Energy Physics
TABLE OF CONTENTS
Photomultiplier Tubes PageOperating Characteristics ........................................................................ 2List Guide for Photomultiplier Tubes ..................................................... 18Photomultiplier Tubes ........................................................................... 20Dimensional Outlines and Basing Diagrams for Photomultiplier Tubes ........... 28Typical Gain Characteristics .................................................................. 40Position Sensitive Photomultiplier Tubes .............................................. 44Voltage Distribution Ratios .................................................................... 46
Photomultiplier Tube AssembliesQuick Reference for PMT Hybrid Assemblies .................................... 48Dimensional Outlines and Circuit Diagrams for PMT Hybrid Assemblies ............ 50Quick Reference for PMT Socket Assemblies ..................................... 58Dimensional Outlines and Circuit Diagrams for PMT Socket Assemblies ............. 60
Dimensional Outlines for E678 Series Sockets ..................... 68
Index by Type No. .................................................................... 70
Cautions and Warranty ............................................................ 72
Typical Photocathode Spectral Response and Emission Spectrum of Scintillators ................................. 73
2
Operating Characteristics
This section describes the prime features of photomultiplier tube construction and basic operating characteristics.
1. GENERAL
The photomultiplier tube (PMT) is a photosensitive device con-sisting of an input window, a photocathode, focusing electro-des, an electron multiplier (dynodes) and an anode in a va-cuum tube, as shown in Figure 1. When light enters the photo-cathode, the photocathode emits photoelectrons into vacuum by the external photoelectric effect. These photoelectrons are directed by the potential of focusing electrode towards the elec-tron multiplier where electrons are multiplied by the process of secondary electron emission.The multiplied electrons are collected to the anode to produce output signal.
2. PHOTOCATHODE
2.1 Spectral Response
The photocathode of PMT converts energy of incident light into photoelectrons by the external photoelectric effect. The conver-sion efficiency, that is photocathode sensitivity, varies with the wavelength of incident light. This relationship between the pho-tocathode sensitivity and the wavelength is called the spectral response characteristics.Typical spectral response curves of the variation of bialkali photocathodes are shown on the inside of the back cover.The spectral response range is determined by the photoca-thode material on the long wavelength edge, and by the win-dow material on the short wavelength edge.In this catalog, the long wavelength cut-off of spectral response range is defined as the wavelength at which the cathode radi-ant sensitivity drops to 1 % of the maximum sensitivity.
2.2 Quantum Efficiency and Radiant SensitivitySpectral response is usually expressed in term of quantum effi-ciency and radiant sensitivity as shown on the inside the back cover.Quantum efficiency (QE) is defined as the ratio of the number of photoelectrons emitted from the photocathode to the number of incident photons.It's customarily stated as a percentage. The equation of QE is as follows:
2.3 Window Materials
The window materials commonly used in PMT are as follows:
(1) Borosilicate glass
This is the most frequently used material. It transmits light from the infrared to approximately down to 300 nm.For some scintillation applications where radioactivity of K40 contained in the glass affects the measurement, "K-free" glass is recommended.As "K-free" glass contains very little amount of Potassium, the background counts originated by 40K is minimized.
(2) UV-transmitting glass
This glass transmits ultraviolet light well as the name implies, and it is widely used. The UV cut-off wavelength is approxi-mately 185 nm.
(3) Synthetic silica
This material transmits ultraviolet light down to 160 nm. Silica is not suitable for the stem material of tubes because it has a different thermal expansion coefficient from kovar metal which is used for the tube leads. Thus, borosilicate glass is used for the stem. In order to seal these two materials having different thermal expansion ratios, a technique called graded seal is used. This is a technique to seal several glass materials having gradually different thermal expansion ratios. Another feature of silica is superiority in radiation hardness.
2.4 Photocathode Materials
The photocathode is a photoemissive surface with very low work and high energy physics applications:
(1) Bialkali
This has a spectral response which fits the emission spectra of most scintillators. Thus, it is frequently used for scintillator ap-plications.
(2) High Temperature Bialkali
This is particularly useful at higher operating temperatures up to 175 °C. Its major application is oil well logging. Also it can be operated with very low dark current at the room temperature.
Radiant sensitivity (S) is the photoelectric current from the pho-tocathode divided by the incident radiant power at a given wa-velength, expressed in A/W (ampere per watt).The equation of S is as follows:
Quantum efficiency and radiant sensitivity have the following relationship at a given wavelength.
where λ is the wavelength in nm (nanometer).
Figure 1: Cross-Section of Head-On Type PMT
TPMHC0048EA
Number of PhotonsNumber of Photoelectrons
QE = ×100 (%)
Radiant Power of LightPhotoelectric Current
S = (A/W)
λS×1240
QE = ×100 (%)
PHOTOCATHODE
INCIDENTLIGHT
ELECTRON MULTIPLIER(DYNODES)
ANODE
INPUTWINDOW
FOCUSING ELECTRODES
PHOTOELECTRON
STEM
3
As stated above, the spectral response range is determined by the materials of the photocathode and the window as shown in Figure 33.It is important to select appropriate materials which will suit the application.
2.5 Luminous and Blue Sensitivity
Since the measurement of spectral response characteristics of a PMT requires a sophisticated system and time, it isn't practi-cal to provide spectral response data on each tube. Instead, cathode and anode luminous sensitivity data are usually at-tached.
The cathode luminous sensitivity is the photoelectric current from the photocathode per incident light flux (10-5 to 10-2 lu-men) from a tungsten filament lamp operated at a distribution temperature of 2856 K.The cathode luminous sensitivity is expressed in the unit of µA/lm (micro amperes per lumen).Note that the lumen is a unit used for luminous flux in the visible region, therefore these values may be meaningless for tubes which are sensitive out of the visible region (refer to Figure 2).The cathode blue sensitivity is the photoelectric current from the photocathode per incident light flux of a tungsten filament lamp at 2856 K passing through a blue filter. Corning CS-5-58 filter which is polished to half stock thickness is used for the measurement of this sensitivity. This filter is a band-pass filter and its peak wavelength of transmittance is 400 nm.Since the light flux, once transmitted through the blue filter, can not be expressed in lumen, the blue sensitivity is usually repre-sented by the blue sensitivity index.The blue sensitivity is a very important parameter in the scintil-lation counting since most of the scintillators produce emission spectrum in the blue region, and it may dominant factor of en-ergy resolution.These parameters of cathode luminous and blue sensitivities are particularly useful when comparing tubes having the same or similar spectral response ranges. Hamamatsu final test sheets accompanied with tubes usually indicate these parameters.
Figure 2: Typical Human Eye Response and Spectral Distribution of 2856 K Tungsten Lamp
TPMOB0054EB100
80
60
40
0
20
200 400 600 800 1000 1200 1400
WAVELENGTH (nm)
RE
LAT
IVE
VA
LUE
(%
)
VISUAL SENSITIVITY
TUNGSTEN LAMPAT 2856 K
3. ELECTRON MULTIPLIER (DYNODES)
The superior sensitivity (high gain and high S/N ratio) of PMT is due to a low noise electron multiplier which amplifies electrons in a vaccum with cascade secondary emission process. The electron multiplier consists of several to up to 19 stages of electrodes which are called dynodes.
3.1 Dynode Types
There are several principal types of dynode structures. Fea-tures of each type are as follows:
(1) Linear focused type
Fast time response, high pulse linearity
(2) Box and grid type
Good collection efficiency, good uniformity
(3) Box and linear focused type
Good collection efficiency, good uniformity, low profile
(4) Circular cage type
Fast time response, compactness
(5) Venetian blind type
Good uniformity, large output current
(6) Fine mesh type
High immunity to magnetic fields, good uniformity, high pulse linearity, position detection possible.
(7) Coarse mesh type
Immunity to magnetic fields, high pulse linearity, position detec-tion possible.
(8) Metal channel type
Compact dynode construction, fast time response, position de-tection possible.
Also hybrid dynodes combining two of the above dynodes have been developed. These hybrid dynodes are designed to pro-vide the merits of each dynode type.
4. ANODE
The PMT anode output is the product of photoelectric current from the photocathode and gain. Photoelectric current is pro-portional to the intensity of incident light. Gain is determined by the applied voltage on a specified voltage divider.
4.1 Luminous sensitivity
The anode luminous sensitivity is the anode output current per incident light flux (10-10 to 10-5 lumen) from a tungsten filament lamp operated at a distribution temperature of 2856 K. This is expressed in the unit of A/lm (amperes per lumen) at a speci-fied anode-to-cathode voltage with a specified voltage divider.
4
5. ANODE DARK CURRENT
A small amount of output current flows in a PMT even when it is operated in complete darkness. This current is called the anode dark current. The dark current and the noise resulted from are critical factors to determin the lower limit of light de-tection.The causes of dark current may be categorized as follows:
(1) Thermionic emission of electrons
Since the materials of the photocathode and dynodes have very low work functions, they emit thermionic electrons even at the room temperature. Most of the dark current originates from the thermionic emissions especially from the photocathode, and it is multiplied by the dynodes.
(2) Ionization of residual gases
Residual gases inside the PMT can be ionized by the flow of photoelectrons. When these ions strike the photocathode or earlier stages of dynodes, secondary electrons may be emit-ted, thus resulting in relatively large output noise pulses. These noise pulses are usually observed as afterpulses following the primary signal pulses and may be a problem in detecting short light pulses. Present PMT's are designed to minimize afterpul-ses.
(3) Glass scintillation
In case electrons deviating from their normal trajectories strike the glass envelope, scintillations may occur and dark pulses may result. To eliminate these pulses, PMT's may be operated with the anode at high voltage and the cathode at the ground potential. Otherwise it is useful to coat the glass bulb with a conductive paint connected to the cathode (called HA coating: see page 13).
(4) Ohmic leakage
Ohmic leakage resulting from insufficient insulation of the glass stem base and socket may be another source of dark current. This is predominant when a PMT is operated at a low voltage or low temperature.Contamination by dirt and humidity on the surface of the tube may cause ohmic leakage, and therefore should be avoided.
(5) Field emission
When a PMT is operated at a voltage near the maximum rating value, some electrons may be emitted from electrodes by strong electric fields causing dark pulses. It is therefore recom-mended that the tube be operated at 100 volts to 300 volts low-er than the maximum rating.The anode dark current decreases along time after a PMT is placed in darkness. In this catalog, anode dark currents are specified as the state after 30 minutes storage in darkness.
4.2 Gain (Current Amplification)
Photoelectrons emitted from a photocathode are accelerated by an electric field so as to strike the first dynode and produce secondary electron emissions. These secondary electrons then impinge upon the next dynode to produce additional secondary electron emissions. Repeating this process over successive dynode stages (cascade process), a high gain is achieved. Therefore a very small photoelectric current from the photoca-thode can be observed as a large output current from the anode of the PMT.Gain is simply the ratio of the anode output current to the pho-toelectric current from the photocathode. Ideally, the gain of the PMT is defined as δn, where n is the number of dynode stage and δ is an average secondary emission ratio.While the secondary electron emission ratio δ is given by
δ = A • Eα
where A is constant, E is an interstage voltage, and α is a coef-ficient determined by the dynode material and geometric struc-ture. It usually has a value of 0.7 to 0.8.When a voltage V is applied between the cathode and the anode of the PMT having n dynode stages, gain G becomes
Figure 3 shows gain characteristics.Since generally PMTs have 8 to 12 dynode stages, the anode output varies directly with the 6th to 10th power of the change in applied voltage. The output signal of the PMT is extremely susceptible to fluctuations in the power supply voltage, thus the power supply should be very stable and exhibit minimum rip-ple, drift and temperature coefficient. Regulated high voltage power supplies designed with this consideration are available from Hamamatsu.
Figure 3: Example of Gain vs. Supply Voltage
= δn = (A • Eα)n = A • n + 1
V α n =
(n + 1)αnAn
Vαn = K • Vαn
( )G
(K: constant)
104 109
200 300 500 700 1000 1500
AN
OD
E L
UM
INO
US
SE
NS
ITIV
ITY
(A
/lm)
SUPPLY VOLTAGE (V)
GA
IN
ANO
DE
SEN
SITI
VITY
GAI
N
108
107
106
105
104
103
103
102
101
100
10-1
10-2
TPMOB0038EB
5
6. TIME RESPONSE
In applications where forms of the incident light are pulses, the anode output signal should reproduce a waveform faithful to the incident pulse waveform.This reproducibility depends on the anode pulse time re-sponse.
(1) Rise Time (refer to Figure 4)
The time for the anode output pulse to rise from 10 % to 90 % of the peak amplitude when the whole photocathode is illumin-ated by a delta-function light pulse.
(2) Electron Transit Time (refer to Figure 4)
The time interval between the arrival of a delta-function light pulse at the photocathode and the instant when the anode out-put pulse reaches its peak amplitude.
(3) T.T.S. (Transit Time Spread) (refer to Figure 5)
This is also called the transit time jitter. This is the fluctuation in transit time between individual pulses, and is defined as the FWHM of the frequency distribution of electron transit times. T.T.S. depends on the number of incident photons. The values in this catalog are measured in the single photoelectron state.
(4) C.R.T. (Coincident Resolving Time)
This is one of the important parameters in high energy physics applications and is defined as the FWHM of a coincident timing spectrum of a pair PMT's facing each other when they detect coincident gamma-ray emission due to positron annihilation of a radiation source (22Na). The scintillators used are CsF, BGO or BaF2 crystals. These PMT's can be selected for special re-quirements.
Figure 4: Definition of Rise Time and Transit Time
Figure 5: Definition of T.T.S.
Tt
FWHM=T.T.S.
TIME
FR
EQ
UE
NC
Y
Tt
These parameters are affected by the dynode structure and applied voltage. In general, PMTs of the linear focused or cir-cular cage structure exhibit better time response than that of the box-and-grid or venetian blind structure.
Figure 6 shows typical time response characteristics vs. ap-plied voltage for types R2059 (51 mm dia. head-on, 12-stage, linear-focused type).
Figure 6: Time Response Characteristics vs. Supply Voltage
500 1000 1500 2000 30002500
SUPPLY VOLTAGE (V)
TIM
E (
ns)
TYPE NO. : R2059
T. T. S.
RISE TIME
TRANSIT TIME
102
101
100
TPMOB0059EB
7. PULSE LINEARITY
The definition of the pulse linearity is proportionality between the input light amount and the output current in the pulse oper-ation mode. When intense light pulses are to be measured, it's necessary to know the pulse linearity range of the PMT.In this catalog, typical values of pulse linearity are specified at two points (±2 % and ±5 % deviations from linear proportionali-ty), as shown in Figure 7.The two-pulse technique is employed in this measurement. LED's are used for a pulsed light source. Its pulse width is 50 ns and the repetition rate is 1 kHz.The deviation from the proportionality is called non-linearity in this catalog. The cause of non-linearity is mainly a space charge effect in the later stages of an electron multiplier. This space charge effect depends on the pulse height of the PMT output current and the strength of electric fields between elec-trodes.
DELTA-FUNCTIONLIGHT PULSE AT PHOTOCATHODE
RISE TIME
TRANSIT TIME
Tt 90%
10%
TPMOC0041EA
TPMOC0042EA
6
9. STABILITY
In scintillation counting, there are two relevant stability charac-teristics for the PMT in pulse height mode operation, the long term and the short term. In each case a 137Cs source (662 keV), and an NaI(Tl) scintillator, and a multichannel pulse height ana-lyzer are used. PMT's are warmed up for about one hour in the dark with voltage applied.
9.1 Long Term Stability (Mean gain deviation)
This is defined as follows when the PMT is operated for 16 hours at a constant count rate of 1000 s-1:
where P is the mean pulse height averaged over n readings, Pi is the pulse height at the i-th reading, and n is the total number of readings.
9.2 Short Term Stability
This is the gain shift against count rate change. The tube is ini-tially operated at about 10000 s-1. The photo-peak count rate is then decreased to approximately 1000 s-1 by increasing the distance between the 137Cs source and the scintillator coupled to the PMT.
9.3 Drift and Life Characteristics
While operating a photomultiplier tube continuously over a long period, anode output current of the photomultiplier tube may vary slightly with time, although operating conditions have not changed. This change is reffered to as drift or in the case where the operating time is 1000 hours to 10000 hours it is called life characteristics. Figure 9 shows typical life characteristics. Drift is primarily caused by damage to the last dynode by heavy electron bombardment. Therefore the use of lower anode current is desirable. When stability is of prime impor-tance, the use of average anode current of 1 µA or less is rec-ommended.
8. UNIFORMITY
Although the focusing electrodes of a PMT are designed so that electrons emitted from the photocathode or dynodes are collected efficiently by the first or following dynodes, some electrons may deviate from their desired trajectories and col-lection efficiency is degraded. The collection efficiency varies with the position on the photocathode from which the photo-electrons are emitted, and influences the spatial uniformity of a photomultiplier tube. The spatial uniformity is also determined by the photocathode surface uniformity itself.PMTs especially designed for gamma camera applications have excellent spatial uniformity. Example of spatial uniformity is shown in Figure 8.
The special voltage distribution ratios are designed to achieve strong electric fields in the later stages of the electron multiplier. Some types are specified with these special voltage dividers.
Figure 7: Example of Pulse Linearity Characteristic
Figure 8: Example of Spatial Uniformity
Figure 9: Examples of Life
nDg =
nΣ
i =1P-Pi
P
100 • (%)
10
ANODE PEAK CURRENT (mA)
DE
VIA
TIO
N (
%)
2%
5%
0
-10
-20100 101 102 103
TPMHB0094ED
100
50
0
TOP VIEW OFPHOTOCATHODE
SE
NS
ITIV
ITY
(%
)
a a'
100 50 0
aa'
SENSITIVITY (%)
TPMHB0794EA
TPMHC0050EA
150
125
100
75
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25
1 10 100
OPERATING TIME (h)
1000 100000
RE
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OD
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EN
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Y (
%)
TEST CONDITIONS SUPPLY VOLTAGE: 1000 V INITIAL CURRENT: 100 µA LIGHT SOURCE: TUNGSTEN LAMP TEMPERATURE: 25 °C NUMBER OF SAMPLES: 10
x
x + σ
x - σ
7
10. ENVIRONMENT
10.1 Temperature Characteristics
The sensitivity of the PMT varies with the temperature. Figure 10 shows typical temperature coefficients of anode sensitivity around the room temperature for bialkali and high temp. bialkali photocathode types. In the ultraviolet to visible region, the tem-perature coefficient of sensitivity has a negative value, while it has a positive value near the longer wavelength cut-off.Since the temperature coefficient change is large near the lon-ger wavelength cut-off, temperature control may be required in some applications.
10.2 Magnetic Field
Most PMTs are affected by the presence of magnetic fields. Magnetic fields may deflect electrons from their normal trajec-tories and cause a loss of gain. The extent of the loss of gain depends on the type of the PMT and its orientation in the mag-netic field. Figure 11 shows typical effects of magnetic fields on some types of PMTs. In general, a PMT having a long path from the photocathode to the first dynode are very sensitive to magnetic fields. Therefore head-on types, especially of large diameter, tend to be more adversely influenced by magnetic fields.When a PMT has to be operated in magnetic fields, it may be necessary to shield the PMT with a magnetic shield case. (Ha-mamatsu provides a variety of magnetic shield cases.)
Figure 10: Typical Temperature Coefficients of Anode Sensitivity
200 400 600 800
WAVELENGTH (nm)
TE
MP
ER
AT
UR
E C
OE
FF
ICIE
NT
(%
/°C
)
HIGH TEMP.BIALKALI
BIALKALI
0.5
0
-0.5
TPMOB0036EC
For example, the shield case, of which inner diameter is 60 mm and the thickness is 0.8 mm, can be used in a magnetic field of around 5 mT without satulation. If a magnetic field strength is more than 10 mT, the double shielding method is necessary for a conventional PMT, otherwise proximity mesh types should be used. It should be noted that the magnetic shielding effect de-creases towards the edge of the shield case as shown in Fig-ure 12. It is suggested to cover a PMT with a shield case lon-ger than the PMT length by at least half the PMT diameter.
Figure 11: Typical Effects by Magnetic Fields Perpendicular to Tube Axis
Figure 12: Edge Effect of Magnetic Shield Case
LONGER than r
1000
100
10
1
t
L
r r
SH
IELD
ING
FA
CT
OR
2r PHOTOMULTIPLIER TUBE
TPMOB0011EB
-3 -2 -1 0 1 2 30.01
0.1
1.0
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MAGNETIC FLUX DENSITY (mT)
51 mm dia.HEAD-ON TYPE BOX-AND-GRID TYPE DYNODE
19 mm dia.HEAD-ON TYPE LINEAR-FOCUSED TYPE DYNODE( )
( )
TPMOB0017EB
The proximity mesh made of non-magnetic material has been introduced as alternate dynodes in PMT's. These types (see page 24) exhibit much higher immunity to external magnetic fields than the conventional PMT's. Also triode and three types (see page 24) are useful for applications at high light intensi-ties.
8
11.1 Anode Grounding and Photocathode Grounding
In order to eliminate the potential difference between the pho-tomultiplier tube anode and external circuits such as an amme-ter, and to facilitate the connection, the generally used techni-que for voltage divider circuits is to ground the anode and sup-ply a high negative voltage (-HV) to the photocathode, as shown in Figure 14. This scheme provides the signal output in both DC and pulse operations, and is therefore used in a wide range of applications.
In photon counting and scintillation counting applications, how-ever, the photomultiplier tube is often operated with the photo-cathode grounded and a high positive voltage (+HV) supplied to the anode mainly for purposes of noise reduction. This pho-tocathode grounding scheme is shown in Figure 15, along with the coupling capacitor Cc for isolating the high voltage from the output circuit. Accordingly, this setup cannot provide a DC sig-nal output and is only used in pulse output applications. The re-sistor RP is used to give a proper potential to the anode. The resistor RL is placed as a load resistor, but the actual load re-sistance will be the combination of RP and RL.
11. VOLTAGE DIVIDER CIRCUITS
To operate a photomultiplier tube, a high voltage of 500 volts to 2000 volts is usually supplied between the photocathode (K) and the anode (P), with a proper voltage gradient set up along the photoelectron focusing electrode (F) or grid (G), secondary electron multiplier electrodes or dynodes (Dy) and, depending on photomultiplier tube type, an accelerating electrode (Acc). Figure 13 shows a schematic representation of photomultiplier tube operation using independent multiple power supplies, but this is not a practical method. Instead, a voltage divider circuit is commonly used to divide, by means of resistors, a high vol-tage supplied from a single power supply.
Figure 13: Schematic Representation of Photomultiplier Tube Operation
Figure 14: Anode Grounded Voltage Divider Circuit
Figure 15: Photocathode Grounded Voltage Divider CircuitTACCC0055EA
KLIGHT
F Dy1 Dy2 Dy3 P
V1 V2 V3 V4 V5
POWER SUPPLIES
ANODE CURRENTIp
A
e- e- e- e-
PHOTOELECTRONS
SECONDARY ELECTRONS
Figure 14 shows a typical voltage divider circuit using resistors, with the anode side grounded. The capacitor C1 connected in parallel to the resistor R5 in the circuit is called a decoupling capacitor and improves the output linearity when the photomul-tiplier tube is used in pulse operation, and not necessarily used in providing DC output. In some applications, transistors or Zener diodes may be used in place of these resistors.
TACCC0056EB
K F Dy1 Dy2 Dy3 P
R1 R2 R3 R4 R5
OUTPUT
RL
C1
Ip
-HV
TACCC0057EB
FK Dy1 Dy2 Dy3 P
R1 R2 R3 R4 R5
RP
C1
RL
OUTPUTCC
Ip
+HV
C2
9
Figure 16: Equally Divided Voltage Divider Circuit
Figure 17: Tapered Voltage Divider Circuit
Figure 18: Output Linearity of Photomultiplier Tube
Figure 19: Basic Operation of Photomultiplier Tubeand Voltage Divider Circuit
11.2 Standard Voltage Divider Circuits
Basically, the voltage divider circuits of socket assemblies lis-ted in this catalog are designed for standard voltage distribu-tion ratios which are suited for constant light measurement. Socket assemblies for side-on photomultiplier tubes in particu-lar mostly use a voltage divider circuit with equal interstage vol-tages allowing high gain as shown in Figure 16.
11.4 Voltage Divider Circuit and Photomultiplier Tube Output Linearity
In both DC and pulse operations, when the light incident on the photocathode increases to a certain level, the relationship be-tween the incident light level and the output current begins to deviate from the ideal linearity. As can be seen from Figure 18, region A maintains good linearity, and region B is the so-called overlinearity range in which the output increase is larger than the ideal level. In region C, the output goes into saturation and becomes smaller than the ideal level. When accurate measure-ment with good linearity is essential, the maximum output cur-rent must be within region A. In contrast, the lower limit of the output current is determined by the dark current and noise of the photomultiplier tube as well as the leakage current and noise of the external circuit.
11.5 Output Linearity in DC Mode
Figure 19 is a simplified representation showing photomultiplier tube operation in the DC output mode, with three stages of dy-nodes and four dividing resistors R1 through R4 having the same resistance value.
11.3 Tapered Voltage Divider Circuits
In most pulsed light measurement applications, it is often nec-essary to enhance the voltage gradient at the first and/or last few stages of the voltage divider circuit, by using larger resis-tances as shown in Figure 17. This is called a tapered voltage divider circuit and is effective in improving various characteris-tics. However it should be noted that the overall gain decrea-ses as the voltage gradient becomes greater. In addition, care is required regarding the interstage voltage tolerance of the photomultiplier tube as higher voltage is supplied. The tapered voltage circuit types and their suitable applications are listed below.
TACCC0058EB
K Dy1 Dy2 Dy3 P
1R 1R 1R 1R 1R
-HV
RL
C2
OUTPUT
C1
1R
Dy4 Dy5
Tapered circuit at the first few stages (resistance: large / small)Photon counting (improvement in pulse height distribution)Low-light-level detection (S/N ratio enhancement)High-speed pulsed light detection (improvement in timing properties)Other applications requiring better magnetic characteristics and uniformity
Tapered circuit at the last few stages (resistance: small / large)High pulsed light detection (improvement in output linearity)High-speed pulsed light detection (improvement in timing properties)Other applications requiring high output across the load resistor
TACCC0059EB
K Dy1 Dy2 Dy3 P
2R 1.5R 1R 1R 3R
-HV
RL
C2
OUTPUT
C1
2R
Dy4 Dy5
TACCB0005EA
0.001
0.01
0.1
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0.001 0.01 0.1 1.0 10
A
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ACTUALCURVE
IDEALCURVE
TACCC0060EA
K Dy1 Dy2 Dy3 P
R1 R2 R3
-HV
Ip
R4
A
IR1 IR2 IR3 IR4
ID
IDy1 IDy2 IDy3IK
I1I2 I3
I4
10
Figure 22: Changes in Interstage Voltages at DifferentIncident Light Levels
Figure 21: Operation with Light Input
TACCC0062EA
ID' =ID + ∆ID
V1' V2' V3' V4'
IR1' IR2' IR3' IR4'
I1' (=IK') I2' I3'I4' (=IP')
Ik' IDy1' IDy2' IDy3' IP'
R1 R2 R3 R4
K Dy1 Dy2 Dy3 P
-HV
Figure 22 shows changes in the interstage voltages as the inci-dent light level varies. The interstage voltage V4' with light input drops significantly compared to V4 in dark state operation. This voltage loss is redistributed to the other stages, resulting an in-creases in V1', V2' and V3' which are higher than those in dark state operation. The interstage voltage V4' is only required to collect the secondary electrons emitted from the last dynode to the anode, so it has little effect on the anode current even if dropped to 20 or 30 volts. In contrast, the increases in V1', V2' and V3' directly raise the secondary emission ratios (δ1, δ2 and δ3) at the dynodes Dy1, Dy2 and Dy3, and thus boost the over-all gain m (= δ1 • δ2 • δ3 ). This is the cause of overlinearity in region B in Figure 10. As the incident light level further increa-ses so that V4' approaches 0 volts, output saturation occurs in region C.
TACCB0017EA
80
90
100
110
120
V1 V2 V3 V4
POSITION OF INTERSTAGE VOLTAGE
INT
ER
ST
AG
E V
OLT
AG
E (
%)
HIGH LIGHT INPUT
MODERATE LIGHT INPUT
NO OR FAINT LIGHT INPUT
Where In' is the interelectrode current which has the following relation:
I1' < I2' < I3' < I4'
Thus, the interstage voltage Vn' (=IRn' • Rn) becomes smaller at the latter stages, as follows:
V1' > V2' > V3' > V4'
Figure 20: Operation without Light Input
[When light is not incident on the tube]In dark state operation where a high voltage is supplied to a photomultiplier tube without incident light, the current compo-nents flowing through the voltage divider circuit will be similar to those shown in Figure 20 (if we ignore the photomultiplier tube dark current). The relation of current and voltage through each component is given below
Interelectrode current of photomultiplier tube
I1=I2=I3=I4 (= 0 A)
Electrode current of photomultiplier tube
IK=IDy1=IDy2=IDy3=IP (= 0 A)
Voltage divider circuit current
IR1=IR2=IR3=IR4=ID= (HV/ Rn)
Voltage divider circuit voltage
V1=V2=V3=V4=ID • Rn (= HV/4)
[When light is incident on the tube]When light is allowed to strike the photomultiplier tube under the conditions in Figure 20, the resulting currents can be con-sidered to flow through the photomultiplier tube and the voltage divider circuit as schematically illustrated in Figure 21. Here, all symbols used to represent the current and voltage are ex-pressed with a prime ( ' ), to distinguish them from those in dark state operation.The voltage divider circuit current ID' is the sum of the voltage divider circuit current ID in dark state operation and the current flowing through the photomultiplier tube ∆ID (equal to average interelectrode current). The current flowing through each divid-ing resistor Rn becomes as follows:
IRn' = ID' - In'
Σn=1
4
TACCC0061EAID
V1 V2 V3 V4
R1 R2 R3 R4
IR1 IR2 IR3 IR4
I1 (=IK) I2 I3 I4 (=IP)K Dy1 Dy2 Dy3 P
-HV
IK IDy1 IDy2 IDy3 IP
11
Figure 24: Active Voltage Divider Circuit
Figure 25: Voltage Divider Circuit Using Zener Diodes
Figure 23: Output Linearity vs. Anode Current toVoltage Divider Current Ratio
11.6 Linearity Improvement in DC Output Mode
To improve the linearity in DC output mode, it is important to minimize the changes in the interstage voltage when photocur-rent flows through the photomultiplier tube. There are several specific methods for improving the linearity, as discussed below.
TACCB0031EA
RATIO OF ANODE CURRENT TO VOLTAGE DIVIDER CURRENT (%)
OU
TP
UT
LIN
EA
RIT
Y (
%)
0.01
10
0.1
1
0.1 101
2Using the active voltage divider circuitUse of a voltage divider circuit having transistors in place of the dividing resistors in last few stages (for example, Hamamatsu E6270 series using FETs) is effective in improving the output linearity. This type of voltage divider circuit ensures good line-arity up to an output current equal to 60 % to 70 % of the vol-tage divider current, since the interstage voltage is not affected by the interelectrode current inside the photomultiplier tube. A typical active voltage divider circuit is shown in Figure 24.
As stated above, good output linearity can be obtained simply by increasing the voltage divider current. However, this is ac-companied by heat emanating from the voltage divider. If this heat is conducted to the photomultiplier tube, it may cause problems such as an increase in the dark current, and variation in the output.
TACCC0063EA
K P
-HV
TWOTRANSISTORS
RL
Dy1 Dy2 Dy3 Dy4 Dy5
3Using Zener DiodesThe output linearity can be improved by using Zener diodes in place of the dividing resistors in the last few stages, because the Zener diodes serve to maintain the interstage voltages at a constant level. However, if the supply voltage is greatly varied, the voltage distribution may be imbalanced compared to other interstage voltages, thus limiting the adjustable range of the voltage with this technique. In addition, if the supply voltage is reduced or if the current flowing through the Zener diodes be-comes insufficient due to an increase in the anode current, noise may be generated from the Zener diodes. Precautions should be taken when using this type of voltage divider circuit. Figure 25 shows a typical voltage divider circuit using Zener di-odes.
TACCC0064EA
K Dy1 Dy2 Dy3
-HV
Dy4 Dy5
TWOZENER DIODES
RL
P
1Increasing the voltage divider currentFigure 23 shows the relationship between the output linearity of a 28 mm (1-1/8") diameter side-on photomultiplier tube and the ratio of anode current to voltage divider current. For exam-ple, to obtain an output linearity of 1 %, it can be seen from the figure that the anode current should be set approximately 1.4 % of the divider circuit current. However, this is a calculated plot, so actual data may differ from tube to tube even for the same type of photomultiplier tube, depending on the supply voltage and individual dynode gains. To ensure high photomet-ric accuracy, it is recommended that the voltage divider current be maintained at least twice the value obtained from this figure.
The maximum linear output in DC mode listed for the D-type socket assemblies in this catalog indicates the anode current equal to 1/20 of the voltage divider current. The output linearity at this point can be maintained within ±3 % to ±5 %.
12
Figure 28: Equally Divided Voltage Divider Circuit andDecoupling Capacitors
TACCC0067EB
K Dy1 Dy2 Dy3
-HV
Dy4 Dy5
RL
P
1R 1R 1R 1R 1R
CD2CD1
1R
TWO DECOUPLING CAPACITORS
11.7 Output Linearity in Pulsed Mode
In applications such as scintillation counting where the incident light is in the form of pulses, individual pulses may range from a few to over 100 milliamperes even though the average anode current is small at low count rates. In this pulsed output mode, the peak current in extreme cases may reach a level hundreds of times higher than the voltage divider current. If this happens, it is not possible to supply interelectrode currents from the vol-tage divider circuit to the last few stages of the photomultiplier tube, thus leading to degradation in the output linearity.
11.8 Improving Linearity in Pulsed Output Mode
1Using decoupling capacitorsUsing multiple power supplies mentioned above is not popular in view of the cost. The most commonly used technique is to supply the interelectrode current by using decoupling capaci-tors as shown in Figure 28. There are two methods for con-necting these decoupling capacitors: the serial method and the parallel method. As Figures 28 and 29 show, the serial method is more widely used since it requires lower tolerance voltages of the capacitors. The capacitance value C (farads) of the de-coupling capacitor between the last dynode and the anode should be at least 100 times the output charge as follows:
C > 100 • Q/V
where Q is the charge of one output pulse (coulombs) and V is the voltage (volts) across the last dynode and the anode.
Since this method directly supplies the pulse current with elec-trical charges from the capacitors, if the count rate is increased and the resulting duty factor becomes larger, the electrical charge will be insufficient. Therefore, in order to maintain good linearity, the capacitance value obtained from the above equa-tion must be increased according to the duty factor, so that the voltage divider current is kept at least 50 times larger than the average anode current just as with the DC output mode.The active voltage divider circuit and the booster method using multiple power supplies discussed previously, provide superior pulse output linearity even at a higher duty factor.
Figure 27: Voltage Divider Circuit Using Multiple PowerSupplies (Booster Method)
5Using multiple high voltage power suppliesAs shown in Figure 27, this technique uses multiple power sup-plies to directly supply voltages to the last few stages near the anode. This is sometimes called the booster method, and is used for high pulse and high count rate applications in high en-ergy physics experiments.
TACCC0066EA
K
RL
PDy1 Dy2 Dy3 Dy4 Dy5
AUXILIARY POWER SUPPLY 1
MAIN POWER SUPPLY
AUXILIARYPOWER SUPPLY 2
Figure 26: Cockcroft-Walton Circuit
4Using Cockcroft-Walton CircuitWhen a Cockcroft-Walton circuit as shown in Figure 26 is used to operate a 28 mm (1-1/8") diameter side-on photomultiplier tube with a supply voltage of 1000 volts, good DC linearity can be obtained up to 200 µA and even higher. Since a high vol-tage is generated by supplying a low voltage to the oscillator circuit, there is no need for using a high voltage power supply.This Cockcroft-Walton circuit achieves superior DC output line-arity as well as low current consumption.
TACCC0065EA
K
RL
PDy1 Dy2 Dy3 Dy4 Dy5
OSCILLATIONCIRCUIT
-HV GENERATED
13
Figure 29: Tapered Voltage Divider Circuit UsingDecoupling Capacitors
12. EXTERNAL POTENTIAL
If the input window or glass envelope near the photocathode is grounded, slight conductivity of glass material causes a current flow between the photocathode, which has a high negative po-tential, and ground.This may cause electrolysis of photocathode, leading to signifi-cant deterioration.Also this may cause noise resulted from the light flashes at the above input window or glass envelope.For those reasons, when designing a PMT housing with an electrostatic or magnetic shield case, extreme care should be required.When the anode ground scheme is used, bringing a grounded metallic holder or magnetic shield case near the glass envel-ope of PMT can cause electrons to strike the inner glass wall, resulting in the noise.This problem can be solved by applying a black conductive paint around the glass envelope and connecting it to the cath-ode potential. Then PMT is wrapped with an insulating black cover, as shown in Figure 30. This method is called HA coating.
2Using tapered voltage divider circuit with decoupling capacitors
Use of the above voltage divider circuit having decoupling ca-pacitors is effective in improving pulse linearity. However, when the pulse current increases further, the electron density also in-creases, particularly in last stages. This may cause a space charge effect which prevents interelectrode current from flow-ing adequately and leading to output saturation. A commonly used technique for extracting a higher pulse current is the ta-pered voltage divider circuit in which the voltage distribution ra-tios in the latter stages are enhanced as shown in Figure 29. Care should be taken in this case regarding loss of the gain and the breakdown voltages between electrodes.Since use of a tapered voltage divider circuit allows an in-crease in the voltage between the last dynode and the anode, it is possible to raise the voltage across the load resistor when it is connected to the anode. It should be noted however, that if the output voltage becomes excessively high, the voltage be-tween the last dynode and the anode may drop, causing a deg-radation in output linearity.
TACCC0068EB
K Dy1 Dy2 Dy3
-HV
Dy4 Dy5
RL
P
1R 1R 1R 1.5R 3R
CD2CD1
2.5R
TWO DECOUPLING CAPACITORS
13. SCINTILLATION COUNTING
13.1 General
Scintillation counting is one of the most common and effective methods in detecting radiation particles. It uses a PMT coupled to a scintillator which produces light by incidence of radiation particles.In radiation particle measurement, there are two parameters that should be measured. One is the energy of individual par-ticle and the other is the amount of particles. When radiation particles enter the scintillator, they produce light flashes in re-sponse to each particle. The amount of flash is proportional to the energy of the incident particle and individual light flashes are detected by the PMT. Consequently, the output pulses ob-tained from the PMT contain information on both the energy and number of pulses, as shown in Figure 31.
Figure 30: HA Coating
INSULATING BLACK COVER
CONDUCTIVE PAINT CONNECTED TOCATHODE PIN
TPMHC0049EB
Figure 31: Incident Particles and PMT Output
TPMOC0039EA
SCINTILLATOR
PMT
THE HEIGHT OF OUTPUTPULSE IS PROPORTIONALTO THE ENERGY OF INCIDENT PARTICLE.
TIME
CU
RR
EN
T
TIME
14
To obtain a good energy resolution, it is important to use a good scintillator having a high efficiency and a good intrinsic energy resolution. It is also important to reduce a light loss be-tween a PMT and a scintillator. For this purpose, it is useful to couple them with silicon oil having a refractive index close to that of the faceplate window of the PMT or scintillator material or its protective window.
The following factors determin the energy resolution.
(1) Energy conversion efficiency of the scintillator(2) Intrinsic energy resolution of the scintillator(3) Quantum efficiency of the photocathode(4) Collection efficiency of photoelectrons at the first dynode(5) Secondary emission yield of dynodes (especially first dy-
node)
The equation of the pulse height resolution is described as fol-lows:
R(E)2 = RS(E)2 + RP(E)2
where R(E) : energy resolution RS(E) : energy resolution of a scintillator RP(E) : energy resolution of a PMT
Figure 33: Definition of Pulse Height Resolution
RP(E)2 is described as follows:
where N : mean number of incident photon η : quantum efficiency α : collection efficiency δ : mean secondary emission yield of each dynode
Nηα
2.352R(E)2 = ×
δ – 1δ
TPMOB0088EA
PULSE HEIGHT
NU
MB
ER
OF
PU
LSE
S
ab
b
aH
H2
Energy Resolution (FWHM) = — × 100 %
By analyzing these output pulses using a multichannel analyz-er (MCA), pulse height distribution (PHD), or energy spectra, as shown in Figure 32, are obtained. From the PHD, the number of incident particles at various energy levels can be measured.
13.2 Energy Resolution
For the energy spectrum measurement, it is very important to have a distinct peak at each energy level. This characteristic is evaluated as the pulse height resolution or the energy resolution and is most significant in the radiation particle identification.Figure 33 shows the definition of the energy resolution using NaI(Tl) scintillator and 137Cs γ-ray source. It is customarily sta-ted as a percentage.
Figure 32: Typical Pulse Height Distribution (Energy Spectral)
(a) 55Fe+Nal(TI)
(b) 137Cs+Nal(TI)
(c) 60Co+Nal(TI)
TPMOB0087EC
1000
500
(51 mm dia. × 2.5 mm t)
5000 1000
10000
5000
(51 mm dia. × 51 mm t)
5000 1000
10000
5000
500
ENERGY
CO
UN
TS
ENERGY
ENERGY
CO
UN
TS
CO
UN
TS
0 1000
(51 mm dia. × 51 mm t)
15
13.3 Emission Spectrum of Scintillator
The quantum efficiency of the PMT is one of the main factors to determine its energy resolution. It is necessary to choose a PMT whose spectral response matches the scintillator emis-sion. Figure 34 shows PMT typical spectral response vs. emis-sion spectra of scintillators. For NaI(Tl), which is the most pop-ular scintillator, bialkali photocathode PMTs are widely used.
Figure 34: Typical Spectral Response and Emission Spectra of Scintillators
TPMHB0342ED
13.4 Features of Scintillators
Figure 35 shows typical temperature responses of various scin-tillators. These characteristics should be considered in the ac-tual operation.Table 1 shows a summary of scintillator characteristics.These data are reported by scintillator manufactures.
Figure 35: Typical Temperature Response of Various Scintillators
-100
CsI (Tl)
-60 -20 0 +20 +60 +100 +140
100
SCINTILLATOR TEMPERATURE (°C)
BGO
RE
LAT
IVE
LIG
HT
OU
TP
UT
(%
)
Pure CsI
80
40
60
20
NaI (Tl)
TPMOB0033EA
Table 1: Summary of Scintillator Characteristics
Density (g/cm3)
Lrad (cm)
Refractive Index
Hygroscopic
Luminescence (nm)
Decay time (ns)
Relative Light Output
3.67
2.59
1.85
Yes
410
230
100
7.13
1.12
2.15
No
480
300
15
4.51
1.85
1.80
Slightly
530
1000
45 to 50
4.51
1.85
1.80
Slightly
310
10
<10
4.88
2.10
1.58
Slightly
220 / 325
0.9 / 630
20
6.71
1.38
1.85
No
430
30
20
1.03
40
1.58
No
400
2.0
25
7.35
0.88
1.82
No
420
40
70
5.29
2.1
1.9
Yes
380
16
165
5.55
2.70
1.97
No
380
30
40
Nal(Tl) BGO Csl(Tl) Pure Csl BaF2 GSO: Ce Plastic LSO: CeLaBr3: Ce YAP: Ce
A: Borosilicate GlassB: UV GlassC: Synthetic SilicaD: Bialkali Photocathode
E: High Temp. Bialkali PhotocathodeF: Super BialkaliG: Ultra Bialkali
0
100
WAVELENGTH (nm)
QU
AN
TU
M E
FF
ICIE
NC
Y (
%)
8060
40
20
100.1
RE
LAT
IVE
INT
EN
SIT
Y (
%)
100
10
1
700100 200 300 400 500 600
BaF2
LaBr3
Nal (Tl)
LSOCsI (Tl)
BGO
D
G
E
C
F
B
A
16
As the metal channel dynode is a sort of an array of small line-ar focused dynodes, secondary electrons hardly go to the adja-cent dynode channel in a process of multiplication. It is possi-ble to make multi-anode PMTs utilizing this feature. R7600 ser-ies is offering 6 various types of anode shapes as well as sin-gle channel type. These anode shapes are categorized into 3 groups. The first group is multianode in matrix. 4 (2 × 2), 16 (4 × 4) and 64 (8 × 8) matrix channels types are available. (see Figure 38-A) Those are suitable for scintillating fiber readout as well as RICH (Ring Image CHerenkov counter). The second group is linear anode. 16 (1 × 16) and 32 (1 × 32) linear chan-nels types are available. (see Figure 38-B) Those are suitable for coupling with slit shape scintillators and ribbon-shaped scin-tillating fiber bundle. The third one is crossed-plate anode. 6X + 6Y type is available. (see Figure 38-C) It is possible to get posi-tion information by using a center-of-gravity method, this PMT is suitable for compact PET and radiation imaging.R8900 series are wider effective area and longer length com-pare with those of R7600 series. Those are also offering matrix channel type as well as single channel type (see Figure 38-D).Flat panel PMT assemblies use a 52 mm square photomultipli-er tube having an effective area ratio of 89 % and a 64-channel or 256-channel multianode. These flat panel PMTs offer a wide photosensitive area and come in thin, compact shape. These PMTs can be efficiently arrayed in rows or matrices with almost no unused space between them. (See figure 38-E)
14. METAL PACKAGE PHOTOMULTIPLIER TUBE
In general including, the development of more compact and portable equipment has continuously progressed. This has led to a strong demand for miniaturization of highly sensitive pho-todetectors like PMTs. However, it is difficult to miniaturize con-ventional PMTs with glass envelopes and sophisticated elec-trode structures.Accordingly, PMTs have been mainly used in high-precision photometric systems, while semiconductor sensors have been used in general purpose, compact and portable equip-ments/applications. To meet the increasing needs for small photodetectors with high sensitivity, Hamamatsu has devel-oped subminiature PMTs (R7400 series) using a metal pack-age in place of the traditional glass envelope. These tubes have a size as small as semiconductor sensors, without sacri-ficing high sensitivity, and have the high speed response of-fered by conventional PMTs. The remarkable features of R7400 series are: smallest size, fast time response, ability of low light level detection and good immunity to magnetic fields.R7400 series are a subminiature PMT that incorporates an eight stages electron multiplier constructed with stacked thin electrodes (metal channel dynode) into a TO-8 type metal can package of 15 mm in diameter and 10 mm in height. The de-velopment of this metal package and its unique thin electrodes have made the fabrication of this subminiature PMT possible. The electrode structure of the electron multiplier was designed by means of advanced computer simulation and electron tra-jectory analysis. Furthermore, our long experience with micromachining technol-ogy has achieved a closed proximity assembly of these thin electrodes. Figure 36 shows a cross section of the metal chan-nel dynode with simulated electron trajectories.
The R5900 / R7600 / R8900 series is another version of metal package PMT. It incorporates 10 to 12 stages of metal channel dynodes into a metal package of 26 mm × 26 mm square and 20 mm in height. The prime features are similar to those of R7400 series, but its effective area is 18 mm × 18 mm instead of 8 mm diameter of R7400. The dimensional outline of R7600U is shown in Figure 37. In this figure, "U" means a tube having an insulation plastic cover. It is necessary to prevent electric shock with some insulation material, because a metal package has a cathode potential voltage.
Figure 36: Cross Section of Metal Channel Dynode with Electron Trajectories
Figure 37: Insulation Plastic Cover of R7600U
TPMHA0278EI
e e
TPMHC0101EA
SIDE VIEW BOTTOM VIEWTOP VIEW
0.6 ± 0.4
22.0 ± 0.5
30.0 ± 0.5
18 MIN.
4.4 ± 0.7
12.0
± 0
.5
PHOTOCATHODE
INSULATIONCOVER
2.54 PITCH
29- 0.45
EFFECTIVE AREA
25.7 ± 0.5
4 MAX.
17
(A) Matrix Channel Type
Figure 38: Various Anode Shape
(B) Liner Channel Type
(D) R8900 Series
(E) Flat Panel Type
(C) Cross-plate Anode Type
TPMHC0204EB
H7260K(R7259K)
R5900U-00-L16
* R5900 series has flange at the bottom of the metal package, whereas R7600 series doesn't have it.
R8900U-00-M4 R8900-00-M16R8900U
* R8900 series have wider effective area and longer length compared with those of R7600 series.
H9500(R8400-00-M256)
H8500C(R10551-00-M64)
H8711(R7600-00-M16)
H7546B(R7600-00-M64)
R7600U-00-M4
R8900U-00-C12
18
List Guide for Photomultiplier Tubes
TubeDiameter
TypeNo.
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
q w
Socket&
SocketAssembly
Cathode Sensitivity Anode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
yAnode toCathodeSupplyVoltage
(V) (A/lm) (nA)Typ.
(nA)Max.
i
LuminousTyp.
(µA/lm)
t
LuminousTyp.
DarkCurrent
!0 !1
GainTyp.
o
Q.E.at Peak
Typ.
(%)
u
q Spectral Response
The relationship between photocathode sensitivity and wave-length of input light.Curve code corresponds to that of spectral response curve on the inside back cover.(Refer to section 2 on page 2 for further details.)
w Outline No.
This number corresponds to that of PMT dimensional outline drawing shown on later pages.Basing diagram symbols are explained as follows:
<No. of Stages>The number of dynodes used.(Refer to section 3 on page 4 for further details.)
t Cathode Sensitivity (Luminous)
The photoelectric current from the photocathode per incident light flux from a tungsten filament lamp operated at 2856 K.(Refer to section 2.5 on page 3 for further details.)
y Cathode Blue Sensitivity Index
The photoelectric current from the photocathode per incident light flux from a tungsten filament lamp operated at 2856 K passing through a blue filter which is Corning CS 5-58 polished to 1/2 stock thickness.(Refer to section 2.5 on page 3 for further details.)
u QE (Quantum Efficiency)
The ratio of the number of photoelectrons emitted from the pho-tocathode to the number of incident photons.This catalog shows quantum efficiency at the peak wavelength.(Refer to section 2.2 on page 2 for further details.)
i Anode to Cathode Voltage
The voltage indicates a standard applied voltage used to meas-ure characteristics. The number in circles corresponds to that of the voltage distribution ratio on page 46 and 47.
o Gain (Current Amplification)
The ratio of the anode output current to the photoelectric cur-rent from the photocathode.(Refer to section 4.2 on page 4 for further details.)
!0 Anode Sensitivity (Luminous)
The output current from the anode per incident light flux from a tungsten filament lamp operated at 2856 K.(Refer to section 4.1 on page 3 for further details.)
e Socket & Socket Assembly
mark : A socket will be supplied with a PMT.no mark : A socket will be supplied as an option.The number in square corresponds to the outline number of the PMT socket assembly on page 58 and 59.
r Dynode
<Dynode Structure>Each mark means dynode structure as follows:
LINE : linear focusedBOX : box and gridB + L : box and linear focusedCC : circular cageVB : venetian blindFM : fine meshCM : coarse meshMC : metal channel
: Dynode: Grid (Focusing Electrode): Accelerating Electrode: Photocathode: Anode: Shield: Internal Connection (Do not use)
DYG(F)ACCKPSHIC
Short IndexPin
FlyingLead
Key
Pin
BASING DIAGRAM SYMBOLSAll base diagrams show terminals viewed from the base end of the tube.
TPMOC0068EB
19
TypeNo.
Note
TypicalPulseHeight
Resolution
!4
Anodeto
CathodeVoltage
(V)
LongTerm
(%)
ShortTerm
(%)
±2 %Deviation
(mA)
±5 %Deviation
(mA)
AverageAnodeCurrent
(mA)
RiseTimeTyp.
(ns)
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Time Response !3 Stability !5 Pulse Linearity !6
(%)
!1 Anode Dark Current
The output current from the anode measured after 30 minutes storage in complete darkness.(Refer to section 5 on page 4 for further details.)
!2 Maximum Rating
<Anode to Cathode Voltage>The maximum anode to cathode voltages are limited by the in-ternal structure of the PMT.Excessive voltage causes electrical breakdown. The voltage lower than the maximum rating should be applied to the PMT.
<Average Anode Current>This indicates the maximum averaged current over any interval of 30 seconds. For practical use, operating at lower average anode current is recommended.(Refer to section 9.3 on page 6 for further details)
Operating ambient temperature range for the photomultiplier itself is -30 °C to +50 °C except for some types of tubes.However, when photomultiplier tubes are operated below -30 °C at their base section, please consult us in advance.
!3 Time Response
<Rise Time>The time for the anode output pulse to rise from 10 % to 90 % of the peak amplitude.
<Electron Transit Time>The time interval between the arrival of a delta function light pulse at the photocathode and the instant when the anode out-put pulse reaches its peak amplitude.
<T.T.S. (Transit Time Spread)>This is the fluctuation in transit time among individual pulses, and is defined as the FWHM of the frequency distribution of transit time.
<C.R.T. (Coincident Resolving Time)>This is defined as the FWHM of a coincident timing spectrum of a pair PMT's. The scintillator used are BGO, BaF2 or CsF crys-tals.(Refer to section 6 on page 5 for further details.)
!4 Pulse Height Resolution (P.H.R.)
The P.H.R. is measured with the combination of an NaI(Tl) scin-tillator and a 137Cs source as a standard measurement. If other scintillators or γ-ray sources are used, note is attached.(Refer to section 13.2 on page 14 for further details.)
!5 Stability
<Long Term Stability (Mean Gain Deviation)>This is defined as follows under the operation for 16 hours at a constant count rate of 1000 s-1:
where P is the mean pulse height averaged over n readings, Pi is the pulse height at the i-th reading, and n is the total number of readings.
<Short Term Stability>This is the gain shift on count rate charge. The tube is first oper-ated at about 10000 s-1. The photo-peak count rate is then de-creased to about 1000 s-1 by increasing the distance between the 137Cs source and the tube coupled to the NaI(Tl) scintillator.(Refer to section 9 on page 6 for further details.)
!6 Pulse Linearity
Typical values of pulse linearity are specified at two points (±2 % and ±5 % deviation points from linear proportionality).(Refer to section 7 on page 5 and 6 for further details.)
nDg =
nΣ
i =1P-Pi
P
100 • (%)
(at 25 °C)
20
Photomultiplier Tubes
TubeDiameter
TypeNo.
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
300 to 650/A-D
160 to 650/C-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-E
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-E
300 to 650/A-D
300 to 650/A-D
300 to 650/A-E
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
185 to 650/B-D
300 to 650/A-D
300 to 650/A-D
E678-11N*
E678-11N*
E678-13F*
E678-13F*
E678-13E*
E678-12L*
E678-12L*
E678-12L*
E678-12R*
E678-12L*
E678-12A*
E678-14T*
E678-14C*
E678-12A*
E678-17A*
E678-12A*
E678-12A*
E678-12A*
E678-14C*
E678-14C*
E678-14C*
E678-14C*
E678-12A*
E678-12A*
E678-12A*
E678-12A*
—
E678-12A*
z
z
x
c
v
v
b
n
⁄1
,
⁄2⁄3
⁄1
⁄4
⁄4
⁄4
LINE / 8
LINE / 8
LINE / 10
LINE / 10
LINE / 10
LINE / 10
LINE / 10
LINE / 8
LINE / 10
LINE / 10
LINE / 10
LINE / 10
LINE / 10
LINE / 10
FM / 15
LINE / 10
LINE / 10
LINE / 8
B+L / 9
LINE / 10
LINE / 10
LINE / 8
LINE / 10
CC / 10
CC / 10
LINE / 6
FM / 19
LINE / 8
100
100
110
100
30
110
115
115
30
115
90
30
90
70
80
95
95
95
90
95
90
95
95
100
90
95
80
95
10.0
10.0
10.0
10.0
4.5
10.5
11.0
11.0
4.5
11.0
10.5
4.5
10.5
9.0
9.5
11.0
11.0
11.0
10.5
11.0
10.5
11.0
11.0
11.5
10.5
11.0
9.5
11.0
25
25
25
25
12
26
27
27
12
27
26
12
26
22
23
27
27
27
26
27
26
27
27
28
26
27
23
27
1.0 × 106
1.0 × 106
1.4 × 106
1.0 × 106
5.0 × 105
1.0 × 106
1.7 × 106
1.7 × 106
3.3 × 105
8.7 × 105
5.5 × 105
3.3 × 105
2.0 × 106
5.7 × 106
5.0 × 105
2.0 × 106
1.7 × 106
2.6 × 106
1.1 × 106
1.3 × 106
5.0 × 106
2.0 × 106
2.0 × 106
5.0 × 105
2.0 × 105
1.1 × 106
7.9 × 105
1.0 × 106
5.0 × 105
1.0 × 104
1.0 × 107
5.0 × 105
100
100
150
100
15
110
200
200
10
100
50
10
180
400
40
190160
250
100
120
475190
180
451910075
100
45
0.95
800
47
1
2
1
1
0.5
1
3
10
0.1
10
3
0.1
3
100
5
22
2
5
2
104
3
5232
3
3
2
15
10
50
50
2
15
10
5
50
300
10
50
20
10
20
800
30
1520
15
50
10
20080
20
100402015
5
5
15
100
100
1250
1250
1000
1000
1500
1000
1500
1700
1500
1500
1000
1500
1000
2250
2000
12501500
1000
1300
1000
15001500
1000
1500150012501500
1000
1000
1250
2000
1300
t
u
!7
@9
!7
@0
@6
!2
@8
@1
@8
@8
@8
!9
1
@9
#0
@9
!1
!5
#2
#3
@8
i
o
@3
@5
@3
@3
q
2
!1
q
q
e
w
e
r
t
y
u
t
u
i
i
o
!0
!1
!2
!3
!4
!5
!6
!7
!8
!9
@0
!8
@1
@2
R1635
R2496
R647-01
R4124
R4177-06
R1166
R1450
R3478
R3991A-04
R4125
R5611A-01
R1288A-06
R1924A
R4998
R5505-70
R7899-01
R8619
R9800
R3998-02
R6427
R7111
R7525
R580
R980
R3886
R5330
R7761-70
R9420
10 mm(3/8")
13 mm(1/2")
19 mm(3/4")
25 mm(1")
28 mm(1-1/8")
38 mm(1-1/2")
q w
Socket&
SocketAssembly
Cathode Sensitivity Anode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
yAnode toCathodeSupplyVoltage
(V) (A/lm) (nA)Typ.
(nA)Max.
i
LuminousTyp.
(µA/lm)
t
LuminousTyp.
DarkCurrent
!0 !1
GainTyp.
o
Q.E.at Peak
Typ.
(%)
u
10 mm (3/8 inch) to 38 mm (1-1/2 inch) Dia. Types
Note: The data shown in is measured with tapered voltage distribution ratio. Please refer to page 18 and 19 for each item in the above list.
21
1500
1500
1250
1250
1800
1250
1800
1800
1800
1800
1250
1800
1250
2500
2300
18001800
1500
1500
1500
20002000
1250
1750175017501750
1250
1250
1600
2300
1500
0.03
0.03
0.1
0.03
0.02
0.1
0.1
0.1
0.02
0.1
0.1
0.02
0.1
0.1
0.01
0.10.1
0.1
0.1
0.1
0.20.2
0.1
0.20.20.10.1
0.1
0.1
0.1
0.01
0.1
0.8
0.7
2.1
1.1
2.0
2.5
1.8
1.3
1.0
2.5
1.3
1.3
1.5
0.7
1.5
1.61.6
2.5
1.0
3.4
1.71.8
1.6
1.31.32.72.7
2.8
2.5
2.5
2.1
1.6
9
9
22
12
20
27
19
14
10
16
12
13
17
10
5.6
1716
28
11
23
1617
18
14153740
40
32
25
7.5
17
0.5
0.5
2.0
0.5
—
2.8
0.76
0.36
—
0.85
0.8
—
0.9
0.16
0.35
0.60.7
1.2
0.27
3
0.50.5
0.9
——4.54.5
4.8
2.2
—
0.35
0.55
1.0
1.0
1.0
1.0
2.0
1.0
1.0
1.0
2.0
1.0
1.0
1.0
1.0
1.0
2.0
1.01.0
1.0
1.0
1.0
1.01.0
1.0
1.01.01.01.0
1.0
1.0
1.0
2.0
1.0
23 / BGO *1
23 / BGO *1
7.8
8.1
12.0
7.8
7.8
7.8
11.0
7.8
8.0
9.0
7.8
8.0
9.5
7.87.8
10 / LSO
7.8
7.5
7.87.8
7.8
7.87.87.77.7
7.6
7.6
7.7
9.5
7.8
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.0
2.02.0
2.0
2.0
1.0
2.02.0
2.0
2.02.01.01.0
1.0
2.0
2.0
2.0
2.0
3
3
3
2
8
4
4
4
20
100
10
20
30
40
180
30100
5
30
8
10100
30
1010040150
1
1
80
350
30
7
7
7
5
13
7
8
8
40
170
10
40
50
70
250
50150
8
50
10
30150
50
3015060200
3
3
120
500
50
UV type (R3878)
SILICA (R760) and UV (R960) types
UV type (R4141)
Flying Lead type (R4177-04)
SILICA (R762) and UV (R750) types
SILICA (R2076) and UV (R3479) types
Glass Base type (R5611A)
Flying Lead type (R1924A-01)
SILICA type (R5320)
For +HV operation
Glass Base type (R7899)
UV type (R7056)
For +HV operation
H3164-10
H3695-10
H3165-10
H6520
H6524
H6612
H8135
H6533
H6152-70
H8643
H10580
H7415
H3178-51
TypeNo.
Note AssemblyType
R1635
R2496
R647-01
R4124
R4177-06
R1166
R1450
R3478
R3991A-04
R4125
R5611A-01
R1288A-06
R1924A
R4998
R5505-70
R7899-01
R8619
R9800
R3998-02
R6427
R7111
R7525
R580
R980
R3886
R5330
R7761-70
R9420
TypicalPulseHeight
Resolution
!4
Anodeto
CathodeVoltage
(V)
LongTerm
(%)
ShortTerm
(%)
±2 %Deviation
(mA)
±5 %Deviation
(mA)
AverageAnodeCurrent
(mA)
RiseTimeTyp.
(ns)
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Time Response !3 Stability !5 Pulse Linearity !6
(%)
Note 1: This data is measured with 22Na source and BGO scintillator.
(at 25 °C)
22
TubeDiameter
TypeNo.
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-E
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
185 to 650/B-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
¤0
¤0
⁄7⁄8
⁄6
⁄5
⁄9
⁄9
⁄7⁄8
¤0
⁄9
¤1¤2
¤3
¤1¤2
¤3
¤3
¤3
E678-21C*
E678-21C*
E678-14W
E678-20A*
E678-14W
E678-19J*
E678-14W
E678-15C*
—
E678-14W
E678-21C*
E678-21C*
E678-21C*
E678-20A*
E678-14W
E678-14W
E678-14W
E678-20A*
E678-21C*
E678-14W
E678-14W
E678-20A*
E678-14W
E678-20A*
E678-20A*
E678-20A*
E678-20A*
E678-20A*
E678-20A*
E678-20A*
E678-20A*
E678-20A*
LINE / 12
LINE / 12
BOX / 8
LINE / 12
CM / 10
LINE / 8
LINE / 10
CC / 10
FM / 19
B+L / 8
LINE / 8
LINE / 10
LINE / 12
LINE / 8
B+L / 8
BOX / 8
CM / 12
LINE / 12
LINE / 12
B+L / 8
BOX / 10
LINE / 14
VB / 10
LINE / 14
B+L / 10
B+L / 10
B+L / 14
B+L / 10
B+L / 14
B+L / 10
VB / 11
B+L / 10
90
90
110
90
60
80
90
30
70
110
90
90
90
95
110
110
60
80
90
110
95
70
95
70
80
80
80
80
80
60
60
60
10.5
10.5
30
10.5
8.0
10.0
10.5
4.5
9.0
12.0
10.5
10.5
10.5
11.0
12.0
12.0
8.0
9.5
10.5
12.0
11.0
9.0
11.0
9.0
10.0
10.0
10.0
10.0
10.0
8.0
8.0
8.0
26
26
30
26
20
25
26
12
22
30
26
26
26
27
30
30
20
23
26
30
27
22
27
22
25
25
25
25
25
20
20
20
1.1 × 106
3.0 × 106
1.3 × 106
2.7 × 105
2.0 × 107
1.0 × 107
1.7 × 105
1.3 × 105
2.5 × 106
1.0 × 106
6.0 × 105
3.3 × 105
1.0 × 107
2.7 × 105
1.0 × 106
3.3 × 106
6.7 × 106
5.0 × 105
2.7 × 105
2.7 × 105
5.0 × 105
4.0 × 105
5.0 × 106
5.6 × 105
5.0 × 106
1.0 × 107
2.7 × 105
4.2 × 105
1.4 × 107
4.0 × 107
1.1 × 106
1.4 × 107
3.0 × 106
2.0 × 106
1.0 × 107
1.0 × 109
1.0 × 107
1.0 × 109
5.0 × 107
1.0 × 107
1.0 × 107
100270
120
30
1800900108
200
9054
10
700
30
90
300
600
47.5
30
30
302340045450900
30
40
10002800
100
1000
240160
700
70 000
800
80 000
3000
600
600
610
1000 s-1*2
2
502555
100
53
3
30
2
3
6
9
15
2
2
5550101030
2
10
50300
20
50
3020
50
1000
50
1000
200
200
200
40100
2000 s-1*2
20
4002005050
800
2015
50
200
20
20
40
60
100
20
20
50505005060120
20
50
3001800
100
300
300200
700
5000
700
5000
1000
1000
1000
15002000
1500
1000
2500250012501250
3000
12501500
1500
2000
1000
1750
1750
1750
1500
1000
1000
125012502500250015002000
1000
1250
20002500
1500
2000
15001500
1500
1700
1500
1700
2000
2000
2000
%0
%3
%0
e
$4
$5
@3
@4
!3
@3
@5
@3
2
y
!0
#4
%1
r
y
e
$6
$7
$2
$3
%0
%3
y
!8
%6
%7
!8
%6
#5
#6
%8
0
%8
0
%9
#9
%9
@3
@4
@5
@6
@7
@8
@9
#0
#1
#2
#3
#3
#3
#4
#5
#6
#7
#8
#9
$0
$1
$2
$1
$3
$4
$5
$5
$6
$6
$7
$8
$9
R329-02
R331-05
R1306
R1828-01
R1840
R2083
R2154-02
R4607-06
R5924-70
R6231
R7723
R7724
R7725
R9779
R6232
R1307
R2238
R4143
R6091
R6233
R877
R1250
R1512
R1584
R6594
R5912
R5912-02
R7081
R7081-20
R8055
R3600-02
R7250
51 mm(2")
60 mm
76 mm(3")
127 mm(5")
204 mm(8")
254 mm(10")
508 mm(20")
q w
Socket&
SocketAssembly
Cathode Sensitivity Anode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
yAnode toCathodeSupplyVoltage
(V) (A/lm) (nA)Typ.
(nA)Max.
i
LuminousTyp.
(µA/lm)
t
LuminousTyp.
DarkCurrent
!0 !1
GainTyp.
o
Q.E.at Peak
Typ.
(%)
u
51 mm (2 inch) to 508 mm (20 inch) Dia. Types
Note: The data shown in is measured with tapered voltage distribution ratio. Please refer to page 18 and 19 for each item in the above list.
Note 2: Dark count
332 mm(13")
23
27002700
2500
1500
3000300015001500
3500
17501750
1800
2300
1500
2000
2000
2000
1750
1500
1500
150015003000300025002500
1500
1500
30003000
2000
3000
20002000
2000
2000
2000
2000
2500
2500
2500
0.20.2
0.2
0.1
0.20.20.10.1
0.2
0.10.1
0.02
0.1
0.1
0.2
0.2
0.2
0.1
0.1
0.1
0.10.10.20.20.20.2
0.1
0.1
0.20.2
0.1
0.2
0.10.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
2.62.7
2.6
7.0
1.31.75.05.0
0.7
3.43.4
2.5
2.5
8.5
1.7
2.1
2.5
1.8
9.5
8.0
5.55.51.81.82.62.7
9.5
20.0
2.52.2
15.0
2.5
3.53.5
3.8
4.0
4.3
4.5
5.3
10
7.0
4840
48
60
28321517
16
3133
29
9.5
48
23
29
35
20
52
64
172132364840
52
90
5453
82
54
4545
55
68
63
78
88
95
110
1.11.1
1.1
—
0.550.550.71.3
0.37
3.63.6
—
0.44
11.7
1.1
1.2
1.3
0.25
12.2
—
——0.60.62
1.5
12.2
—
1.21.2
—
1.2
1.51.5
2.4
2.8
2.9
3.3
2.8
5.5
3.5
1.01.0
—
0.5
1.01.00.50.5
1.0
1.01.0
2.0
2.0
0.5
1.0
1.0
1.0
1.0
0.5
0.5
0.50.51.01.01.01.0
0.5
0.5
1.01.0
0.5
—
——
—
—
—
—
—
—
—
7.67.6
—
6.3 (8.5) *3
7.87.88.58.5
7.8
7.67.6
10.0
9.5
6.3 (8.5) *3
7.6
7.6
7.6
7.6
6.3 (8.5) *3
6.3 (8.5) *3
8.58.57.87.87.87.8
6.3 (8.5) *3
8.0
8.38.3
8.0
—
——
—
—
—
—
—
—
—
1.01.0
—
0.5
1.01.01.01.0
2.0
1.01.0
2.0
2.0
0.5
1.0
1.0
1.0
1.0
0.5
0.5
1.01.01.01.01.01.0
0.5
0.5
1.01.0
1.0
—
——
—
—
—
—
—
—
—
15100
15
1
10025080200
100
50150
1
500
5
80
60
40
50
5
1
2005001001504080
5
10
100160
5
100
30100
20
40
20
40
60
20
60
30200
30
5
200500200400
150
70200
5
700
10
100
90
80
80
10
5
50065018025060110
10
20
150250
20
150
50150
40
70
40
70
80
40
80
SILICA type (R2256-02) UV type (R5113-02)
K-FREE type (R1306-15)
SILICA type (R2059) UV type (R4004)
SILICA type (R3377)
Glass Base type (R3149)
For +HV operation
Flying Lead type (R6231-01)
Flying Lead type (R6232-01)
K-FREE type (R1307-07)
UV type (R4885)
Flying Lead type (R6233-01)
K-FREE type (R877-01)
H6410 / H7195
H1949-50 / H1949-51
H2431-50
H6614-70
H10570
R2238-01
H6525
H6559
H6527
H6528
R3600-06
TypeNo.
(at 25 °C)
R329-02
R331-05
R1306
R1828-01
R1840
R2083
R2154-02
R4607-06
R5924-70
R6231
R7723
R7724
R7725
R9779
R6232
R1307
R2238
R4143
R6091
R6233
R877
R1250
R1512
R1584
R6594
R5912
R5912-02
R7081
R7081-20
R8055
R3600-02
R7250
TypicalPulseHeight
Resolution
!4
Anodeto
CathodeVoltage
(V)
LongTerm
(%)
ShortTerm
(%)
±2 %Deviation
(mA)
±5 %Deviation
(mA)
AverageAnodeCurrent
(mA)
RiseTimeTyp.
(ns)
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Time Response !3 Stability !5 Pulse Linearity !6
(%)
Note 3: This data in parenthese is measured with 57Co.
Note AssemblyType
24
Square, Rectangular Shape Photomultipliers
TubeDiameter
TypeNo.
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
300 to 650/A-D
160 to 650/C-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
E678-12V
E678-12V
E678-32B
E678-32B
E678-32B
E678-32B
E678-32B
—
—
—
—
—
—
—
¤4¤5
¤4¤5
¤6
¤7
¤8
‹0
‹1
MC / 8
MC / 8
MC / 10
MC / 10
MC / 10
MC / 10
MC / 10
MC / 12
MC / 12
MC / 12
MC / 12
MC / 10
MC / 12
MC / 12
70
70
80
80
70
80
80
80
80
80
80
70
60
60
8.0
8.0
9.5
9.5
8.5
9.5
9.5
9.5
9.5
9.5
9.5
8.5
9.5
9.5
21
21
24
24
21
24
24
24
24
24
24
21
24
24
7.0 × 105
7.0 × 105
2.0 × 106
1.8 × 106
4.0 × 106
1.0 × 106
1.0 × 106
1.0 × 106
3.5 × 106
0.63 × 105
0.63 × 105
2.0 × 106
1.5 × 106
1.5 × 106
50
50
160
140
280
80
80
80
280
50
50
140
90
90
0.2
0.2
2
0.5/ch
0.2
2
1/ch
0.8/ch
0.8/ch
0.2/ch
0.2/ch
0.2
0.1/ch
0.05/ch
2
2
20
5/ch
2
20
5/ch
4/ch
4/ch
2/ch
2/ch
2
10/ch
5/ch
800
800
800
800
800
800
800
800
800
800
800
800
1000
1000
w
w
@2
@2
!7
!6
!6
$0
$8
$9
$9
!7
%4
%5
%0
%1
%2
%3
%4
%5
%6
%7
P56@8
P56@9
P56#0
P56#1
P57#2
P57#3
R7400U
R7400U-06
R7600U
R7600U-00-M4R5900U-00-L16
R8900U
R8900U-00-M4
R8900-00-M16
H8711
H7546B
H8804
H7260K
H8500C
H9500
16 mmTO-8type
30 mmsquare
type
Assem-blies
q w
Socket&
SocketAssembly
Cathode Sensitivity Anode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
yAnode toCathodeSupplyVoltage
(V) (A/lm) (nA)Typ.
(nA)Max.
i
LuminousTyp.
(µA/lm)
t
LuminousTyp.
DarkCurrent
!0 !1
GainTyp.
o
Q.E.at Peak
Typ.
(%)
u
Metal Package Photomultiplier and Assemblies
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
E678-17A*
—
—
, FM / 15
FM / 19
FM / 19
80
80
70
9.5
9.5
9.0
23
23
22
5.0 × 105
1.0 × 107
1.0 × 107
40
800
700
5
15
30
30
100
200
2000
2000
2000
1
2
2
!0
@1
#1
R5505-70
R7761-70
R5924-70
25 mm(1")
38 mm(1.5")
51 mm(2")
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
z
x
⁄9
⁄9
m
E678-11N*
E678-13F*
E678-14W
E678-14W
E678-17A*
E678-20A*
LINE / 8
LINE / 10
B+L / 8
B+L / 8
LINE / 10
L+VB / 10
95
100
110
110
80
80
9.5
9.5
12.0
12.0
9.5
9.5
23
23
30
30
23
23
1.1 × 106
1.0 × 106
2.7 × 105
2.7 × 105
2.5 × 106
1.2 × 106
100
100
30
30
200
100
1
1
2
2
20
10
50
15
20
20
250
200
1250
1000
1000
1000
1250
1250
t
!7
y
y
#2
#1
%8
%9
0
1
2
3
R2248
R2102
R6236
R6237
R1548-07
R8997
10 mm(3/8")
13 mm(1/2")
60 mm
76 mm(3")
25 mm(1")
38 mm(1-1/2")
Hexagonal Shape Photomultipliers300 to 650/A-D
300 to 650/A-D
300 to 650/A-D
⁄7⁄8
⁄9
⁄9
E678-14W
E678-14W
E678-14W
BOX / 8
B+L / 8
B+L / 8
110
110
110
12.0
12.0
12.0
30
30
30
2.7 × 105
2.7 × 105
2.7 × 105
30
30
30
2
2
2
20
20
20
1000
1000
1000
e
y
y
4
5
6
R1538
R6234
R6235
60 mm
60 mm
76 mm(3")
2π Shape Photomultipliers300 to 650/A-D
300 to 650/A-D
E678-12A*
E678-14C*
LINE / 10
BOX / 11
90
90
10.5
10.5
26
26
1.1 × 106
2.2 × 106
100
200
3
2
20
10
1000
1000
@8
#8
7
8
R7373A-01
R8143
25 mm(1")
28 mm(1-1/8")
Fine Mesh Photomultipliers
Note: Please refer to page 18 and 19 for each item in the above list.
25
1000
1000
900
900
900
900
900
1000
1000
1000
1000
900
1100
1100
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.017
0.023
0.023
0.1
0.1
0.1
0.78
0.78
1.4
1.2
0.60
1.8
1.4
1.3
0.83
1.0
1.0
0.60
0.8
0.8
5.4
5.4
9.6
9.5
7.4
12.4
11.4
13
12
12
12
6.8
6.0
6.0
0.28
0.28
0.35
0.36
0.18
0.8
0.95
0.75
0.33
0.38
0.38
0.18
0.4
0.4
1.0
1.0
1.0
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
2.0
2.0
2.0
—
—
—
—
—
—
—
—
—
—
—
15
15
30
10
0.8
30
5
1.5
0.5
0.3
0.3
0.6
1
0.2
30
30
60
30
1.2
60
10
3.5
1
0.6
0.6
0.8
2
1
UV type (R7400U-03) is available
UV type (R7600U-03) is available
*4
*4
*4
*4
*4, Assembly with divider network
*4, Assembly with divider network
*4, Assembly with divider network
*4, Assembly with divider network
*4, Assembly with divider network
*4, Assembly with divider network
TypeNo.
(at 25 °C)
Note
R7400U
R7400U-06
R7600U
R7600U-00-M4R5900U-00-L16
R8900U
R8900U-00-M4
R8900-00-M16
H8711
H7546B
H8804
H7260K
H8500C
H9500
2300
2300
2300
0.01
0.01
0.1
1.5
2.1
2.5
5.6
7.5
9.5
0.35
0.35
0.44
2.0
2.0
2.0
9.5
9.5
9.5
2.0
2.0
2.0
180
350
500
250
500
700
For +HV operation
For +HV operation
For +HV operation
R5505-70
R7761-70
R5924-70
1500
1250
1500
1500
1750
1600
0.03
0.1
0.1
0.1
0.1
0.1
0.9
2.1
9.5
9.5
1.8
5.0
9.0
22
52
52
20
25
0.6
2.2
12.2
12.2
1.0
2.8
1.0
1.0
0.5
0.5
1.0
2.0
23 / BGO*1
8.1
6.3 (8.5)*3
6.3 (8.5)*3
20 / BGO*1
16 / BGO*1
2.0
2.0
0.5
0.5
2.0
2.0
3
3
5
5
10
4
7
7
10
10
15
10
Flying Lead type (R6236-01) is available
Flying Lead type (R6237-01) is available
*4, Dual (2) channel
*4, Quadrant (4) channel
R2248
R2102
R6236
R6237
R1548-07
R8997
TypicalPulseHeight
Resolution
!4
Anodeto
CathodeVoltage
(V)
LongTerm
(%)
ShortTerm
(%)
±2 %Deviation
(mA)
±5 %Deviation
(mA)
AverageAnodeCurrent
(mA)
RiseTimeTyp.
(ns)
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Time Response !3 Stability !5 Pulse Linearity !6
(%)
1500
1500
1500
0.1
0.1
0.1
8.0
9.5
9.5
60
52
52
—
12.2
12.2
0.5
0.5
0.5
6.3 (8.5)*3
6.3 (8.5)*3
6.3 (8.5)*3
0.5
0.5
0.5
1
5
5
5
10
10
Flying Lead type (R1538-01) is available
Flying Lead type (R6234-01) is available
Flying Lead type (R6235-01) is available
R1538
R6234
R6235
1250
1250
0.1
0.1
2
25
19
72
1.1
—
1.0
1.0
7.8
8
2.0
2.0
15
0.2
30
0.5
R7373A-01
R8143
Note 1: This data is measured with 22Na source and BGO scintillator.Note 3: This data in parenthese is measured with 57Co.Note 4: Dark current, time response and pulse linearity data is typical value for channel.
26
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / F
300 to 650 / F
300 to 650 / F
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / G
300 to 650 / F
300 to 650 / F
300 to 650 / F
300 to 650 / F
300 to 650 / F
E678-32B
E678-32B
E678-32B
E678-32B
E678-32B
E678-32B
E678-32B
E678-32B
—
E678-32B
—
—
—
—
—
—
E678-14C
E678-12A
E678-14W
E678-14W
E678-14W
¤8
¤8
¤6
¤6
¤7
¤7
‹0
‹1
¤9
⁄0
⁄9
⁄9
¤1¤2
MC / 10
MC / 10
MC / 10
MC / 10
MC / 10
MC / 10
MC / 10
MC / 10
MC / 12
MC / 11
MC / 12
MC / 12
MC / 12
MC / 12
MC / 10
MC / 10
B+L / 9
L / 8
B+L / 8
B+L / 8
B / 10
105
135
105
135
105
135
105
105
105
105
105
135
105
135
105
135
130
130
130
130
130
13.5
15.5
13.5
15.5
13.5
15.5
13.5
13.5
13.5
13.5
13.5
15.5
13.5
15.5
13.5
15.5
13.5
13.5
13.5
13.5
13.5
35
43
35
43
35
43
35
35
35
35
35
43
35
43
35
43
35
35
35
35
35
3.0 × 106
3.0 × 106
1.0 × 106
1.0 × 106
1.3 × 106
1.3 × 106
1.0 × 106
1.0 × 106
1.0 × 106
5.4 × 105
2.0 × 106
2.0 × 106
3.0 × 105
3.0 × 105
2.0 × 106
2.0 × 106
1.0 × 106
3.7 × 105
2.3 × 105
2.3 × 105
3.1 × 105
320
400
105
135
140
175
105
105
105
70
210
270
30
40
210
270
130
48
30
30
40
0.2/ch
0.2/ch
2
2
0.5/ch
0.5/ch
2
1/ch
0.8/ch
2
0.8/ch
0.8/ch
0.2/ch
0.2/ch
0.2/ch
0.2/ch
5
10
10
10
20
2/ch
2/ch
20
20
5/ch
5/ch
20
5/ch
8/ch
20
4/ch
4/ch
2/ch
2/ch
2/ch
2/ch
25
100
30
30
100
800
800
800
800
800
800
800
800
800
800
800
800
800
800
800
800
1000
1300
1000
1000
1250
!7
!7
@2
@2
@2
@2
!6
!6
$0
#7
$8
$8
$9
$9
!7
!7
!5
!1
y
y
!8
%4
%4
%2
%2
%3
%3
%5
%6
%7
P44q
P56@8
P56@8
P56@9
P56@9
P56#1
P56#1
!4
@2
#2
$0
$1
R5900U-100-L16
R5900U-200-L16
R7600U-100
R7600U-200
R7600U-100-M4
R7600U-200-M4
R8900U-100
R8900U-100-M4
R8900-100-M16
R8900U-100-C12
H8711-100
H8711-200
H7546B-100
H7546B-200
H7260K-100
H7260K-200
R3998-100-02
R9420-100
R6231-100
R6233-100
R877-100
q w
Socket&
SocketAssembly
Cathode Sensitivity Anode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
yAnode toCathodeSupplyVoltage
(V) (A/lm) (nA)Typ.
(nA)Max.
i
LuminousTyp.
(µA/lm)
tAnode
LuminousSensitivity
Typ.
Dark Current(After 30 min)
!0 !1
GainTyp.
o
Q.E.at Peak
Typ.
(%)
u
UBA (Ultra Biallali), SBA (Super Bialkali) Photomultipliers
Notes: Please refer to page 18 and 19 for each item in the above list.
MetalPackage
PMT30 mmsquare
type
MetalPackage
PMTassem-
blies
19 mm(3/4")
38 mm(1-1/2")51 mm
(2")76 mm
(3")127 mm
(5")
TubeDiameter
TypeNo.
27
900
900
900
900
900
900
900
900
1000
1000
-1000
-1000
-1000
-1000
-900
-900
1500
1500
1500
1500
1500
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.017
0.017
0.023
0.023
0.1
0.1
0.1
0.1
0.1
0.1
0.1
0.6
0.6
1.4
1.4
1.2
1.2
1.8
1.4
1.3
2.2
0.83
0.83
1.0
1.0
0.6
0.6
3.4
1.6
8.5
9.5
20
7.4
7.4
9.6
9.6
9.5
9.5
12.4
11.4
13
11.9
12
12
12
12
6.8
6.8
23
17
48
52
90
0.18
0.18
0.35
0.35
0.36
0.36
0.8
0.95
0.75
0.75
0.33
0.33
0.38
0.38
0.18
0.18
3
0.55
11.7
12.2
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
1.0
1.0
0.5
0.5
0.5
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
7.0
7.0
6.1
6.2
7.6
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
—
1.0
2.0
0.5
0.5
0.5
0.8/ch
0.8/ch
30
30
10/ch
10/ch
30
5/ch
—
2
0.5/ch
0.5/ch
0.3/ch
0.3/ch
0.6/ch
0.6/ch
8
30
5
5
10
1.2/ch
1.2/ch
60
60
30/ch
30/ch
60
10/ch
3.5
15
1/ch
1/ch
0.6/ch
0.6/ch
0.8/ch
0.8/ch
10
50
10
10
20
SBA type
UBA type
SBA type
UBA type
SBA type
UBA type
SBA type
SBA type
SBA type
SBA type
SBA type
UBA type
SBA type
UBA type
SBA type
UBA type
SBA type
SBA type
SBA type
SBA type
SBA type
Type No.
(at 25 °C)
R5900U-100-L16
R5900U-200-L16
R7600U-100
R7600U-200
R7600U-100-M4
R7600U-200-M4
R8900U-100
R8900U-100-M4
R8900-100-M16
R8900U-100-C12
H8711-100
H8711-200
H7546B-100
H7546B-200
H7260K-100
H7260K-200
R3998-100-02
R9420-100
R6231-100
R6233-100
R877-100
TypicalPulseHeight
Resolution
!4
Anodeto
CathodeVoltage
(V)
LongTerm
(%)
ShortTerm
(%)
±2 %Deviation
(mA)
±5 %Deviation
(mA)
AverageAnodeCurrent
(mA)
RiseTimeTyp.
(ns)
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Time Response !3 Stability !5 Pulse Linearity !6
(%)
Note
28
Dimensional Outline and Basing DiagramsFor Photomultiplier Tubesq R1635, R2496 w R4124
e R647-01, R4177-06 r R1166
t R1450, R4125 y R3478
TPMHA0343EB
13.5 ± 0.5
10 MIN.
50 ±
213
MA
X.
13 PIN BASE
PHOTOCATHODE
FACEPLATE
12
3
4
56 7 8
9
10
11
1213
ICDY1
DY3
DY5
DY7
DY9P
DY10
DY8
DY6
DY4
DY2
K
SHORT PIN
TPMHA0102EA
12
3
4
56
7
8
9
1011
IC
DY1
DY3
DY5
DY7
SHORT PIN
DY8
DY6
DY4
DY2
K
FACEPLATE
PHOTOCATHODE
11 PIN BASE
8 MIN.
10 M
AX
.45
.0 ±
1.5
A
P
A
R1635
R2496
R2496 has a plano-concave faceplate.
9.7 ± 0.4
10.5 ± 0.5
TPMHA0120EA
13 PIN BASE
PHOTOCATHODE
FACEPLATE
B
A
10 MIN.
13 M
AX
.
A B
R647-01
R4177-06
13.5 ± 0.5
14.5 ± 0.7
71 ± 2
61 ± 2
12
3
4
56 7 8
9
10
11
1213DY3
DY5
DY7
DY9
PDY10
SHORT PIN
DY8
DY6
DY4
DY2
KDY1IC
15 MIN.
18.6 ± 0.7
FACEPLATE
PHOTOCATHODE
88 ±
213
MA
X.
12 PIN BASE
DY3
DY5
DY7
DY9
P
SHORT PIN
12
3
4
56 7
8
9
10
1112
DY10 DY8
DY6
DY4
DY2
K
DY1
TPMHA0344EA
15 MIN.
18.6 ± 0.7
FACEPLATE
PHOTOCATHODE
88 ±
213
MA
X.
12 PIN BASE
DY3
DY5
DY7
DY9
P
SHORT PIN
12
3
4
56 7
8
9
10
1112
DY10 DY8
DY6
DY4
DY2
K
DY1
TPMHA0307EA TPMHA0431EB
FACEPLATE
PHOTOCATHODE
15 MIN.
18.6 ± 0.7
65 ±
213
MA
X.
12 PIN BASE
DY3
DY5
DY7
IC
P
IC
SHORT PIN
12
3
4
56 7
8
9
10
1112
DY8
DY6
DY4
DY2
K
DY1
29
(Unit: mm)
u R3991A-04, R5611A-01 i R1288A-06, R1924A
TPMHA0117EB TPMHA0040EC
12
3
4
56
7 89
10
11
12
1314
KDY1
DY6
DY5
DY7
DY9P IC
IC
DY10
DY8
DY3
DY4DY2
SHORT PIN
25.4 ± 0.5
22 MIN.
13 M
AX
.43
.0 ±
1.5
FACEPLATE
PHOTOCATHODE
14 PIN GLASS BASE
o R4998
TPMHA0093ED
!0 R5505-70
25.8 ± 0.7
17.5 MIN.
40.0
± 1
.513
MA
X.
FACEPLATE
PHOTO-CATHODE
HA COATING
17 PIN BASE
1716
1514
1312
1011
987
65
4
32
1
P
DY 4DY 6
DY 8
DY 7
DY 5
DY 3
K
DY 15DY 13
DY 14
DY 10
DY 1
DY 11DY 12
DY 2
DY 9
SHORT PIN
TPMHA0236EA
!1 R7899-01 !2 R8619
TPMHA0474EA TPMHA0551EB
4
32
1
12
135
6
14
1516
18
DY9
DY7
DY5
DY3DY1
P DY10
DY8
DY6
DY4
DY2
K
DY1
DY3
DY5
DY7
DY9P
12
3
4
56 7
8
9
10
1112
DY10
DY8
DY6
DY4
DY2
K
A Temporary Base Removed
B Bottom View
79 ±
213
MA
X.
22 MIN.
25.4 ± 0.5
PHOTOCATHODE
FACE PLATE
SEMIFLEXIBLELEADS
37.3 ± 0.5
A
B
12 PIN BASE JEDECNo. B12-43
A TEMPORARY BASE REMOVED
A
R3991A-04
R5611A-01
28 ± 1.5
30 ± 1.5
12PIN BASEJEDEC No.B12-43
PHOTOCATHODE
FACEPLATE
A
18.6 ± 0.7
13 M
AX
.
45 M
IN.
15 MIN.
A
B37.3 ± 0.5
SEMIFLEXIBLELEADS
DY3
DY5
DY7
DY9
P DY10
12
3
4
56 7
8
9
10
1112
DY8
DY6
DY4
DY2
KDY1
DY1
DY3
DY5
DY7
P
DY9 DY10
DY8
DY6
DY4
DY2K
12
3
4
5
69
10
11
121314
B BOTTOM VIEW
12
3
4
5
12
18
P
DY1
DY3
DY5
DY7(Acc)
DY9
DY10DY8
DY6
DY4
DY2
G
K
12
3
4
5
67
8
9
1011
12
P
DY1DY3
DY5
DY7(Acc)
DY9
DY10
DY8
DY6
DY4
DY2
GK
13
14
15
16
17
A Temporary Base Removed
26 ± 1
20 MIN.
71 ±
1
13 M
AX
.
52 M
IN.
A
HA COATING
SMA CONNECTOR
B
37.3 ± 0.5
PHOTOCATHODE
FACEPLATE
12 PIN BASEJEDECNo. B12-43
B Bottom View
SEMIFLEXIBLELEADS
3
4
5
67
10
18
DY1
DY3
DY5
DY7
DY9
PDY10
DY8
DY6
DY4
DY2
K
1112
13
14
17
A TEMPORARY BASE REMOVED
B BOTTOM VIEW
25.4 ± 0.5
22 MIN.
68.0
± 1
.5
13 M
AX
.
50 M
IN.
FACEPLATE
PHOTO-CATHODE
12 PIN BASEJEDECNo. B12-43
A
SEMIFLEXIBLELEADS
B
37.3 ± 0.5
12
3
4
56 7
8
9
10
1112
DY1
DY3
DY5
DY7
DY9 DY8
DY6
DY4
DY2
K
P DY10
30
5
13
810
146
127
15
1
DY3
DY1
DY5
DY7P
DY8
DY6
DY4
DY2
K
DY1
DY3
DY5
DY7
NCP
12
3
4
56 7
8
9
10
1112
NC
DY8
DY6
DY4
DY2
K
A Temporary Base Removed
B Bottom View
FACE PLATE
55 ±
213
MA
X.
22 MIN.
25.4 ± 0.5
PHOTOCATHODE
SEMIFLEXIBLELEADS
37.3 ± 0.5
A
B
12 PIN BASE JEDECNo. B12-43
!3 R9800 !4 R3998-02, R3998-100-02
!5 R6427
28.5 ± 0.5
25 MIN.FACEPLATE
PHOTOCATHODE
85 ±
213
MA
X.
14 PIN BASE
12
3
4
56
7 89
10
11
12
1314
ICDY3
DY2
DY7
DY9
ICP DY10
DY8
DY6
DY4
DY5
KDY1
SHORT PIN
TPMHA0387EB
TPMHA0521EB TPMHA0114EA
!6 R7111
TPMHA0506EA
12
3
4
56
7 89
10
11
12
1314
KDY1
DY6
DY5
DY7
DY9P IC
IC
DY10
DY8
DY3
DY4DY2
SHORT PIN
28.5 ± 0.5
25 MIN.FACEPLATE
PHOTOCATHODE
43.0
± 1
.513
MA
X.
14 PIN BASE
!7 R7525
12
3
4
56
7 89
10
11
12
1314
ICDY3
DY2
DY5
DY7
ICP DY8
DY6
IC
DY4
IC
KDY1
SHORT PIN
28.5 ± 0.5
25 MIN.FACEPLATE
PHOTOCATHODE
85 ±
213
MA
X.
14 PIN BASE
TPMHA0450EB
!8 R580, R5330
TPMHA0121EA
FACEPLATE
PHOTO-CATHODE
14 PIN BASE
28.5 ± 0.5
25 MIN.
60 ±
213
MA
X.
12
3
4
56
7 89
10
11
12
1314
GDY2
DY3
IC
DY6
DY8P DY9
DY7
DY5
IC
DY4
DY1K
SHORT PIN
37.3 ± 0.5
12 PIN BASEJEDECNo. B12-43
34 MIN.FACEPLATE 38 ± 1
PHOTO-CATHODE
109
± 2
127
MA
X. DY1
DY3
DY5
DY7
DY9
P
12
3
4
56 7
8
9
10
1112
DY10
DY8
DY6
DY4
DY2
K
DY1
DY3
DY5
IC
IC
P
12
3
4
56 7
8
9
10
1112
IC
IC
DY6
DY4
DY2
K
R580
R5330
31
(Unit: mm)
!9 R980
37.3 ± 0.5
12 PIN BASEJEDECNo. B12-43
34 MIN.FACEPLATE 38 ± 1
PHOTO-CATHODE
99 ±
2
116
MA
X. DY1
DY3
DY5
DY7
DY9
P
12
3
4
56 7
8
9
10
1112
DY10
DY8
DY6
DY4
DY2
K
TPMHA0228EA
@0 R3886
TPMHA0104EA
@1 R7761-70 39 ± 1
27 MIN.
50 ±
213
MA
X.
27
DY1DY3
DY5
DY7
DY9
DY11DY13
DY15DY17 DY19 P
DY18DY16
DY14
DY12
DY10
DY8
DY6DY4
DY2K
11 1213
14151617
1819
20211
23
4567
89
10
FACEPLATE
PHOTO-CATHODE
SEMIFLEXIBLELEADS 0.7
HA COATING
TPMHA0469EC
@3 R329-02
TPMHA0123EF
123
4567
98
11121314
151617
1819
2021
DY1DY3
DY5
DY2
P
DY9DY11
DY12IC
SH IC DY10DY8
DY6DY4
DY7
G
IC
ICIC
K
10
21 PIN BASE
46 MIN.FACEPLATE53.0 ± 1.5
127
± 2
HA COATING
13 M
AX
.
LIGHT TIGHT SHIELD
PHOTO-CATHODE
*CONNECT SH TO DY5
@2 R9420, R9420-100
TPMHA0519EC
5 13
4 14
2
6 12
7 11
1DY1
DY3
DY5
DY7
P DY8
DY6
DY4
DY2
K
DY1
DY3
DY5
DY7
NC
P
12
3
4
56 7
8
9
10
1112
NC
DY8
DY6
DY4
DY2
K
A Temporary Base Removed
B Bottom View87
± 2
13 M
AX
.
34 MIN.
38 ± 1
PHOTOCATHODE
FACE PLATE
SEMIFLEXIBLELEADS
37.3 ± 0.5
12 PIN BASE JEDECNo. B12-43
A
B
@4 R331-05
TPMHA0072EE
53.0 ± 1.5
46 MIN.FACEPLATE
PHOTO-CATHODE
HA COATING
21 PIN BASE
126
± 2
13 M
AX
.
50.0
± 0
.2
123
4567
98
10 11 12 1314
151617
1819
2021
DY1DY3
DY5
DY2
P
DY9
DY11
DY12IC
SH IC DY10DY8
DY6DY4
DY7
G
ICIC
ICK
*CONNECT SH TO DY5
SHORT PIN
P
DY1
DY3
DY5
DY7
DY9
P
12
3
4
56 7
8
9
10
1112
DY10
DY8
DY6
DY4
DY2
K
A Temporary Base Removed
B Bottom View
38.0 ± 0.7
34 MIN.
63.5
± 1
.570
MIN
.13 M
AX
.
DY3
DY5
DY7
DY9
DY10
DY8
DY6
DY4
DY2
K
3
4
5
6 10
11
12
13
1512
9
DY1
B
37.3 ± 0.5
PHOTO-CATHODE
FACEPLATE
12 PIN BASEJEDECNo. B12-43
A
SEMIFLEXIBLELEADS
32
@6 R1828-01
@7 R1840 @8 R2083
@9 R2154-02 #0 R4607-06
53.0 ± 1.5
46 MIN.FACEPLATE
PHOTO-CATHODE
170
± 3
192
MA
X.
HA COATING
52.5 MAX.
20 PIN BASEJEDECNo. B20-102
2
IC
34567
89 10 1112
1314151617
1819
201DY1DY3IC
DY5
DY7
DY9DY11
ICP DY12
DY10DY8
DY6
DY4
DY4DY2
ICG
K
TPMHA0064ED
TPMHA0095EB
19 PIN BASE
46 MIN.
53.0 ± 1.5
PHOTO-CATHODE
121
± 2
FACEPLATE
13 M
AX
.
HA COATING
SHORT PIN
12
345
76
98
10 1112
1314
15
1617
1819DY1
DY3
DY5
DY7
P
IC IC IC
ACC KG
IC
DY2
DY4
DY4
DY6DY8
SMA CONNECTOR
TPMHA0185ED
51.0 ± 0.5
46 MIN.FACEPLATE
PHOTO-CATHODE
124
± 2
147
MA
X.
56.5 ± 0.5
14 PIN BASEJEDECNo. B14-38
12
3
4
7 89
10
11
12
1314
DY1DY2
IC
DY4
DY5
DY6DY7 DY8
DY9
DY10
P
DY3
ICK
56
TPMHA0296EB
52 ± 1
46 MIN.FACEPLATE
PHOTOCATHODE
80 ±
213
MA
X.
15 PIN BASE
DY1
DY3
DY5
DY7
DY9
P
IC IC DY10
DY8
DY6
DY4
DY2
IC
K
12
3
4
56
7 8 910
11
12
1314
15
SHORT PIN
TPMHA0003EC
56.5 ± 0.5
14PIN BASEJEDEC No.B14-38
46 MIN.
51.0 ± 0.5
13 M
AX
.
55 ±
1
1DY2
65 M
IN.
PHOTO-CATHODE
FACEPLATE
A TEMPORARY BASE REMOVED
SEMIFLEXIBLELEADS
A
B
23
5
6
10
12
13
1516
1718DY4
DY6
DY8
DY10
P
DY9
DY7
DY5
DY3DY1K
12
3
4
56
7 89
10
11
12
1314
DY2IC
IC
DY6
DY8
DY10P DY9
DY7
DY5
DY3
DY4
DY1K
B BOTTOM VIEW
@5 R1306
12
3
4
56
7 89
10
11
12
1314
DY1DY2
IC
DY4
DY5
DY6DY7 DY8
IC
IC
P
DY3
GK
51.0 ± 0.5
46 MIN.
114
± 2
137
MA
X.
56.5 ± 0.5
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDEC No. B14-38
TPMHA0089EC
33
#1 R5924-70
(Unit: mm)
#2 R6231, R6231-100
51.0 ± 0.5
46 MIN.FACEPLATE
PHOTO-CATHODE
90 ±
3
113
MA
X.
56.5 ± 0.5
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
14 PIN BASEJEDEC No. B14-38
TPMHA0388EB
#3 R7723, R7724, R7725
TPMHA0509EC
123
4567
98
11121314
151617
1819
2021
DY1DY3
IC
DY2
P
DY5DY7
DY8IC
IC IC DY6IC
ICDY4
IC
IC
IC
ICIC
K
10
21 PIN BASE
46 MIN.FACEPLATE52 ± 1
112
± 2
13 M
AX
.
PHOTO-CATHODE
123
4567
98
11121314
151617
1819
2021
DY1DY3
DY5
DY2
P
DY7
DY9
DY10IC
IC IC DY8DY6
ICDY4
IC
IC
ICIC
ICK
10
123
4567
98
11121314
151617
1819
2021
DY1DY3
DY5
DY2
P
DY9DY7
DY11
DY12IC
IC IC DY10DY8
DY6DY4
IC
ICIC
ICK
10
R7723
R7724 R7725
#4 R9779
TPMHA0520EE
#5 R6232
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
59.5 ± 0.5
55 MIN.
100
± 3
123
MA
X.
56.5 ± 0.5
51.5 ± 1.5
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0510EA
#6 R1307
12
3
4
56
7 89
10
11
12
1314
DY1DY2
IC
DY4
DY5
DY6DY7 DY8
IC
IC
P
DY3
GK
76.0 ± 0.8
70 MIN.
127
± 3
150
MA
X.
56.5 ± 0.5
51.5 ± 1.5
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0078EA
DY1DY3DY5DY7
DY9DY11
DY13
DY15
DY17
DY19P
DY18 DY16DY14
DY12DY10
DY8
DY6
DY4
DY2
K
26
222120
1918
17161514
1110
9876
54
3 2 1
52 ± 1
39 MIN.
50 ±
213
MA
X.
31
FACEPLATE
PHOTO-CATHODE
HA COATING
SEMIFLEXIBLELEADS 0.7
5
14
15
173
6
1378
1012
1
DY1
DY3
Acc
DY5
DY7P
DY8
DY6
DY4
DY2
GK
Acc
DY1
DY3
DY5
ICIC IC
DY7
P IC
DY8
DY4
DY6
DY2
IC
ICIC
IC G
K
A TEMPORARY BASE REMOVED
B BOTTOM VIEW
1918
171615
1413
12111098
7654
32 1 20
98 ±
213
MA
X.
46 MIN.
51.0 ± 1.0
PHOTOCATHODE
FACEPLATE
SEMIFLEXIBLELEADS
52.5 MAX.
A
B
12 PIN BASE JEDECNo. B20-102
TPMHA0490EA
34
#7 R2238 #8 R4143
#9 R6091 $0 R6233, R6233-100
$1 R877, R877-100, R1512
13 M
AX
.
70 MIN.
55.0
± 1
.5
56.5 ± 0.5
FACEPLATE
PHOTO-CATHODE
76.0 ± 0.8
70 M
IN.
14PIN BASEJEDEC No. B14-38
SEMIFLEXIBLELEADS
A TEMPORARY BASE REMOVED
B
ADY4
DY6
DY8
DY10
DY12 P
DY 2 DY1DY3
DY5
DY7
DY9DY11
1
34
6
7
9 1112
1314
16
181920
12
3
4
7 89
10
11
12
1314
DY2DY4
DY3
DY8
DY10
DY12P DY11
DY9
DY7
DY5
DY6
DY1
K
56
B BOTTOM VIEW
TPMHA0076EC
10
12
34567
89 11 12
13141516
1718
1920DY1
DY3IC
DY5
DY7
DY9
DY11IC P
IC KG
DY2
DY4IC
DY6DY8
IC
DY10DY12
65 MIN.
77.0 ± 1.5
192
± 5
215
MA
X.
HACOATING
53.5 MAX.
FACEPLATE
PHOTO-CATHODE
20 PIN BASEJEDECNo. B20-102
TPMHA0112EC
TPMHA0285ED
76.0 ± 0.8
70 MINFACEPLATE
PHOTO-CATHODE
100
± 3
123
MA
X.
56.5 ± 0.5
14 PIN BASEJEDECNo. B14-38
51.5 ± 1.5
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
TPMHA0389EB
TPMHA0074EC
12
3
4
56
7 89
10
11
12
1314
DY1DY2
IC
DY4
DY5
DY6DY7 DY8
DY9
DY10
P
DY3
GK
133.0 ± 1.5
111 MIN.
171
± 3
194
MA
X.
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
56.5 ± 0.5
55 MAX.
76 ± 1
65 MIN.
137
± 2
FACEPLATE
PHOTO-CATHODE
21 PIN BASE
13 M
AX
.
* CONNECT SH TO DY5
123
4567
98
11 12 1314
151617
1819
2021
DY1DY3
DY5
DY2
P
DY9DY11
DY12IC
SH IC DY10DY8
DY6DY4
DY7
G
IC
ICIC
K
10
SHORT PIN
35
$2 R1250 $3 R1584
(Unit: mm)
TPMHA0018EC TPMHA0187ED
$4 R6594
TPMHA0373ED
$5 R5912, R5912-02
TPMHA0500EA
20-PIN BASEJEDEC No. B20-102
84.5 ± 2.0
52.5 MAX.
220
± 5
275
MA
X.
190 MIN.
202 ± 5
INPUT WINDOW
R131 PHOTOCATHODE
(Bottom View)
R5912
10
12
34567
89 11 12
13141516
1718
1920FOCUS3
DY3DY5DY7
IC
DY9P
IC IC
DY1 KFOCUS2
DY2
DY4
ICDY6
DY8
FOCUS1
DY10IC
(Bottom View)
R5912-02
10
12
34567
89 11 12
13141516
1718
1920DY3
FOCUS3DY5DY7
DY9
DY11DY13
P IC
DY1 KFOCUS2
DY4
FOCUS1
DY6DY8
DY10
DY2
DY12DY14
IC: Internal Connection(Do not use)
10
123
4567
89 1112
13141516
1718
1920DY1
DY3DY5
DY7
DY9
DY11
DY13IC P
IC KG
DY2
DY4DY6
DY8DY10
IC
DY12DY14
133 ± 2
120 MIN.
259
± 5
276
± 5
52.5 MAX.
20 PIN BASEJEDEC No. B20-102
FACEPLATE
PHOTOCATHODE
HA COATING
R132
$6 R7081, R7081-20
TPMHA0501EA
20-PIN BASEJEDEC No. B20-102
84.5 ± 2.0
52.5 MAX.
245
± 5
300
MA
X.
220 MIN.
253 ± 5INPUT WINDOW
R136.7
PHOTOCATHODE
(Bottom View)
R7081
10
12
34567
89 11 12
13141516
1718
1920FOCUS3
DY3DY5DY7
IC
DY9P
IC IC
DY1 KFOCUS2
DY2
DY4
ICDY6
DY8
FOCUS1
DY10IC
(Bottom View)
R7081-20
10
12
34567
89 11 12
13141516
1718
1920DY3
FOCUS3DY5DY7
DY9
DY11DY13
P IC
DY1 KFOCUS2
DY4
FOCUS1
DY6DY8
DY10
DY2
DY12DY14
IC: Internal Connection(Do not use)
$7 R8055
TPMHA0502EA
20-PIN BASEJEDEC No. B20-102
202 ± 3
52.5 MAX.
213 ± 3
333
± 5
368
MA
X.
312 MIN.
332 ± 5
INPUT WINDOW
R223.4
PHOTOCATHODE
METAL STEM FLANGE
(Bottom View)
10
12
34567
89 11 12
13141516
1718
1920FOCUS3
DY3DY5
IC
DY7
DY9IC
P IC
DY1 KIC
FOCUS2
DY2
DY4DY6
DY8
FOCUS1
ICDY10
IC: Internal Connection(Do not use)
10
123
4567
89 1112
13141516
1718
1920DY1
DY3DY5
DY7
DY9
DY11
DY13IC P
IC KG
DY2
DY4DY6
DY8DY10
IC
DY12DY14
133 ± 2
120 MIN.
259
± 5
276
± 5
52.5 MAX.
20 PIN BASEJEDECNo. B20-102
FACEPLATE
PHOTO-CATHODE
HA COATING
84.5 ± 2
PHOTOCATHODE
R82
.5 ±
2.0
178
± 2
70 M
IN.
265
MA
X.
20 PIN BASEJEDEC No. B20-102
52.5 MAX.
13 M
AX
.
128 ± 2
110 MIN.
A
B
SEMIFLEXIBLELEADS
10
123
4567
89 1112
13141516
1718
1920
FOCUS3DY3
DY5
DY7
IC
DY9P
IC IC
DY1 KFOCUS2
FOCUS1
DY4
ICDY6
DY8
DY2
DY10IC
12
4
78
9 10
615
14
16
1920
2123FOCUS3
DY3
DY5
DY7DY9
P
DY1 K FOCUS2
FOCUS1
DY4DY6
DY8
DY2
DY10
B BOTTOM VIEW
A TEMPORARY BASE REMOVED
36
$8 R3600-02 $9 R7250
%0 R7400U %1 R7400U-06
%2 R7600U, R7600U-100/-200 %3 R7600U-00-M4, R7600U-100-M4/-200-M4
TPMHA0092EE TPMHA0475ED
10.1
6
5.08
10.16
5.08
12- 0.45
INSULATION COVER (Polyoxymethylene)
PHOTOCATHODE8 MIN.
0.5 ± 0.2
11.5 ± 0.4 4.0 ± 0.3
Bottom ViewSide View
5 ± 1SHORT PINGUIDE MARK
5
.4 ±
0.3
DY4
DY2
DY1
K
DY3
1 2 3
4
5
6
789
10
11
12
DY5
DY7
P
DY8DY6
SHORT PIN(IC)
SHORT PIN(IC)
IC: Internal Connection(Do not use)
15.9
± 0
.4
WIN
DO
W 9
.4 ±
0.4
TPMHA0411EC
INSULATION COVER (Polyoxymethylene)
10.1
6
5.08
10.16
5.08
12- 0.45
PHOTOCATHODE8MIN.
12.8 ± 0.5 4.0 ± 0.3
Bottom ViewSide View
SHORT PINGUIDE MARK
5.4
± 0.3
DY4
DY2
DY1
K
DY3
1 2 3
4
5
6
789
10
11
12
DY5
DY7
P
DY8DY6
SHORT PIN(IC)
SHORT PIN(IC)
IC: Internal Connection(Do not use)
WIN
DO
W11
.0 ±
0.4
15.9
± 0
.4
0.3 ± 0.2 5 ± 1
TPMHA0410EC
TPMHA0278EI TPMHA0297EI
508 ± 10
430 MIN.
610
± 20
20PIN BASEJEDEC No.B20-102
680
MA
X.
254 ± 10
82 ± 2
PHOTOCATHODER315
10
4567
89 1112
131415
1716
181920
DY1
DY3
IC
DY5DY7
DY9IC P
ICFOCUS2
DY2
DY4
ICDY8
DY6
K
DY10IC
FOCUS1
FOCUS312
3
IC: Internal Connection(Do not use)
SIDE VIEW BOTTOM VIEWTOP VIEW
0.6 ± 0.4
22.0 ± 0.5
30.0 ± 0.5
18 MIN.
4.4 ± 0.7
12.0
± 0
.5
PHOTOCATHODE
INSULATIONCOVER
2.54 PITCH
29- 0.45
EFFECTIVE AREA
25.7 ± 0.5
Basing Diagram
KDyPCUTIC
: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Don't Use)
ICICP
ICICICIC
ICICICICICICIC
1 2 3 4 5 6 7 8 932 1031 1130 1229 1328 1427 1526 1625 1724 23 22 21 2019 18
K IC (
Dy1
0)IC D
y1D
y2D
y3D
y4IC
(D
y10)
CU
T (
K)
CU
T (
K)
Dy1
0D
y9D
y8D
y7D
y6D
y5IC
(D
y10)
CU
T (
K)
GUIDECORNER
4 MAX.
K CU
T (
IC)
CU
T (
IC)
Dy1
Dy2
Dy3
Dy4
CU
T (
IC)
CU
T (
K)
CU
T (
K)
Dy1
0D
y9D
y8D
y7D
y6D
y5C
UT
(IC
)C
UT
(K
)
GUIDECORNER
12.0
± 0
.5
SIDE VIEW BOTTOM VIEW
TOP VIEW
CUT (IC)P1
CUT (IC)CUT (IC)CUT (IC)
P4CUT (IC)
CUT (IC)P2CUT (IC)CUT (IC)CUT (IC)P3CUT (IC)
25 1724 23 22 21 2019 18
10111213141516
1 2 3 4 5 6 7 8 932313029282726
P1
P4
P2
P3
15- 0.454 MAX.
0.6 ± 0.4
22.0 ± 0.5 4.4 ± 0.7
PHOTO-CATHODE
2.54 PITCH
20.32
20.3
2
BASING DIAGRAM
KDyPCUTIC
: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Do not Use)
18 M
IN.
18 MIN.
30.0 ± 0.5
18 MIN.
25.7 ± 0.5
INSULATION COVER
PHOTOCATHODE
508 ± 10
460 MIN.
610
± 20
20PIN BASEJEDEC No.B20-102
680
MA
X.
PHOTOCATHODE
254 ± 10
82 ± 2
R315
10
123
4567
89 1112
13141516
1718
1920DY1
DY3DY5
IC
DY7
DY9
DY11P
DY10
ICFOCUS3
FOCUS2
DY2IC
DY4
DY6
K
DY8IC
FOCUS1IC: Internal Connection
(Do not use)
37
%4 R5900U-00-L16, R5900U-100-L16/-200-L16 %5 R8900U, R8900U-100
%6 R8900U-00-M4, R8900U-100-M4 %7 R8900-00-M16, R8900-100-M16
(Unit: mm)
TPMHA0298EG TPMHA0529EA
TPMHA0531EBTPMHA0530EA
GKDyPCUTIC
: Grid: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Do not Use)
ICP
IC
ICICICIC
ICICICICICICIC
1 2 3 4 5 6 7 8 932 1031 1130 1229 1328 1427 1526 1625 1724 23 22 21 2019 18
G CU
T (
Dy1
1)K D
y1D
y2D
y3D
y4IC
(D
y10)
CU
T (
G)
CU
T (
G)
Dy1
0D
y9D
y8D
y7D
y6D
y5IC
(D
y10)
CU
T (
G)
GUIDECORNER
30.0 ± 0.5
23.5
26.2 ± 0.5
PHOTOCATHODE
2.54 PITCH
20.32
29- 0.454 MAX.
12.0
± 0
.5
0.6 ± 0.4
29.0 ± 0.5 4.4 ± 0.7
20.3
2
SIDE VIEW BOTTOM VIEWTOP VIEW BASING DIAGRAM
INSULATION COVER
PHOTOCATHODE
CUT (IC)P1
CUT (IC)CUT (IC)CUT (IC)
P4CUT (IC)
CUT (IC)P2CUT (IC)CUT (IC)CUT (IC)P3CUT (IC)
1 2 3 4 5 6 7 8 932 1031 1130 1229 1328 1427 1526 1625 1724 23 22 21 2019 18
G CU
T (
Dy1
0)K D
y1D
y2D
y3D
y4C
UT
(D
y10)
CU
T (
G)
CU
T (
G)
Dy1
0D
y9D
y8D
y7D
y6D
y5C
UT
(D
y10)
CU
T (
G)
GUIDECORNER
30.0 ± 0.5
23.5
26.2 ± 0.5
PHOTO-CATHODE
2.54 PITCH
16- 0.454 MAX.
12.0
± 0
.5
0.6 ± 0.4
29.0 ± 0.5 4.4 ± 0.7 20.32
20.3
2
P1
P4
P2
P3
23.5
23.5GKDyPCUTIC
: Grid: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Do not Use)
SIDE VIEW BOTTOM VIEW
TOP VIEW
BASING DIAGRAM
INSULATION COVER
PHOTOCATHODE
GUIDECORNER
1 2 3 4 5 6 7 8 910
1112
1314
1516
17181920212223242526
2728
2930
3132
Dy8
CU
T (
K)
P12
P10 P8
P6
P4
Dy5 K
Dy1Dy3ICP2P1P3Dy9
Dy7
CU
T (
K)
P5
P7
P9
P11
P13
Dy6
K
Dy2Dy4
ICP15
P14P16
Dy10
PHOTO-CATHODE
PHOTOCATHODE
INSULATION COVER
12
4 MAX.
1 MAX.
24 MAX. 4.4 ± 0.7
30.0 ± 0.5
15.8
25.7 ± 0.5
16
P16
15.8
0.81.0 PITCH
30- 0.45
2.54 PITCH
20.32
20.3
2
P1
KDyPCUTIC
: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Do not Use)
SIDE VIEW BOTTOM VIEW
TOP VIEW
BASING DIAGRAM
1234
13141516
P1P4
P13P16
BASING DIAGRAM
23.5
EPOXY1.2 MAX.
2.5 MAX.
12.5 MAX.
25
.5 ±
0.5
0.8
27.2 ± 0.5 7.0 ± 0.5 6 MAX.
2.54 PITCH
20.32
8×2.
54=2
0.32
5.08
10.1
6
15.2
4
5.08
15.24
30- 0.45
GKDyPCUTIC
: Grid: Photocathode: Dynode: Anode: Short Pin: Internal Connection (Don't Use)
PHOTO-CATHODE
PHOTO-CATHODE
SIDE VIEW BOTTOM VIEW
TOP VIEW
23.5
23.5
3.5
MA
X.
30+0 -0.5
G CUT (
IC)
CUT (
IC)
CUT (
IC)
CUT (
IC)CU
T (IC)
CUT (
IC)
P16
P12
P8
P4
P14
P10
P6
P2
P13
P9
P5
P1
P15
P11
P7
P3
Dy6
Dy5CU
T (IC)
CUT (
IC)CU
T (IC)
CUT (
IC)CU
T (IC)
K Dy1
Dy12
Dy11
Dy10
Dy9
Dy8
Dy7
CUT (
IC)
CUT (
IC)
Dy2
Dy3
Dy4
CUT (
IC)
CUT (
IC)
38
^0 R6236 ^1 R6237
^2 R1548-07
54 M
IN.
59.5
± 1
.0
59.5 ± 1.0
54 MIN.
56.5 ± 0.5
100
± 3
123
MA
X.
51.5 ± 1.5
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0392EB
TPMHA0511EA
70 M
IN.
76.0
± 1
.5
76.0 ± 1.5
70 MIN.
123
MA
X.
100
± 3
56.5 ± 0.5
51.5 ± 1.5
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0393EB
IC
DY3 IC
DY7-1
DY9
DY7-2
DY6
DY4
DY2DY5
ICK
P1P2 DY10
SHORT PIN
DY8
DY1 12
3
45
67
8 9 1011
12
1314
1516
17
24.0 ± 0.5FACEPLATE
PHOTOCATHODE
70 ±
213
MA
X.
17 PIN BASE
8 MIN. 8 MIN.
18 M
IN.
24.0
± 0
.5
%8 R2248 %9 R2102
TPMHA0098EC
12
3
4
56 7 8
9
10
11
1213
DY1
DY3
DY5
DY7
P
DY9
DY10DY8
DY6
DY4
DY2
IC
K
SHORT PIN
FACEPLATE
10 M
IN.
13.5
± 0
.5
13.5 ± 0.5
71 ±
213
MA
X.
PHOTOCATHODE
13 PIN BASE
10 MIN.
TPMHA0096EA
12
3
4
56
7
8
9
1011
IC
DY1
DY3
DY5
DY7P
DY8
DY6
DY4
DY2
K
FACEPLATE
PHOTOCATHODE
8 MIN.
9.8 ± 0.48
MIN
.10
MA
X.
11 PIN BASE
45.0
± 1
.5
9.8
± 0.
4
SHORT PIN
^3 R8997
TPMHA0552EB
5 15
4 16
1
7
14
813
20DY1
DY5
DY3
P-C
DY7-D
DY7-C
DY9
P-D
DY8DY10
DY7-A
DY7-B
P-A
P-B
DY6
DY2DY4
K
A Temporary Base Removed
B Bottom View
32
6
1918
17
1211
DY1
DY5DY3
P-C
DY7-D
DY7-C
ICIC
DY9
P-D
DY8DY10
DY7-A
DY7-B
P-A
P-B
DY6
DY2DY4
K
1 202 193 18
4 17
5
6
16
15
7 148 13
9 1210 11
84 ±
213
MA
X.
PHOTOCATHODE
FACE PLATE
SEMIFLEXIBLELEADS
51.0 ± 0.5
12 PIN BASE JEDECNo. B20-102
A
B
39+0 -1
33 MIN.
16 MIN.
16 M
IN.
33 M
IN.
38.1 MAX.
39
^4 R1538 ^5 R6234
^6 R6235 ^7 R7373A-01
^8 R8143
(Unit: mm)
TPMHA0512EA
56.5 ± 0.5
59.5 ± 0.5
55 MIN.
100
± 3
123
MA
X.
60 M
IN.
67.5
± 0
.6
51.5 ± 1.5
12
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0390EB
79 M
IN.
85 ±
1
56.5 ± 0.5
76.0 ± 1.5
70 MIN.
100
± 3
123
MA
X.
51.5 ± 1.51
2
3
4
56
7 89
10
11
12
1314
DY1IC
P
DY3
DY4
DY5DY6 IC
IC
DY7
DY8
DY2
GK
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0391EB
56.5 ± 0.5
59.5 ± 0.5
55 MIN.
125
± 3
1960
MIN
.
67.5
± 0
.6
51.5 ± 1.5 12
3
4
56
7 89
10
11
12
1314
DY1DY2
IC
DY4
DY5
DY6DY7 DY8
IC
IC
P
DY3
GK
FACEPLATE
PHOTO-CATHODE
14 PIN BASEJEDECNo. B14-38
TPMHA0507EA
TPMHA0460EA
2
3
4
56
7 89
10
11
12
14IC
DY3
DY2
DY7
DY9
DY11P DY10
DY8
DY6
DY4
DY5
KDY1
SHORT PIN
1
112
± 2
13 M
AX
.
20 M
IN.
28.5 ± 0.5
25 MIN.
PHOTOCATHODE
14 PIN BASE
13
HA COATING
FACE PLATE
29.0 ± 0.7
DY1
DY3
DY5
DY7
PDY9 DY10
DY8
DY6
DY4
DY2
3
4
56 10
11
12
13
14
17
K
A TEMPORARY BASE REMOVED
DY1
DY3
DY5
DY7
P
DY9
DY2
K1
2
3
4
56 7
8
9
10
1112
DY10
DY8
DY6
DY4
2
8
25.4 ± 0.5
13 M
AX
.
43.0
± 1
.550
MIN
.
R13 ± 1
PHOTOCATHODE
FACEPLATE
SEMIFLEXIBLELEADS
12 PIN BASE JEDECNo. B12-43
B BOTTOM VIEWA
B
37.3
40
Typical Gain Characteristics
10 mm (3/8") Dia. and TO-8 Types 13 mm (1/2") Dia. Types
19 mm (3/4") Dia. Types 25 mm (1") Dia. Types
TPMHB0095EE TPMHB0096EC
TPMHB0097EF
500 700 1000 1500 2000 2500 3000
108
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
R4124
R4177-06
R2102
R647-01
TPMHB0099ED
300 700 1500 2000
108
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
500 1000
R1635R2248R2496
R7400U
500 700 1000 1500 2000 2500 3000
108
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
R5611A-01
R3991A-04
R4125
R1166 R1450
R3478
500 700 1000 1500 2000 2500 3000
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
108
R1924A
R8619
R9800
R5505-70
R4998R1548-07
R7899-01
R7373A-01
R1288A-06
41
28 mm (1-1/8") Dia. Types 38 mm (1-1/2") Dia. Types
TPMHB0101EDTPMHB0100EE
51 mm (2") Dia. Types 51 mm (2") Dia. Types
TPMHB0791EA TPMHB0792EA
500 700 1000 1500 2000 2500 3000102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
R7111
R8143
R7525
R3998-02
R6427
500 700 1000 1500 2000 2500 3000102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
R7761-70
R9420
R5330
R3886
R980
R8997
R580
500 700 1000 1500 2000 2500 3500102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
3000
R331-05
R7725
R329-02
R1828-01
500 700 1000 1500 2000 2500 3500102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
3000
R1306
R7723
R2083R6231
R9779
42
51 mm (2") Dia. Types 60 mm (2.5") Dia. Types
TPMHB0793EA
76 mm (3") Dia. Types 127 mm (5") Dia. Types
TPMHB0107EE
500 700 1000 1500 2000 2500 3000103
SUPPLY VOLTAGE (V)
GA
IN
104
105
106
107
108
109
R1250R1584
R1512R6594
R877
TPMHB0108EC
TPMHB0105ED
500 700 1000 1500 2000 2500 3000102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
R6232R6234R6236
R1538
102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
500 700 1000 1500 2000 2500 35003000
R1840
R5924-70
R2154-02
R7724
R4607-06
500 700 1000 1500 2000 2500 3000102
SUPPLY VOLTAGE (V)
GA
IN
103
104
105
106
107
108
R6091
R1307
R6233R6235R6237
R4143
R2238
43
Metal Package Types Metal Package Types and Assembly Type
TPMHB0788EA TPMHB0789EA
204 mm (8"), 254 mm (10") and 508 mm (20") Dia. Types
103
SUPPLY VOLTAGE (V)
GA
IN
104
105
106
107
108
109
R5912R7081
R3600-02R7250
500 700 1000 1500 2000 2500 3000
TPMHB0109EB TPMHB0657EB
300 700 1500 2000
108
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
500 1000
R8900-00-M16
R8900UR8900U-00-M4
R8900U-00-C12
R7600UR7600U-00-M4
300 700 1500 2000
108
SUPPLY VOLTAGE (V)
GA
IN
107
106
105
104
103
102
500 1000
H8711
H7546BH8804
H7260K
H8500CH9500
R5900U-00-L16
104
SUPPLY VOLTAGE (V)
GA
IN
105
106
107
108
109
1010
R5912-02R7081-20
R8055
500 700 1000 1500 2000 2500 3000
44
Position Sensitive Photomultiplier Tubes
TubeDiameter
TypeNo.
OutlineNo.
SpectralResponse
Range (nm)/
Curve Code
300 to 650/A-D E678-32B ¤9 MC / 116(X) + 6(Y) Plates 4.0 85 10.0 25qR8900U-00-C12
30 mmSquare
q w
Socket&
SocketAssembly
Anode Sensitivity Cathode Sensitivitye
DynodeStructure/ No. ofStages
BlueSens.Index
(CS 5-58)Typ.
r
y
(µA/lm)
Number of Platesor wires
t
LuminousTyp.
23.5 × 23.5
(mm)
EffectiveArea
AnodePitch
(mm)
Q.E.at PeakTyp.
(%)
300 to 650/A-D
300 to 650/A-D
—
—
CM / 12
CM / 12
16(X) + 16(Y) Wires
28(X) + 28(Y) Wires
3.75
4.0
80
80
9.0
9.0
23
23
w
e
R2486-02
R3292-02
3"round
5"round
50
100
u
Position Sensitive Photomultiplier Tubes with Metal Channel Dynodes
Position Sensitive Photomultiplier Tubes
Note: Please refer to page 18 and 19 for each item in the above list.
q R8900U-00-C12, R8900U-100-C12
TPMHA0524EB
SIDE VIEW BOTTOM VIEW
TOP VIEW
BASING DIAGRAM
KDy2Dy4Dy6Dy8
Dy10CUT (Dy11)
PX1PX2PX3PY1PX4PX5PX6
1 2 3 4 5 6 7 8 932 1031 1130 1229 1328 1427 1526 1625 1724 23 22 21 2019 18
G CU
T (
Dy1
1)D
y1D
y3D
y5D
y7D
y9D
y11
CU
T (
G)
CU
T (
G)
PY
6P
Y5
PY
4C
UT
(IC
)P
Y3
PY
2C
UT
(D
y11)
CU
T (
G)
GUIDECORNER
30.0 ± 0.5
23.5
26.2 ± 0.5
2.54 PITCH
25- 0.454 MAX.
12.0
± 0
.5
0.6 ± 0.4
29.0 ± 0.5 4.4 ± 0.7 20.32
20.3
2
PX1PX2PX3PX4PX5PX6
PY
6P
Y5
PY
4P
Y3
PY
2P
Y1
23.5
23.5GKDyP
CUTIC
: Grid: Photocathode: Dynode: Anode (PX1-PX6) (PY1-PY6): Short Pin: Internal Connection (Do not Use)
PHOTO-CATHODE
INSULATION COVER
PHOTOCATHODE
45
7.0 × 105800 #7 1000 0.160 2 2.2 0.7510 R8900-00-C12, without cover type, isavailable.
TypeNo.
Note
R8900U-00-C12
Anode Sensitivity
Anode toCathodeSupplyVoltage
DarkCurrent
i o !1!0
GainTyp.
LuminousTyp.
Typ.
Anodeto
CathodeVoltage
(V)
AverageAnodeCurrent
(mA)(A/lm)
RiseTimeTyp.
(ns)
11.9
5.0 × 105
1.3 × 105
1250 $1
1250 $1
1300
1300
0.06
0.06
40
10
20
40
5.5
6.0
—
—
50
150
No suffix number: PMT alone-01: PMT + Voltage Divider-02: -01 + Resistor ChainNo suffix number: PMT + HA-01: PMT + HA +Voltage Divider-02: -01 + Resistor Chain
R2486-02
R3292-02
17
20
TransitTimeTyp.
(ns)
T.T.S.Typ.
(FWHM)
(ns)
Maximum Rating !2 Typical Time Response !3
(nA)Max.(nA)
e R3292-02
w R2486-02
TPMHA0160ED
X1X2X3X4X5X6X7X8X9X10X11X12X13X14X15X16
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
Y11
Y12
Y13
Y14
Y15
Y16
DY2
DY1
DY3
DY4
DY5
DY6
DY7
DY8
DY9
DY10
DY11
DY12
2R 2R
2R
2R
2R
2R C1
1R
C3
C2
2R
2R
2R
2R
2R
1RK
Focus 10 kΩ
YDYCXBXA
RG-174/U
1R : 180 kΩ 1/2 W2R : 360 kΩ 1/2 WC1 : 0.002 µF/2 kVC2 : 0.01 µF/500 VC3 : 0.01 µF/500 V
2R
HVIN
EACH RESISTOR: 1 kΩ
TPMHC0086EE
TPMHA0162EE
DY2
DY1
DY3
DY4
DY5
DY6
DY7
DY8
DY9
DY10
DY11
DY12
K
10 kΩ
2R
2R
2R
2R
2R
1R2R
C3
2R
2R
2R
2R
2R
C1
C2
R2R
RG-174/U
X1X2X3X4X5
X24X25X26X27X28
Y1
Y2
Y3
Y4
Y5
Y24
Y25
Y26
Y27
Y28
YDYCXBXA
1R : 180 kΩ 2R : 360 kΩ
C2 : 0.01 µF/500 VC3 : 0.01 µF/500 V
HVIN
C1 : 0.002 µF/2 kV
EACH RESISTOR: 1 kΩ
TPMHC0088EE
76 ± 1
55 ±
220
± 1
11.2
86.2
± 3
.0
-HV: RG-174/U
50 MIN.
SIGNAL OUTPUT: 0.8D COAXIAL CABLES
PHOTO-CATHODE
100 MIN.
132 ± 3
113
± 2
20 ±
1
133
± 3
PHOTO-CATHODE
SIGNAL OUTPUT: 0.8D COAXIAL CABLES
-HV: RG-174/U
HA COATING
46
Voltage Distribution RatiosInterstages for the dynodes of a PMT are supplied by a voltage divider network consisting of series resistors, as shown on the right page. The cathode ground scheme (1) is usually used in scintillation counting because it reduces noise resulting from glass scintillation. In fast-pulse light applications, use of the anode ground scheme (2) is suggested. Either scheme re-quires decoupling (charge-storage) capacitors connected to the last few stages of dynodes in order to maintain the dynode vol-
tage at a constant value during pulse duration. refer to section 11 and 12 on page 8 to 13 for further details.To free the user from the necessity of designing voltage divider and performing troublesome parts selection, Hamamatsu pro-vides a variety of socket assemblies which enable sufficient performance to be derived from PMT's by making simple con-nections only.
Voltage Distribution Ratio
Acc: Grid (Accelerating Electrode)
(Note 1)
Note 1: Acc should be connected to Dy7 except R4998.
<Symbols>K: Photocathode G: Grid F: Focusing ElectrodeDy: Dynode GR: Guard Ring P: Anode Acc: Accelerating ElectrodeDy3 Dy4 Dy5 Dy6 PDy2Dy1K
1 2 4 2112
Voltage Distribution Ratios
6
Numberof
stages
VoltageDistribution
No.q
Dy3 Dy4 Dy5 Dy6 PDy2Dy1K G11
1.511
1.51.51.52
1.51.5
11111111111
1111111
1.2111
1111111
1.5111
Dy711111112111
Dy81111111
3.3211
0.51111113111
11
1.521
1.5111
1.51
—1
4.8—2——————
11
1.322344447
stages
8
No.w
e
r
t
y
u
i
o
!0
!1
!2
Dy3 Dy4 Dy5 Dy6 PDy2Dy1K G1.8 1 1 1
Acc1
Dy70.5 3
Dy82.51.24.81.3
stages8
No.!3
Dy3 Dy4 Dy5 Dy6 PDy2Dy1K G11
11
11
1.51.5
Dy711
Dy811
11
Dy911
11
—1
33
stages
9
No.!4
!5
Dy3 Dy4 Dy5 Dy6 PDy2Dy1K G111
1.811
1.5111
1.51.21
1.51.51
1.51.52
1111111111111111111
1111111111111111111
1111111111111111111
Dy7111111111
1.21111111
1.21
Dy811111
1.211
1.21.51111211
1.51
111
1.51
1.811
1.52.2111131121
Dy911131
3.611
1.83.61111
3.611
3.32
Dy100.511
2.51
3.31123
0.75111
3.31131
211
1.211
1.51111
1.2111
1.5111
1.5—1
4.8———————————————
0.511
1.31.51.51.52222
2.63333444
stages
10
No.!6
!7
!8
!9
@0
@1
@2
@3
@4
@5
@6
@7
@8
@9
#0
#1
#2
#3
#4
Dy3 Dy4 Dy5 Dy6 PDy2F1 F3 F2K Dy10.170.17
0.850.85
1.51.5
11
Dy711
Dy811
11.2
Dy91
1.5
Dy101
1.813
12.4
00
0.180.18
88
stages
10
No.#5
#6
47
Voltage Distribution Ratio
Schematic Diagram of Voltage Divider Networks(1) Cathode Ground Scheme (+HV) (2) Anode Ground Scheme (-HV)
Note 2: Shield should be connected to Dy5.
R
DY.1
R
CATHODE
R R R R R R R R
DY.nANODE Cc
Rd
C C C C
+HV Rd : 1MΩCc : 0.005µF
R : 100kΩ 1MΩC : 0.01µF 0.1µF
DY.…
TPMOC0043EB TPMOC0044EB
R
DY.1
R
CATHODE
DY.2…
R R R R R R R R
DY.nANODE
C C C C-HV R : 100k 1MΩC : 0.01µF 0.1µF
RL
(Note 2)
(Note 2)
(Note 2)
Dy2 Dy3 Dy4 Dy5 PDy1GK11
11
11
11
Dy611
Dy711
Dy811
Dy911
Dy1011
Dy110.51
21
1.5—
0.52
Voltage Distribution Ratios
11
Numberof
stages
VoltageDistribution
No.#7
#8
Dy2 Dy3 Dy4 Dy5 PDy1F2 F1 F3K0.02 3 1 1
Dy61
Dy71
Dy81
Dy91 1 1
Dy101Dy11
121511#9
stagesNo.
Dy2 Dy3 Dy4 Dy5 PDy1GK2.41
1.81.81.81.81122
1.42
1.61.6
11111111111111
11111111111111
11111
1.211111111
Dy611111
1.51111111
1.2
Dy7111
1.5121111111
1.5
Dy8111
2.51
2.811111112
Dy911
1.53.61.541
1.21111
1.62.4
11
1.54.51.55.71
1.5111123
113
8.6381
1.81212
3.33.9
Dy1011
2.54
2.5512151123
Dy11 Dy121.81
1.21.21.21.211221111
——33
2.82.8————0—00
0.6111
1.21.2222344
4.34.3
12
$0
$1
$2
$3
$4
$5
$6
$7
$8
$9
%0
%1
%2
%3
stagesNo.
Dy2 Dy3 Dy4 Dy5 PDy1GK1.81.8
11
11
11
Dy611
Dy71
1.2
Dy81
1.5
Dy912
12.8
1.54
Dy101.55.7
Dy11 Dy1238
Dy132.55
Dy141.21.2
7.57.5
2.52.5
14%6
%7
stagesNo.
Dy2 Dy3 Dy4 Dy5Dy1K11
11
11
11
Dy611
Dy711
Dy811
Dy911
11
10.9
Dy100.50.1
Dy11 Dy12 GR P11
11
11
12%4
%5
stagesNo.
Dy2 Dy3 Dy4 Dy5 PF2Dy1K555
3.333.3
3.33
1.671.7
1.67
111
Dy6111
Dy7111
Dy8121
Dy9131
——1.2
——1.5
Dy10——2.2
Dy11 Dy12——3
Dy1314
2.4
Dy140.60.60.6
F1000
F33.43.43.4
000
11.318.511.3
10
14
%8
%9
^0
stagesNo.
Dy2 Dy3 Dy4 Dy5 PDy1K11
11
11
11
Dy611
Dy711
Dy811
Dy911
11
11
Dy1011
Dy11 Dy1211
Dy1311
Dy14—1
Dy15—1
Dy16—1
Dy17—1
Dy1811
Dy1911
22
1519
^1
^2
stagesNo.
48
Quick Reference for PMT Hybrid Assemblies
TubeDiameter
AssemblyTypeNo.
OutlineNo. Notes
Tube Type No./
VoltageDistribution
Ratio
Refe-rence
Page forPMT
Feature
16
16
16
16
16
17
16
17
16
16
16
16
16
16
16
-1500
-1500
-1250
-1250
-1800
-1800
-1800
-1250
-2500
+2300
-1800
-1500
-2000
-1750
+2300
1.0 × 106
1.0 × 106
1.4 × 106
1.0 × 106
1.7 × 106
1.0 × 106
1.0 × 106
5.5 × 105
5.7 × 106
5.0 × 105
1.7 × 106
1.1 × 106
2.0 × 106
7.9 × 105
1.0 × 107
H6610 (R5320)
+HV
H7416 (R7056)
+HV
t
u
!7
@0
@6
!2
!2
@8
!9
1
#0
!1
#2
@3
2
q
w
e
r
t
y
u
i
o
!0
!1
!2
!3
!4
!5
H3164-10
H3695-10
H3165-10
H6520
H6524
H6613
H6612
H8135
H6533
H6152-70
H8643
H10580
H7415
H3178-51
H8409-70
R1635
R2496
R647-01
R1166
R1450
R2076
R3478
R5611A
R4998
R5505-70
R7899-01
R9800
R6427
R580
R7761-70
10 mm(3/8")
13 mm(1/2")
19 mm(3/4")
25 mm(1")
28 mm(1-1/8")
38 mm(1-1/2")
Assembly CharacteristicsPMT CharacteristicsMaximum
RatingGainTyp.
SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*SHIELDCABLE*
SHV
SHIELDCABLE*
H.VInput
Terminal
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
RG-174/U
BNC
RG-174/U
SignalOutput
Terminal
(V)
OverallVoltage
0.34
0.31
0.27
0.26
0.36
0.33
0.33
0.23
0.32
0.36
0.35
0.33
0.31
0.54
0.29
(mA)
Divider2
Current
-1250
-1250
-1000
-1000
-1500
-1700
-1700
-1000
-2250
+2000
-1500
-1300
-1500
-1500
+2000
(V)
Overall1
Voltage
StandardRating
Note : 1: When overall voltage is negative (-HV), DC and pulse signals are obtained. When it's positive (+HV), pulse signal is obtained.2: The maximum average anode current is defined as 5 % of divider current.* mark: It's possible to attach an SHV connector to the shield cable.
49
18
18
18
18
18
18
18
18
18
18
18
18
18
-2700
-2700
-3000
-3000
-3500
+2300
-1750
-1500
-3000
-2500
-3000
-3000
+2500
3.0 × 106
3.0 × 106
1.0 × 107
1.0 × 107
2.5 × 106
1.0 × 107
5.0 × 105
5.0 × 105
5.0 × 106
1.0 × 107
1.4 × 107
1.4 × 107
1.0 × 107
BNC
BNC × 3**
BNC × 3**
BNC
BNC
RG-174/U
BNC
RG-174/U
BNC
BNC
BNC
BNC
H6521 (R2256-02)H6522 (R5113-02)
H3177-50 (R2059)H4022-50 (R4004)H3177-51 (R2059)H4022-51 (R4004)
H3378-50 (R3377)
+HV
H6526 (R4885)
%3
%2
$4
$4
!3
2
r
$6
$2
%3
%6
%6
#9
!6
!7
!8
!9
@0
@1
@2
@3
@4
@5
@6
@6
@7
H6410
H7195
H1949-50
H1949-51
H2431-50
H6614-70
H10570
R2238-01
H6525
H6559
H6527
H6528
R3600-06
R329-02
R329-02
R1828-01
R1828-01
R2083
R5924-70
R9779
R2238
R4143
R6091
R1250
R1584
R3600-02
51 mm(2")
76 mm(3")
127 mm(5")
508 mm(20")
20
20
20
20
20
20
-1000
-1000
-1000
-900
-1100
-1100
3.5 × 106
6.3 × 105
6.3 × 105
2.0 × 106
1.5 × 106
1.5 × 106
TERMINALPIN
TERMINALPIN
TERMINALPIN
TERMINALPIN
TERMINALPIN
TERMINALPIN
(14 µA is total anode current of 16 ch.)(18 µA is total anode current of 64 ch.)(18 µA is total anode current of 64 ch.)(100 µA is total anode current of 32 ch.)(100 µA is total anode current of 64 ch.)(100 µA is total anode current of 256 ch.)
$8
$9
$9
!7
%4
%5
@8
@9
#0
#1
#2
#3
H8711
H7546B
H8804
H7260K
H8500C
H9500
16 ch (4 × 4)
64 ch (8 × 8)
64 ch (8 × 8)
32 ch (1 × 32)
64 ch (8 × 8)
256 ch (16 × 16)
MetalPackage
PMT
TubeDiameter
AssemblyTypeNo.
OutlineNo. Notes
Tube Type No./
VoltageDistribution
Ratio
Refe-rence
Page forPMT
Feature
Assembly CharacteristicsPMT CharacteristicsMaximum
RatingGainTyp.
H.VInput
Terminal
SignalOutput
Terminal
(V)
OverallVoltage
(mA)
Divider2
Current
(V)
Overall1
Voltage
StandardRating
0.49
0.91
1.15
0.58
0.52
0.29
0.33
0.37
0.58
0.49
0.68
0.68
0.35
0.28
0.36
0.36
0.33
0.16
0.16
SHV
SHV
SHV
SHV
SHV
SHIELDCABLE*
SHV
SHIELDCABLE*
SHV
SHV
SHV
SHV
TERMINALPIN
TERMINALPIN
TERMINALPIN
TERMINALPIN
SHV
SHV
-2000
-2000
-2500
-2500
-3000
+2000
-1500
-1250
-2500
-2000
-2000
-2000
+2000
-800
-800
-800
-800
-1000
-1000
Note : 1: When overall voltage is negative (-HV), DC and pulse signals are obtained. When it's positive (+HV), pulse signal is obtained.2: The maximum average anode current is defined as 5 % of divider current.* mark: It's possible to attach an SHV connector to the shield cable.** mark: It has 2 anode outputs and 1 dynode output.
HYBRID CABLEH.V=SINGLE WIRE(SIGNAL=RG-58C/U)
50
Dimensional Outlines and Circuit DiagramsFor PMT Hybrid Assembliesq H3164-10 w H3695-10
e H3165-10 r H6520
t H6524 y H6613
TPMHA0309EC TPMHA0310EB
TPMHA0311EC TPMHA0312EB
TPMHA0313EB TPMHA0314EA
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
P
*MA
GN
ET
IC S
HIE
LD
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1 to R11C1 to C3
: 330 kΩ: 0.01 µF
10.5 ± 0.6
8 MIN.
95.0
± 2
.5
45.0
± 1
.5
1500
MIN
.
PHOTOCATHODE
PMT: R1635WITH HA COATING
MAGNETICSHIELD (t=0.2 mm)WITH HEATSHRINKABLE TUBE
POTTINGCOMPOUND
-H.V: SHIELD CABLE (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
10.6 ± 0.2
* MAGNETIC SHIELD IS CONNECTEDTO -H.V INSIDE OF THIS PRODUCT.
THE H3164-11 IS A VARIANT OF H3164-10WITH A TERMINAL RESISTOR (50Ω).
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
PC3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1 to R4R5 to R10C1 to C3
: 510 kΩ: 330 kΩ: 0.01 µF
11.3 ± 0.7
8 MIN.
95.0
± 2
.5
45.0
± 1
.5
1500
MIN
.
PHOTOCATHODE
PMT: R2496WITH HA COATING
MAGNETICSHIELD (t=0.2 mm)WITH HEATSHRINKABLE TUBE
POTTINGCOMPOUND
-H.V: SHIELD CABLE (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
10.6 ± 0.2
*MA
GN
ET
IC S
HIE
LD
* MAGNETIC SHIELD IS CONNECTEDTO -H.V INSIDE OF THIS PRODUCT.
THE H3695-11 IS A VARIANT OF H3695-10WITH A TERMINAL RESISTOR (50Ω).
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHIELD CABLE (RED)
PC3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1 to R11C1 to C3
: 330 kΩ: 0.01 µF
14.3 ± 0.6
10 MIN.
116.
0 ±
3.0
71 ±
2
1500
MIN
.
PHOTOCATHODE
POTTINGCOMPOUND
-H.V: SHIELD CABLE (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
12.4 ± 0.5
PMT: R647-01WITH HA COATING
MAGNETICSHIELD (t=0.2 mm)WITH HEATSHRINKABLE TUBE
*MA
GN
ET
IC S
HIE
LD
* MAGNETIC SHIELD IS CONNECTEDTO -H.V INSIDE OF THIS PRODUCT.
THE H3165-11 IS A VARIANT OF H3165-10WITH A TERMINAL RESISTOR (50Ω).
23.5 ± 0.5
19.3 ± 0.7
15 MIN.
PHOTOCATHODE
130.
0 ±
0.8
88 ±
2
1500
MIN
.
1 M
AX
.
PMT: R1166WITH HA COATING
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1R2 to R11C1 to C3
: 510 kΩ: 330 kΩ: 0.01 µF
-H.V: SHIELD CABLE (RED)
MAGNETIC SHIELD CASE (t=0.5 mm)
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
THE H6520-01 IS A VARIANT OF H6520WITH A TERMINAL RESISTOR (50Ω).
23.5 ± 0.5
18.7 ± 1.0
15 MIN.
PHOTOCATHODE
130.
0 ±
0.8
65 ±
2
1500
MIN
.
1 M
AX
.
PMT: R2076WITH HA COATING
MAGNETIC SHIELD CASE (t=0.5 mm)
POTTINGCOMPOUND
-H.V: SHIELD CABLE (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1R2R3
R4, R6 to R11R5
C1 to C3
: 1 MΩ: 750 kΩ: 560 kΩ: 330 kΩ: 510 kΩ: 0.01 µF
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
THE H6613-01 IS A VARIANT OF H6613WITH A TERMINAL RESISTOR (50Ω).
23.5 ± 0.5
19.3 ± 0.7
15 MIN.
PHOTOCATHODE
130.
0 ±
0.8
88 ±
2
1500
MIN
.
1 M
AX
.
PMT: R1450WITH HA COATING
MAGNETIC SHIELD CASE (t=0.5 mm)
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1R3
R2, R4 to R11C1 to C3
: 680 kΩ: 510 kΩ: 330 kΩ: 0.01 µF-H.V
: SHIELD CABLE (RED)
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
THE H6524-01 IS A VARIANT OF H6524WITH A TERMINAL RESISTOR (50Ω).
51
u H6612 i H8135
(Unit: mm)
TPMHA0315EA TPMHA0513EB
o H6533 !0 H6152-70
!1 H8643 !2 H10580
TPMHA0317EB TPMHA0470EB
TPMHA0554EA
31.0 ± 0.5
26 ± 1
20 MIN.
120.
0 ±
0.8
71 ±
1
1500
MIN
.
1 M
AX
.
PHOTOCATHODE
WITH HA COATING
PMT: R4998 (H6533)R5320 (H6610)
MAGNETIC SHIELD CASE (t=0.8 mm)
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
-H.V: SHIELD CABLE (RED)
R19
R18
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
P
C4
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1, R3, R19R2, R7 to R12, R15 to R17
R4R5, R18R6, R14
R13R20 to R22
C1 to C3C4
: 430 kΩ: 330 kΩ: 820 kΩ: 390 kΩ: 270 kΩ: 220 kΩ: 51 Ω: 0.022 µF: 0.033 µF
R22
R21
R20
F
ACC
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
23.5 ± 0.5
19.3 ± 0.7
15 MIN.
PHOTOCATHODE
130.
0 ±
0.8
65 ±
2
1500
MIN
.
1 M
AX
.
PMT: R3478WITH HA COATING
MAGNETIC SHIELD CASE (t=0.5 mm)
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
-H.V: SHIELD CABLE (RED)
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R1R2R3
R4, R6 to R11R5
C1 to C3
: 1 MΩ: 750 kΩ: 560 kΩ: 330 kΩ: 510 kΩ: 0.01 µF
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
THE H6612-01 IS A VARIANT OF H6612WITH A TERMINAL RESISTOR (50Ω).
24.0 ± 0.5
19.3 ± 1.0
15 MIN.
60.0
± 0
.8
1 M
AX
.
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
1500
MIN
.
R1R2 to R11
C1 to C3
: 1 MΩ: 330 kΩ: 0.01 µF
-H.V: RG-174/U (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
POTTING COMPOUND
PHOTOCATHODE
PMT: R5611A WITH HA COATING
MAGNETIC SHIELD CASE (t=0.5 mm)
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
TPMHA0514EA
31.0 ± 0.5
26 ± 1
22 MIN.
120.
0 ±
0.8
68 ±
1
1 M
AX
.
-H.V: SHIELD CABLE (RED)
P
K
ANODE OUTPUT: RG-174/U (BLACK)
R17
R18
1500
MIN
.
R1, R2, R4, R11, R12R3, R5 to R10
R13, R14R15, R16
R17 to R19C1, C2
C3C4
: 300 kΩ: 200 kΩ: 360 kΩ: 330 kΩ: 51 Ω: 0.01 µF: 0.022 µF: 0.033 µF
C1
C2
C3
C4
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
DY9
R19DY10
ANODE OUTPUT: RG-174/U (BLACK)
-H.V: SHIELD CABLE (RED)
POTTING COMPOUND
PMT: R7899-01 WITH HA COATING
MAGNETIC SHIELD CASE (t=0.8 mm)
PHOTOCATHODE
R1
R2
R3
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
R14
R15
R16
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
31.0 ± 0.5
25.8 ± 0.7
17.5 MIN.
100.
0 ±
0.8
1500
MIN
.
1 M
AX
.
PMT: R5505-70WITH HA COATING
PHOTOCATHODE
POM CASE
POTTING COMPOUND
+H.V: SHIELD CABLE (RED)
SIGNAL OUTPUT: RG-174/U (BLACK)
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY15
DY14
DY13
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
PC5
C4
C3
C2
C1
C7
K
SIGNAL OUTPUT: RG-174/U (BLACK)
+H.V: SHIELD CABLE (RED)R21
R20
R19
R18
C6R22 R24
R23
R1 to R17R18, R23
R19 to R21R22R24
C1 to C5C6, C7
: 330 kΩ: 1 MΩ: 51 Ω: 100 kΩ: 10 kΩ: 0.01 µF: 0.0047 µF
-H.V: SHIELD CABLE (RED)
* TO MAGNETICSHIELD CASE
ANODE OUTPUT: RG-174/U (BLACK) WITH BNC
-H.V: SHIELD CABLE (RED) WITH SHV
PHOTOCATHODE
MAGNETICSHIELD CASE
VOLTAGE DIVIDER CURRENT=383 µA / 1500 V INPUT
31.5 ± 0.5
25.4 ± 0.5
22 MIN.
120.
0 ±
0.8
1 M
AX
.15
00 M
IN.
AC
TIV
E V
OLT
AG
E D
IVID
ER
C3
C2
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
C1
DY8
P
DY7
DY5
DY4
DY3
DY2
DY1
K
DY6
ANODE OUTPUT: RG-174/U (BLACK)
R1R2
R3, R5R4, R6 to R8
R9 to R11C1 to C3
: 1 MΩ: 200 kΩ: 150 kΩ: 300 kΩ: 51 Ω: 0.01 µF
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
52
!3 H7415 !4 H3178-51
!5 H8409-70 !6 H6410
TPMHA0318EC
47.0 ± 0.5
39 ± 1
34 MIN.
162.
0 ±
0.8
1 M
AX
.
PHOTOCATHODE
MAGNETIC SHIELD CASE (t=0.8 mm)
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HV
SIG
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHV-R
P
C4
C3
C2
C1
K
SIGNAL OUTPUT: BNC-R
R1, R10, R12R2 to R6, R13
R7R8R9
R11R14R15C1C2C3C4C5
: 300 kΩ: 150 kΩ: 180 kΩ: 220 kΩ: 330 kΩ: 240 kΩ: 51 Ω: 10 kΩ: 0.01 µF: 0.022 µF: 0.047 µF: 0.1 µF: 4700 pF
R14
R15
C5
PMT: R580WITH HA COATING
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
TPMHA0320EB
TPMHA0324ECTPMHA0476EB
60.0 ± 0.5
53.0 ± 1.5
46 MIN.
200.
0 ±
0.5
1 M
AX
.
PHOTOCATHODE
MAGNETIC SHIELD CASE (t=0.8 mm)
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HV
SIG
R1, R5R2, R10, R16
R3, R9R4, R6 to R8, R14, R18
R11, R13, R17R12, R15
R19R20, R21
R22C1C2C3C4C5C6
: 240 kΩ: 220 kΩ: 180 kΩ: 150 kΩ: 300 kΩ: 360 kΩ: 51 Ω: 100 Ω: 10 kΩ: 0.022 µF: 0.047 µF: 0.1 µF: 0.22 µF: 0.47 µF: 470 pF
R18R17R16R15R14R13R12R11R10R9R8
R7
R6R5R4R3R2R1
DY12
DY11
DY10DY9DY8DY7DY6DY5
DY4DY3DY2DY1
-H.V: SHV-R
PC5
C4
C3
C2C1
SIGNAL OUTPUT: BNC-R
R21
R20
R19
R22
C6G
SH
K
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
* TO MAGNETICSHIELD CASE
PMT: R329-02 (H6410) R2256-02 (H6521) R5113-02 (H6522)WITH HA COATING
45.0 ± 0.5
39 ± 1
80.0
± 0
.815
00 M
IN.
1 M
AX
.
50 ±
2 PMT: R7761-70WITH HA COATING
POM CASE
POTTING COMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
+H.V: SHIELD CABLE (RED)
R21
R20
R19
R18
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY19
DY18
DY17
DY16
DY15
DY14
DY13
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C5
C4
C3
C2
C1
K
R25
R24
R23
R22
R1 to R21R22, R28
R23 to R25R26R27
C1 to C5C6, C7
: 330 kΩ: 1 MΩ: 51 Ω: 10 kΩ: 100 kΩ: 0.01 µF: 0.0047 µF
P
C6
SIGNAL OUTPUT: RG-174/U (BLACK)
+H.V: SHIELD CABLE (RED)
C7R27 R26
R28
PHOTOCATHODE
27 MIN.
33.0 ± 0.5
29.0 ± 0.7
25 MIN.
PHOTOCATHODE
85 ±
2
1500
MIN
.
WITH HA COATING
PMT: R6427 (H7415)R7056 (H7416)
MAGNETIC SHIELD CASE (t=1.0 mm)
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)
-H.V: SHIELD CABLE (RED)
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
-H.V: SHIELD CABLE (RED)
P
C3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
R16
R15
R14
130.
0 ±
0.8
1 M
AX
.
* TO MAGNETICSHIELD CASE
R1,R2R3R5
R4,R6 to R13R14 to R16
C1 to C3
: 430 kΩ: 470 kΩ: 510 kΩ: 330 kΩ: 51 Ω: 0.01 µF
* MAGNETIC SHIELD IS CONNECTEDTO GND INSIDE OF THIS PRODUCT.
THE H7415-01 IS A VARIANT OF H7415WITH A TERMINAL RESISTOR (50Ω).
53
(Unit: mm)
!8 H1949-50
60.0 ± 0.5
53.0 ± 1.5
46 MIN.
235.
0 ±
0.5
1 M
AX
.
PHOTOCATHODE
PMT: R1828-01 (H1949-50)
MAGNETIC SHIELD CASE (t=0.8 mm)
-HV
A1
A2
DY
-H.V: SHV-RANODE
OUTPUT 2: BNC-R
WITH HA COATING
R2059 (H3177-50)R4004 (H4022-50)
R1, R21R2, R5
R3, R7 to R12, R16R4, R6
R13, R14, R17R15
R18 to R20C1
C2 to C4, C10C5, C6
C7C8, C9
C11, C12
: 10 kΩ: 120 kΩ: 100 kΩ: 180 kΩ: 150 kΩ: 300 kΩ: 51 Ω: 470 pF: 0.01 µF: 0.022 µF: 0.033 µF: 4700 pF: 0.01 µF
R17
DY12
-H.V: SHV-R
PC7
K
ANODE OUTPUT 2: BNC-R
R21
R1
Acc
C11
ANODE OUTPUT 1: BNC-R
DYNODE OUTPUT: BNC-R
C10
G
C12
C1
DYNODE OUTPUT: BNC-R
ANODE OUTPUT 1: BNC-R
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
DY11DY10DY9DY8DY7DY6DY5DY4DY3DY2
DY1
R16R15R14R13R12R11R10R9R8R7R6R5
R4R3R2
R20R19R18
C6C5C4C3C2
C9C8
TPMHA0325EC
!7 H7195
TPMHA0323EC
!9 H1949-51
60.0 ± 0.5
53.0 ± 1.5
46 MIN.
235.
0 ±
0.5
1 M
AX
.
PHOTOCATHODE
PMT: R1828-01 (H1949-51) R2059 (H3177-51) R4004 (H4022-51)WITH HA COATING
MAGNETIC SHIELD CASE (t=0.8 mm)
-HV
A1
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
PC6
C5
C4
C3
C2
C1
SIGNAL OUTPUT: BNC-R
R1, R4R2, R5
R3, R6 to R11, R17R12 to R16R18 to R20
R21C1 to C7
C8C9
C10C11
: 240 kΩ: 360 kΩ: 200 kΩ: 300 kΩ: 51 Ω: 10 kΩ: 0.01 µF: 0.022 µF: 0.033 µF: 0.01 µF: 470 pF
R20
R19
R18
G1
Acc
-H.V: SHV-R
C11
R21
C9
C8
C7
C10
K
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
TPMHA0326EC
-HV
A1
A2
DY
60.0 ± 0.5
53.0 ± 1.5
46 MIN.
215
± 1
1 M
AX
.
PHOTOCATHODE
PMT: R329-02WITH HA COATING
MAGNETIC SHIELD CASE (t=0.8 mm)
- H.V: SHV-R
ANODE OUTPUT 2: BNC-R
DYNODE OUTPUT: BNC-R
R1, R25R2 to R4, R17 to R19
R5, R6, R8 to R13, R15R16, R20, R21
R7, R14R22
R23, R24C1C2C3C4C5C6C7
: 10 kΩ: 110 kΩ
: 100 kΩ: 160 kΩ: 51 Ω: 100 Ω: 470 pF: 0.022 µF: 0.047 µF: 0.1 µF: 0.22 µF: 0.47 µF: 0.01 µF
R21R20R19R18R17R16R15R14R13R12R11R10
R9
R8R7R6R5R4R3R2
DY12
DY11
DY10DY9DY8DY7DY6DY5
DY4DY3DY2DY1
-H.V: SHV-R
PC6
C5
C4
C3C2
K
ANODE OUTPUT 2: BNC-R
R25
R24
R23
R22
R1
C1G
C7
ANODE OUTPUT 1: BNC-RDYNODE OUTPUT: BNC-R
ANODE OUTPUT 1: BNC-R
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
SH
@0 H2431-50
TPMHA0327EB
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HVSIG
60.0 ± 0.5
53.0 ± 1.5
46 MIN.
200
± 1
1 M
AX
.
PHOTOCATHODE
PMT: R2083 (H2431-50)
MAGNETIC SHIELD CASE (t=0.8 mm)
WITH HA COATINGR3377 (H3378-50)
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
PC8
C6
C4
C3
C2
C1
SIGNAL OUTPUT: BNC-R
R17
F
ACC
-H.V: SHV-R
C1
R1
C13
C12
C10 C11C9
C7
C5
K
* TO MAGNETICSHIELD CASE
R1R2, R15
R3, R4, R13R5
R6, R16R7
R8 to R11R12R14R17
C1, C2C3 to C11C12, C13
C14
: 33 kΩ: 390 kΩ: 470 kΩ: 499 kΩ: 360 kΩ: 536 kΩ: 300 kΩ: 150 kΩ: 430 kΩ: 51 Ω: 4700 pF: 0.01 µF: 1000 pF: 2200 pF
54
@2 H10570
@3 R2238-01
TPMHA0555EA
@1 H6614-70
60.0 ± 0.5
52 ± 1
39 MIN.
1500
MIN
.
PHOTOCATHODE
801
MA
X.
PMT: R5924-70WITH HA COATING
BLACK COATING
POM CASE
AL PANEL
SIGNAL OUTPUT: RG-174/U (BLACK)
+H.V: SHIELD CABLE (RED)
+0 -1
R21
R20
R19
R18
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R8
R6
R5
R4
R3
R2
R1
DY19
DY18
DY17
DY16
DY15
DY14
DY13
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C5
C4
C3
C2
C1
K
R1 to R21R22, R29
R23 to R26R27R28
C1 to C5C6, C7
: 330 kΩ: 1 MΩ: 51 Ω: 10 kΩ: 100 kΩ: 0.01 µF: 0.0047 µF
R26
R25
R24
R23
R22
P
C6
SIGNAL OUTPUT: RG-174/U (BLACK)
+H.V: SHIELD CABLE (RED)
C7R28 R27
R29
TPMHA0472EB
TPMHA0151EA
@4 H6525, H6526
84.5 ± 0.5
77.0 ± 1.5
65 MIN.
PHOTOCATHODE
1 M
AX
.
MAGNETIC SHIELD CASE (t=0.8 mm)
205.
0 ±
0.8
285
± 6
104.
0 ±
0.5
(AS
SY
PA
RTS
LE
NG
TH)
PMT: R4143 (H6525)
WITH HA COATINGR4885 (H6526)
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
PC6
C5
C4
C3
C2
C1
SIGNAL OUTPUT: BNC-R
R3, R4R2, R5
R1, R6 to R11, R17R12 to R16R18 to R20
R21C1 to C7
C8C9
C10C11
: 240 kΩ: 360 kΩ: 200 kΩ: 300 kΩ: 51 Ω: 10 kΩ: 0.01 µF: 0.022 µF: 0.033 µF: 0.01 µF: 470 pF
R20
R19
R18
G1Acc
-H.V: SHV-R
C11
R21
C9
C8
C7
C10
K
G2
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HVSIG
67.0 ± 0.5
TPMHA0330EB
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1-H.V: SHIELD CABLE (RED)
PC3
C2
C1
K
SIGNAL OUTPUT: RG-174/U (BLACK)
C4
R2
R1HA COATING
R1R2R3
R4 to R15R16C1C2C3C4
: 10 MΩ: 1 kΩ: 480 kΩ: 240 kΩ: 51 kΩ: 0.01 µF: 0.02 µF: 0.03 µF: 0.0047 µF
R16
77 ± 1
70 MIN.
PHOTOCATHODE
PMT: R2238WITH HA COATINGAND HEAT SHRINKABLETUBE
PC-BOARD60 ± 0.5
SIGNAL OUTPUT: RG-174/U (BLACK)
-H.V: SHIELD CABLE (RED)
75 ±
215
00 M
IN.
55 ±
2
-HVSIG
VOLTAGE DIVIDER CURRENT=383 µA / 1750 V (MAX.) INPUT
AC
TIV
E V
OLT
AG
E D
IVID
ER
C3
C2
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
R11
C1
DY8
P
DY7
DY5
DY4
DY2
DY3
DY1
Acc
G
K
DY6
R1 to R7R8 to R10
R11C1 to C3
: 300 kΩ: 51 Ω: 1 MΩ: : 0.022 µF
-H.V INPUT: SHV-R
ANODE OUTPUT: BNC-R
60.0 ± 0.5
52.0 ± 1.5
46 MIN.
PHOTOCATHODE
MAGNETIC SHIELD CASE
200.
0 ±
0.5
1 M
AX
.
-H.V INPUT: SHV-R
ANODE OUTPUT: BNC-R
55
(Unit: mm)
@5 H6559 @6 H6527, H6528
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HV
SIG
1 M
AX
.
40 ±
1
218
± 1
70 ± 1
83 ± 1
77.0 ± 1.5
65 MIN.
PHOTOCATHODE
MAGNETIC SHIELD CASE (t=0.8 mm)
PMT: R6091WITH HA COATING
R1, R5R2, R10, R16
R3, R9R4, R6 to R8, R14, R18
R11, R13, R17R12, R15
R19R20, R21
R22C1C2C3C4C5C6
: 240 kΩ: 220 kΩ: 180 kΩ: 150 kΩ: 300 kΩ: 360 kΩ: 51 Ω: 100 Ω: 10 kΩ: 0.022 µF: 0.047 µF: 0.1 µF: 0.22 µF: 0.47 µF: 470 pF
R18R17R16R15R14R13R12R11R10R9R8
R7
R6R5R4R3R2R1
DY12
DY11
DY10DY9DY8DY7DY6DY5
DY4DY3DY2DY1
-H.V: SHV-R
PC5
C4
C3
C2C1
SIGNAL OUTPUT: BNC-R
R21
R20
R19
R22
C6G
SH
K
* TO MAGNETICSHIELD CASE
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
TPMHA0331EB TPMHA0332ED
140
± 1
360
± 6
2 M
AX
.
PHOTOCATHODE
MAGNETIC SHIELD CASE (t=0.8 mm)
56
259
± 2
120 MIN.
131 ± 2
142.0 ± 0.8
77
74
40
R1584 (H6528)WITH HA COATING
PMT: R1250 (H6527)
SOCKET ASSYHOUSING
BLACK TAPE
R17
R16
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY14
DY13
DY12
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
P
C5
C4
C3
C2
C1
SIGNAL OUTPUT: BNC-R
R1, R17R2R3R4R5
R6 to R13R14, R15
R16R18
R19, R20R21
: 240 kΩ: 360 kΩ: 390 kΩ: 120 kΩ: 180 kΩ: 100 kΩ: 150 kΩ: 300 kΩ: 51 Ω: 100 Ω: 10 kΩ
C1C2C3C4C5C6
: 0.022 µF: 0.047 µF: 0.1 µF: 0.22 µF: 0.47 µF: 470 pF
R20
R19
R18
R21 -H.V: SHV-R
C6G1
G2
K
H6527=Flat window, BorosilicateH6528=Curved window, UV glass
-H.V: SHV-R
SIGNAL OUTPUT: BNC-R
-HV
SIG
* MAGNETIC SHIELD IS CONNECTED TO GND INSIDE OF THIS PRODUCT.
* TO MAGNETICSHIELD CASE
@7 R3600-06
TPMHA0156EC
610
± 20
460 MIN.
695
TY
P.
PMT: R3600-02
(85)
82.7 ± 2.0
116CABLE LENGTH
5000
HEATSHRINKABLETUBE
PHOTOCATHODE
254 ± 10
R15
R14
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
P
C3
C2
C1
R17
R16
K
SIGNAL OUTPUT: RG-58C/U (BLACK)
SIGNAL/HV GND
R18C4
F3
F2
F1
+H.V: SINGLE WIRE
R1R3R4R5
R2,R6 to R15R16
R17, R18C1, C2C3, C4
: 1.3 MΩ: 549 kΩ: 5.49 kΩ: 820 kΩ: 274 kΩ: 200 kΩ: 10 kΩ: 0.001 µF: 4700 pF
508 ± 10
HYBRID CABLE *
* HYBRID CABLE CONTAINS A SIGNAL CABLE AND HV WIRE WITH ADDITIONAL COVER.
56
@8 H8711, H8711-100, H8711-200 @9 H7546B, H7546B-100, H7546B-200
#1 H7260K, H7260K-100, H7260K-200#0 H8804
TPMHA0487ED
TPMHA0455EDTPMHA0550EA
52.0 ± 0.5
24.0
± 0
.5
70.
8 T
YP
.35
.0 ±
0.5
3.3
31.8
2.54 × 15 = 38.11.27 2.54
2.54
5.08
7.62
-HV INPUT TERMINAL ( 0.5)
GND TERMINALPIN ( 0.5)ANODE #1
ANODE #2
HOUSING (POM)
ANODE #32
ANODE #31
ANODEWINDOW #1
0.8
1
ANODEWINDOW #32
DY10 OUTPUTPIN ( 0.5)
ANODE #1 to #32 OUTPUT ( 0.46)(16 PIN × 2 LINE 2.54 PITCH)
A32-ANODE - A2 -HV
DY OUT A31-ANODE - A1 GND7.5
GN
D T
ER
MIN
AL
PIN
SHIELD
SHIELD
-HV
INP
UT
TE
RM
INA
L P
IN
P1 P2 P31 P32
AN
OD
E1
OU
TPU
T
AN
OD
E2
OU
TPU
T8 × 2 LINE2.54 PITCH
AN
OD
E31
OU
TPU
T
AN
OD
E32
OU
TPU
T
DY
10 O
UT
PU
T
R10
GK
R1 to R7R8, R9
R10R11
C1 to C4
: 220 kΩ: 51 Ω: 1 MΩ: 10 kΩ: 0.01 µF
VO
LTA
GE
DIV
IDE
R C
UR
RE
NT
= 0
.37
mA
at -
900
V (
MA
X. R
AT
ING
) IN
PU
T
R7
R6
R5
R4
R3
R2
R1
C1
C2
C3C4
DY1
DY2
DY3
DY4
DY5
DY6
DY7
DY8
DY9
DY10R9
R11
R8
ACTI
VE B
ASE
CIRC
UIT
30.0 ± 0.5
4 × 164.5 PITCH
4- 0.3GUIDE MARKS
TOP VIEW
SIDE VIEW
BOTTOM VIEW
25.7
12
34
1314
1516
25.7
18.1
0.3
4.2
45.0
± 0
.8
0.8
MA
X.
2.8
DIVIDER ASSEMBLY
POM CASE
INSULATINGTAPE
PMT:R7600-00-M16 (H8711)R7600-100-M16 (H8711-100)R7600-200-M16 (H8711-200)
GN
D
GN
D-H
VD
Y
P8
P1
P16
P9
2.54
× 7=
17.7
8
2.54
12.7
7.62
2.545.082.54
Dy12 OUTPUT TERMINAL PIN ( 0.46)
-HV INPUTTERMINAL PINS ( 0.46)
ANODE OUTPUTTERMINAL PIN( 0.46,2.54 PITCH 8 × 4)
4-SCREWS (M2)
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
R14
C2
C1
C3C4
KF
R17
R18
R34
R16
R15
Dy12
Dy11
Dy10
Dy9
Dy8
Dy7
Dy6
Dy5
Dy4
Dy3
Dy2
Dy1
AN
OD
E15
OU
TP
UT
AN
OD
E16
OU
TP
UT
GN
D
-HV
INP
UT
GN
D
P15 P16
R13
DY
12 O
UT
PU
TG
ND
GN
D
AN
OD
E1
OU
TP
UT
AN
OD
E2
OU
TP
UT
GN
D
GN
D
GN
D
P1 P2
GN
D
AN
OD
E9
OU
TP
UT
TE
RM
INA
L P
INS
TE
RM
INA
L P
INS
TE
RM
INA
L P
INS
P9
AN
OD
E8
OU
TP
UT
P8
TE
RM
INA
L P
INS
R1 to R3R4 to R13
R14R15 to R17
R18C1 to C4
: 360 kΩ: 180 kΩ: 1 MΩ: 51 Ω: 10 kΩ: 0.01 µF
30.0 ± 0.5
0.8
MA
X.
45 ±
0.8
4.2
5.2
2.54×7=17.78
2.54
2.54
×9=2
2.86
2.54
12345678
5758596061626364
25.7
18.1
0.3 2
45
P8 P1
P64 P57
0.95
4- 0.3 GUIDE MARKS
ANODE OUTPUT TERMINAL PINS ( 0.64) 2.54 PITCH 8 × 8
4-SCREWS (M2) -HV INPUT TERMINAL PINS( 0.64)
GND TERMINAL PIN ( 0.64)
Dy12 OUTPUTTERMINAL PIN( 0.64)
POM CASE
SOFT TAPE
PMT:R7600-00-M64 (H7546B)R7600-100-M64 (H7546B-100)R7600-200-M64 (H7546B-200)
4- 0.3GUIDE MARKS
X
Y
P64
P57
P8P1
P1
P8
P9
P16
P17
P24
P25
(PINS CONNECTION: BOTTOM VIEW)
*A: THROUGH HOLE (NO CONNECTION)
P32
P33
P40
P41
P48
P49
P56
P57
GND-HV
*A
GND
DY12OUT
P64
12
34
56
78
5758
5960
6162
6364
BOTTOM VIEW
DY12 OUTPUT TERMINAL PIN ( 0.64)TS-101-T-A-1, SAMTEC
GND TERMINAL PIN ( 0.64)TS-101-T-A-1, SAMTEC
ANODE OUTPUT TERMINAL PINS( 0.64, 2.54 PITCH, 8 × 8)TD-108-T-A-1, SAMTEC × 4 PCS
-HV TERMINAL PINS ( 0.64)ASP-23882-A-1, SAMTEC
0.3
24- 0.3GUIDE MARKS
2- 3.5
25.7
FILLED WITH INSULATOR
45.0 ± 0.8
5.2
4.2
SIDE VIEW
30.0
± 0
.5
2.54×
7=17
.78
2.54
POM CASE
DIVIDER ASSEMBLY
PMT: R7600-M64 SERIES
TOP VIEW
45
0.95
X
Y
4- 0.3GUIDE MARKS
40.0
± 0
.3
48.0
± 0
.5
30+0.5 -0
5+0.5 -0
2.54×9=22.86
2.54
4-SCREWS (M2)
FK
R21
R1 R2 R3
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9 Dy10 Dy11 Dy12
R4 R5 R6 R7 R8 R9 R10 R11 R12 R13
C1 C3
C4
R14
R17 R18 R19 R20
R15 R16
-HV INPUT TERMINAL PIN( 0.64)
P1P2P63P64
AN
OD
E1
OU
TP
UT
AN
OD
E2
OU
TP
UT
AN
OD
E63
OU
TP
UT
AN
OD
E64
OU
TP
UT
Dy1
2 O
UTP
UT
TER
MIN
AL
PIN
( 0
.64)
2.54 PITCH( 0.64) 8 × 8
GN
D T
ER
MIN
AL
PIN
( 0
.64)
× 2
......
R1, R5 to R14R2 to R4, R15
R16R17 to R19
R20R21
C1 to C3C4
: 100 kΩ: 200 kΩ: 300 kΩ: 51 Ω: 10 kΩ: 1 MΩ: 0.022 µF: 0.01 µF
C2
TPMHA0506EC TPMHC0223EB
F
K R21 R1
R2
R3Dy1
Dy2
Dy3
Dy4
Dy5
Dy6
Dy7
Dy8
Dy9
Dy10
Dy11
Dy12
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
C1
C2
C3C4
R14
R17
R18
R19
R20
R15
R16
-HV INPUT TERMINAL PIN( 0.64)
P1
P2
P63
P64
ANODE1 OUTPUT
ANODE2 OUTPUT
ANODE63 OUTPUT
ANODE64 OUTPUT
Dy12 OUTPUTTERMINAL PIN ( 0.64)
2.54 PITCH( 0.64)8 × 8
GND TERMINAL PIN( 0.64) × 2
......
R1, R5 to R14R2 to R4, R15
R16R17 to R19
R20R21
C1 to C3C4
: 100 kΩ: 200 kΩ: 300 kΩ: 51 Ω: 10 kΩ: 1 MΩ: 0.022 µF: 0.01 µF
57
(Unit: mm)
#2 H8500C
#3 H9500
TPMHA0544EA
TPMHA0504EB
-HVSHV-P(SHIELD CABLE, RED)
DY1K DY2
R1 R2
DY3
R3
DY4
R4
DY5
R5
DY6
R6
DY7
R7
DY8
R8
DY9
R9
R16
C1
ACTIVE VOLTAGEDIVIDER
DY
12 O
UT
PU
T
GN
D
DY10
R17
DY11
R18
DY12 GR P1
R20
R22
R21
C2 R19C3
C7
C8
AN
OD
E O
UT
PU
T (
P1)
P2
AN
OD
E O
UT
PU
T (
P2)
P15
AN
OD
E O
UT
PU
T (
P15
)P16
AN
OD
E O
UT
PU
T (
P16
)(P
17 t
o P
32)
(P22
5 to
P24
0)
P241
AN
OD
E O
UT
PU
T (
P24
1)
P242A
NO
DE
OU
TP
UT
(P
242)
P255
AN
OD
E O
UT
PU
T (
P25
5)
P256
AN
OD
E O
UT
PU
T (
P25
6)
. ..... ...... ......
....
4 × 0.8 mm PITCH HEADER(P/N QTE-040-03-F-D-A, SAMTEC)
R1 to R9: 470 kΩ (±5 %, 0.125 W)R16 to R18: 51 Ω (±5 %, 0.125 W)R19: 10 kΩ (±5 %, 0.125 W)R20: 1 MΩ (±5 %, 0.125 W)R21, R22: 4.99 kΩ (±5 %, 0.125 W)C1, C7: 0.01 µF (200 V)C2: 0.022 µF (200 V)C3: 0.033 µF (200 V)C8: 0.0047 µF (2 kV)DIVIDER CURRENT 180 µA at -1100 V
....
..
....
..
GNDGNDGNDGNDP15P16P31P32P47P48P63P64P79P80P95P96
P111P112P127P128
GNDGNDGNDGNDP13P14P29P30P45P46P61P62P77P78P93P94
P109P110P125P126
P143P144P159P160P175P176P191P192P207P208P223P224P239P240P255P256GNDGNDGNDDY12
OUTPUT
P141P142P157P158P173P174P189P190P205P206P221P222P237P238P253P254GNDGNDGNDGND
SIG4
GNDGNDGNDGNDP11P12P27P28P43P44P59P60P75P76P91P92
P107P108P123P124
GNDGNDGNDGNDP9
P10P25P26P41P42P57P58P73P74P89P90
P105P106P121P122
P139P140P155P156P171P172P187P188P203P204P219P220P235P236P251P252GNDGNDGNDGND
P137P138P153P154P169P170P185P186P201P202P217P218P233P234P249P250GNDGNDGNDGND
SIG3
GNDGNDGNDGNDP7P8
P23P24P39P40P55P56P71P72P87P88
P103P104P119P120
GNDGNDGNDGNDP5P6
P21P22P37P38P53P54P69P70P85P86
P101P102P117P118
P135P136P151P152P167P168P183P184P199P200P215P216P231P232P247P248GNDGNDGNDGND
P133P134P149P150P165P166P181P182P197P198P213P214P229P230P245P246GNDGNDGNDGND
SIG2
GNDGNDGNDGNDP3P4
P19P20P35P36P51P52P67P68P83P84P99
P100P115P116
GNDGNDGNDGNDP1P2
P17P18P33P34P49P50P65P66P81P82P97P98
P113P114
P131P132P147P148P163P164P179P180P195P196P211P212P227P228P243P244GNDGNDGNDGND
P129P130P145P146P161P162P177P178P193P194P209P210P225P226P241P242GNDGNDGNDGND
SIG1
CONNECTION FOR SIGNAL CONNECTORS(BOTTOM VIEW)
23.65 8.68.6
INSULATING TAPE SIG4 SIG3 SIG1SIG2
BASE (POM)
SOCKET HOUSING (POM)
CAP HOUSING (POM)
4-SIGNAL CONNECTOR ; QTE-040-03-F-D-A, SAMTEC(0.8 mm PITCH. DOUBLE ROWWITH INTEGRAL GND PLATE)
NOTE: 4 SETS OF SOCKET AND CABLE ASSEMBLY WILL BE ATTACHED.(SOCKET: QSE-040-01-F-D-A, SAMTEC / CABLE ASSEMBLY: EQCD-040-06, 00-SEU-TEU-1, SAMTEC)
PH
OT
OC
AT
HO
DE
(E
FF
EC
TIV
E A
RE
A)
4
9
5
2.0
± 0.
3
14.4 ± 0.5
1.5
33.3 ± 0.9
36.4 ± 0.9
46.2
4
3.04 × 14=42.56
3.04
49
1173349658197113129145161177193209225241
2183450668298114130146162178194210226242
3193551678399115131147163179195211227243
42036526884100116132148164180196212228244
52137536985101117133149165181197213229245
62238547086102118134150166182198214230246
72339557187103119135151167183199215231247
82440567288104120136152168184200216232248
92541577389105121137153169185201217233249
102642587490106122138154170186202218234250
112743597591107123139155171187203219235251
122844607692108124140156172188204220236252
132945617793109125141157173189205221237253
143046627894110126142158174190206222238254
153147637995111127143159175191207223239255
163248648096112128144160176192208224240256
TOP VIEW SIDE VIEW
CABLE ASSEMBLY (SUPPLIED)
BOTTOM VIEW
M3 DEPTH: 4
-HV: SHV-P(SHIELD CABLE, RED)
START MARK
SEPARATION MARKON FOCUSING ELECTRODE
3.04
× 1
4=42
.56
3.04
450
+20
-0
6
2.6 MAX.
170 ± 5
14.98
6.88
15.72
50.8
50.8
RIBBONIZED COAXIAL CABLE(50 Ω IMPEDANCE)
(MATES WITH QSE-040-01 -F-D-A)
(MATES WITH QTE-040-03 -F-D-A)
METAL PLATE (GND)
GNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGND
*A
P7P8
P15P16P23P24P31P32P39P40P47P48P55P56P63P64
DY12GND
SIG4
GNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGND
P5P6
P13P14P21P22P29P30P37P38P45P46P53P54P61P62GND
*A
SIG3
GNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGND
*A
GND
P3P4
P11P12P19P20P27P28P35P36P43P44P51P52P59P60GNDGND
SIG2
CONNECTION FOR SIGNAL CONNECTORS(BOTTOM VIEW)
GNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGNDGND
P1P2P9
P10P17P18P25P26P33P34P41P42P49P50P57P58*A
GNDSIG1
4.5 ± 0.342
12 × 3=36
52.0
± 0
.3
36
-HV
H85
00
DY
,64,
63
8, 7
625
16, 1
5,56
, 55
60, 5
93
12, 1
1, 4
,52
, 51
GN
D
58,
110
, 9, 2
,57
, 50,
49
14, 1
3, 6
,61
, 54,
53
SIG
4
SIG
3
SIG
2
SIG
1
INSULATING TAPE
PLASTIC BASE
PC BOARD 4-SIGNAL OUTPUT CONNECTOR *B
TMM-118-03-G-D, mfg. SAMTEC
NOTE *A: Polarized position of omitted pin*B: Suitable sockets for the signal connectors will be attached. The equivalent socket is SQT-118-01-L-D (SAMTEC). As it doesn't have a polarized position marker, it can be used at any positions.-HV: SHV-P
(SHIELD CABLE, RED)
450
± 20
PH
OT
OC
AT
HO
DE
(E
FF
EC
TIV
E A
RE
A)
4
9
22
× 17
=34
5
2.0
± 0.
3
16.4 ± 0.51.5 4
27.4 ± 0.932.7 ± 1.0
6.08
× 6
=36
.48
6.26
6.26
6.08 × 6=36.48 6.266.26
P1
P9
P17
P25
P33
P41
P49
P57
P2
P10
P18
P26
P34
P42
P50
P58
P3
P11
P19
P27
P35
P43
P51
P59
P4
P12
P20
P28
P36
P44
P52
P60
P5
P13
P21
P29
P37
P45
P53
P61
P6
P14
P22
P30
P38
P46
P54
P62
P7
P15
P23
P31
P39
P47
P55
P63
P8
P16
P24
P32
P40
P48
P56
P64
TOP VIEW SIDE VIEW
BOTTOM VIEW
0
.5M3 DEPTH 2.5
START MARK
-HVSHV-P(SHIELD CABLE, RED)
DY1K DY2
R1 R2
DY3
R3
DY4
R4
DY5
R5
DY6
R6
DY7
R7
DY8
R8
DY9
R9
R16
C1
ACTIVE VOLTAGEDIVIDER
DY
12 O
UT
PU
T
SIG
NA
L G
ND
DY10
R17
DY11
R18
DY12 GR P1
R20
R22
R21
C2 R19C3
C7
C8C9
AN
OD
E O
UT
PU
T (
P1)
P2
AN
OD
E O
UT
PU
T (
P2)
P3
AN
OD
E O
UT
PU
T (
P3)
P4
AN
OD
E O
UT
PU
T (
P4)
P5
AN
OD
E O
UT
PU
T (
P5)
P6
AN
OD
E O
UT
PU
T (
P6)
P7
AN
OD
E O
UT
PU
T (
P7)
P8
AN
OD
E O
UT
PU
T (
P8)
(P9
to P
16)
(P49
to P
56)
P57
AN
OD
E O
UT
PU
T (
P57
)
P58
AN
OD
E O
UT
PU
T (
P58
)
P59
AN
OD
E O
UT
PU
T (
P59
)
P60
AN
OD
E O
UT
PU
T (
P60
)
P61
AN
OD
E O
UT
PU
T (
P61
)
P62
AN
OD
E O
UT
PU
T (
P62
)
P63
AN
OD
E O
UT
PU
T (
P63
)
P64
AN
OD
E O
UT
PU
T (
P64
)
. .....
....
4-(DOUBLE-ROW 2 mm Pitch) CONNECTOR
R1 to R9: 470 kΩR16 to R18: 51 ΩR19: 10 kΩR20: 1 MΩR21, R22: 4.99 kΩC1: 0.01 µFC2: 0.022 µFC3: 0.033 µFC7: 0.0047 µFC8, C9: 0.0015 µF
DIVIDER CURRENT 173 µA at -1100 V
58
Quick Reference for PMT Socket Assemblies
TubeDiameter
AssemblyTypeNo.
OutlineNo. Notes
Tube Type No./
VoltageDistribution
Ratio
Refe-rence
Page forPMT
Feature
202420202420202020202420212026
20
20
202020202020202022222224222224222226222226242424242222222222
SHV
SHV
SHV
AWG22SHVSHVSHV
AWG22AWG24
SHVAWG22
AWG22
SHV
SHVAWG22
SHV
SHV
AWG22SHV
AWG22
SHIELDCABLE
SHIELDCABLE
SHIELDCABLE
SHV
SHV
BNC
BNC
BNC
RG-174/UBNCBNCBNC
RG-174/UAWG24
BNCRG-174/U
RG-174/U
BNC
BNCRG-174/U
BNC
BNC
RG-174/UBNC
RG-174/U
RG-174/U
RG-174/U
RG-174/U
BNC
BNC
-1500
-1500
-1250
-1250-1800-1800-1800-1800-1750+2300-1800
-1500
-1250
-2000-2000-1750-1250-1250-1750-1250-1250-1750-3000
-1500
+1500
-1500
+1500
-2700-2500
-2700-2500
-1250
-1250
-1000
-1000-1000-1500-1700-1500-1250+2000-1250
-1000
-1000
-1500-1500-1250-1000-1000-1500-1000-1000-1250-2500
-1000
+1000
-1000
+1000
-2000
-1500
6 µA is for total of 2 anodes.E6133-03 (-HV) is available.For R7899 (Glass Base Type)
with shield case
shield case is available.+HV type (E5859-02) is available.
shield case is available.+HV type (E5859-03) is available.
t
u
!7
@9
@0
@6
!2
@1
#2
1
@9
!4
@8
#2
#3
@3
@5
@3
$4
e
e
y
%3
%0
z
z
x
c
v
v
b
n
m
,
.
⁄0
⁄1
⁄2
⁄3
⁄4
⁄4
⁄5
⁄6
⁄7
⁄8
⁄9
⁄9
¤0
¤0
E1761-21
E1761-22
E849-90
E849-68E974-17E974-22E2253-05E974-19E2037-02E6133-04E2924-11
E990-29
E2924-500
E2624-14E2624-04
E2183-500
E2183-501
E1198-07E2979-500
E1198-05
E1198-20
E1198-26
E1198-27
E5859
E5859-01
R1635R2248R2496R647-01R2102R4124R1166R1450R3478R4125R1548-07R5505-70R7899R3998-02R3998-100-02
R1924A
R7111
R6427
R580R980R3886
R2154-02R1828-01
R1306R1538R1307
R6231R6231-100R6232R6233R6233-100R6234R6235R6236R6237R329-02R6091R329-02R331-05R6091
10 mm(3/8")
13 mm(1/2")
19 mm(3/4")
25 mm(1")
25 mm(1")
28 mm(1-1/8")28 mm(1-1/8")
38 mm(1-1/2")
51 mm(2")
51 mm(2")
60 mm(2.4")
76 mm(3")
51 mm(2")
76 mm(3")
Assembly CharacteristicsPMT CharacteristicsMaximum
RatingStandard
Rating
(V)
Overall1
Voltage
0.35
0.32
0.28
0.230.270.370.340.270.130.360.28
0.23
0.24
0.320.370.320.260.260.540.360.360.320.58
0.31
0.28
0.25
0.25
0.5
0.42
(mA)
Divider2
Current(V)
OverallVoltage
H.VInput
Terminal
SignalOutput
Terminal
Note:1: When overall voltage is negative (-HV), DC and pulse signals are obtained. When it's positive (+HV), pulse signal is obtained.2: The maximum average anode current is defined as 5 % of divider current.
59
-1500-1500-2000+1500+1500+2000-1500-1500-2000
-3000
-1800
-1000
-1000
-900
-900
-900
-1000
-1000
-1000
-1250-1250-1500+1250+1250+1500-1250-1250-1500
-2000
-1500
-800
-800
-800
-800
-800
-800
-800
-800
MaximumRating
StandardRating
(V)
Overall1
Voltage
0.320.320.380.320.320.380.320.320.38
0.68
0.32
0.29
0.29
0.3
0.3
0.34
0.27
0.3
0.28
(mA)
Divider2
Current(V)
OverallVoltage
Note:1: When overall voltage is negative (-HV), DC and pulse signals are obtained. When it's positive (+HV), pulse signal is obtained.2: The maximum average anode current is defined as 5 % of divider current.
TubeDiameter
AssemblyTypeNo.
OutlineNo. Notes
Tube Type No./
VoltageDistribution
Ratio
Refe-rence
Page forPMT
Feature
222622
2222
22
22
2424242424242424242424242424
44
24242424
SHIELDCABLE
SHIELDCABLE
SHV
SHV
SHV
PIN
AWG22
SHIELDCABLE
SHIELDCABLE
SHIELDCABLE
SHIELDCABLESHIELDCABLE
PIN
RG-174/U
RG-174/U
BNC
BNC
BNC
PIN
RG-174/U
RG-174/U
0.8D-QEV
0.8D-QEV
0.8D-QEV
RG-174/U
PIN
shield case is available.
+HV type (E7694-01) is available.
on-board type
cable type
Active base type (E6572) is available.
!8
%6
%8
w
w
@2
@2
!7
#7
!6
$0
¤1
¤1
¤2
¤3
¤3
¤4
¤5
¤6
¤7
¤8
¤9
‹0
‹1
E1198-22
E1198-23
E6316-01
E7693
E7694
E5770
E5780
E5996
E7083
E6736
E7514
E10411
E9349
R877R877-100R1512
R1250R1584
R5912
R7081
R7400UR7400U-06
R7600UR7600U-03R7600U-100R7600U-200R7600U-00-M4R7600U-100-M4R7600U-200-M4R5900U-00-L16R5900U-100-L16R5900U-200-L16
R8900U-00-C12
R8900UR8900U-100R8900-00-M16R8900-100-M16
127 mm(5")
204 mm(8")
254 mm(10")
16 mmTO-8Type
30 mmSquareType
Assembly CharacteristicsPMT Characteristics
H.VInput
Terminal
SignalOutput
Terminal
60
Dimensional Outline and Circuit DiagramsFor PMT Socket Assembliesz E1761-21, E1761-22
x E849-90 c E849-68
v E974-17, E974-22
TACCA0075EB TACCA0076EC
E1761-21 E1761-22
13K
R4DY3 2
R6
DY4 10
R2DY1 1
R1
R3DY2 11
R7DY6 9
R5DY5 3
R8DY7 4
R9
P
DY8 8
R10 C2
C1DY9 5
R11 C3DY10 7
6SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
-HV: SHIELD CABLE (RED)SHV CONNECTOR
PMT SOCKETPIN No.
R1 to R11C1 to C3
: 330 kΩ: 10 nF
14.0 ± 0.3
45.0
± 0
.545
0 ±
10
510
0.5
MA
X.
12.6
12.4
POTTINGCOMPOUND
HOUSING(INSULATOR)
TACCA0077ED
14.0 ± 0.3
45.0
± 0
.545
0 ±
10
5
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C3
C2
C1
P
K
7
8
6
9
4
11
3
12
2
13
10
0.5
MA
X.
10
12.6
12.4
5
R1R3
R2, R4 to R11C1 to C3
: 1 MΩ: 510 kΩ: 330 kΩ: 10 nF
POTTINGCOMPOUND
HOUSING(INSULATOR)
SOCKETPIN No.PMT
SIGNAL OUTPUTRG-174/U (BLACK)
SIGNAL GND
POWER SUPPLY GNDAWG22 (BLACK)
-HVAWG22 (VIOLET)
TACCA0210EB
TACCA0212EB TACCA0078EC
E974-17 E974-22
10.6 ± 0.2
50.0
± 0
.545
0
HOUSING(INSULATOR)
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
-H.V: SHIELD CABLE (RED)SHV CONNECTOR
SOCKET: E678-11N
3
11R1
K
R2DY1 2
R4DY2 10
R3
R5DY3 3
R6DY4 9
R7DY5 4
R8
P
C1DY6 8
R9 C2DY7 5
R10 C3DY8 7
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
-H.V: SHIELD CABLE (RED)SHV CONNECTOR
6
PMTSOCKETPIN No.
R1 to R4R5 to R10 C1 to C3
: 510 kΩ: 330 kΩ: 10 nF
11R1
K
R2
R3R4
DY1 2
R5DY2 10
R6DY3 3
R7DY4 9
R8DY5 4
R9
P
C1DY6 8
R10 C2DY7 5
R11 C3DY8 7
SIGNAL OUTPUT : RG-174/U (BLACK)BNC CONNECTOR
-H.V: SHIELD CABLE (RED)SHV CONNECTOR
6PMT
SOCKETPIN No.
R1 to R11C1 to C3
: 330 kΩ: 10 nF
23.0 ± 0.5
47.5
± 1
.045
0 ±
10
43.0
± 0
.5
17.4 ± 0.2
POTTINGCOMPOUND
HOUSING(INSULATOR)
E974-17, -18 attaches BNCand SHV connector at theend of cables.
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C3
C2
C1
P
K
5
6
4
7
2
9
1
10
12
11
8
3
-HV: SHIELD CABLE (RED)SHV CONNECTOR
R1R2 to R11C1 to C3
: 510 kΩ: 330 kΩ: 10 nF
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
SOCKETPIN No.PMT
11K
DY2
12
R4DY3 1
R3
DY1R2
R1
R5DY4 9
R6DY5 2
R7DY6 8
R8
P
DY7 3
C3
R9 C1DY8 7
R10 C2DY9 4
5
R11DY10
SIGNAL OUTPUT: RG-174/U(BLACK)BNC CONNECTOR
-HV: SHIELD CABLE(RED)SHV CONNECTOR
10
6
PMTSOCKETPIN No.
R1R3
R2, R4 to R11C1 to C3
: 680 kΩ: 510 kΩ: 330 kΩ: 10 nF
61
b E2253-05
m E2037-02
. E2924-11
n E974-19
, E6133-04
⁄0 E990-29
(Unit: mm)
TACCA0079EB TACCA0230EB
TACCA0028EC TACCA0231EB
TACCA0032EC TACCA0215EC
55.0
± 0
.545
0 ±
10
HOUSING(INSULATOR)
11K
R6DY3 1
R8
DY4 9
R4DY1 12
R5DY2 10
R9DY6 8
R7DY5 2
R10DY7 3
P
DY8 7C2
R11 C3
C1
R1R2R3
6.2
5
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
-HV: SHIELD CABLE (RED)SHV CONNECTOR
PMT SOCKETPIN No.
18.6+0 -0.4
R1R2R3
R4, R6 to R11R5
C1 to C3
: 1 MΩ: 750 kΩ: 560 kΩ: 330 kΩ: 510 kΩ: 10 nF
SIGNAL OUTPUT: RG-174/U (BLACK)
GND: AWG22 (BLACK)
R1R2 to R7
R8,R11 to R13R9, R10
R14 to R16C1 to C3
: 499 kΩ: 330 kΩ: 390 kΩ: 300 kΩ: 360 kΩ: 10 nF
17.4 ± 0.2
23.0 ± 0.5
43.0
± 0
.547
.5 ±
1.0
450
105
HOUSING(INSULATOR)
SOCKET: E678-12H
P
R15 C3
R16
R14DY10
R13
C2
6
K
R12
C1
R11DY9
R104
R9DY8
R87
DY7R7
3
DY6R6
8
DY5R5
2
DY4R4
9
DY3R3
1
DY2R2
10
DY1
R1
12
-HV: AWG22 (VIOLET)
5
11
+20
-0
5
GND: AWG22 (BLACK)
SIGNAL OUTPUT: RG-174/U (BLACK)
-HV: AWG22 (VIOLET)
PMT SOCKETPIN No.
24 ± 0.5
30.0
± 0
.545
0 ±
10
2
21.9
2 R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C3
C2
C1
SIGNAL OUTPUT2: AWG24(RED)
: 2.7 MΩ: 680 kΩ: 1 MΩ: 10 nF
R1R2, R4 to R11
R3C1 to C3
-HV: AWG24(VIOLET)
P
K
8
7
9
6
10
11
5
12
4
13
3
14
2
17
POWER SUPPLY GND: AWG24(BLACK)
SOCKETPIN No.PMT
SIGNAL OUTPUT1: AWG24(YELLOW)
SIGNAL GND: AWG24(BLACK)
HOUSING(INSULATOR)
POTTINGCOMPOUND
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
+H.V: SHIELD CABLE (RED)SHV CONNECTOR
R1R2 to R18
R19R20, R21
R22 to R24C1 to C5
C6, C7
: 10 kΩ: 330 kΩ: 100 kΩ: 1 MΩ: 51 Ω: 10 nF: 4.7 nF
22.0 ± 0.5
24.0 ± 0.5
255
.0 ±
0.5
450
± 10
HOUSING(INSULATOR)
DY15
P
R24
R1
R20
R17 C49
R18 C5
R19 C7
C6
DY14R23
R16 C311
DY13R22
R15 C28
R21
K
DY12R14 C1
12
DY11R13
7
DY10R12
13
DY9R11
6
DY8R10
14
DY7R9
5
DY6R8
15
DY5R7
4
DY4R6
16
DY3R5
3
DY2R4
17
DY1R3
2
R2
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
+H.V: SHIELD CABLE (RED)SHV CONNECTOR
10
1
POTTINGCOMPOUND
PMT SOCKETPIN No.
26.0 ± 0.3
7
43.0
± 0
.5 0.8
450
± 10
28.0 ± 0.5
2- 3.5
44.0 ± 0.3
35.0 ± 0.3
30.0
± 0
.3
POTTINGCOMPOUND
HOUSING(INSULATOR)
R1 to R4, R6 to R13R5
C1 to C3
: 330 kΩ: 510 kΩ: 10 nF
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
C3
C2
C1
SIGNAL GNDSIGNAL OUTPUTRG-174/U (BLACK)
-HVAWG22 (VIOLET)
P
K
7
SOCKETPIN No.PMT
10
6
11
5
12
4
13
3
14
2
1
POWER SUPPLY GNDAWG22 (BLACK)
14K
G
R4DY3
2
R6DY4
12
R2DY1
1R1
R3DY2
13
R7DY6
10
R5
DY5
3
R8DY7
5
R9
P
DY8
9
R10 C2
C1
DY9
6
R11 C38
7
R1R2 to R6,R8 to R11
R7C1 to C3
: 1 MΩ: 330 kΩ: 510 kΩ: 10 nF
26.0 ± 0.3
7
43.0
± 0
.5 0.8
450
± 10
28.0 ± 0.5
POTTINGCOMPOUND
HOUSING(INSULATOR)
PMT SOCKETPIN No.
SIGNAL OUTPUTRG-174/U (BLACK)
POWER SUPPLY GNDAWG22 (BLACK)
-HVAWG22 (VIOLET)
SIGNAL GND
2- 3.5
44.0 ± 0.3
35.0 ± 0.3
30.0
± 0
.3
62
⁄1 E2924-500
26.0 ± 0.3
43.0
± 0
.545
0 ±
10
: 330 kΩ: 10 nF: 4.7 nF
R1 to R13C1 to C3
C4
28.0 ± 0.5
70.
8
35.0 ± 0.3
44.0 ± 0.3
30.0
± 0
.3
2- 3.5
1
K
R1111
R12 C2
C4
6
R13 C310Dy10
Dy9
Dy8R10
5Dy7R9
12Dy6R8
4Dy5R7
13Dy4R6
3Dy3R5
14Dy2R4
2Dy1R3
R2
R1
C1
-HVSHIELD CABLE (RED)SHV CONNECTOR
P
7SIGNAL OUTPUTRG-174/U (BLACK)BNC CONNECTOR
HOUSING(INSULATOR)
PMT SOCKETPIN No.
POTTINGCOMPOUND
TACCA0081EC
⁄2 E2624-14
⁄3 E2624-04 ⁄4 E2183-500, E2183-501
⁄5 E1198-07
: 1320 kΩ: 510 kΩ: 330 kΩ: 51 Ω: 10 nF: 4.7 nF
R1 R3
R2, R4 to R11R12 to R14
C1 to C3C4
13R1
K
R84
R9 C1
C4
9
R10 C25
R11 C3Dy10 8
Dy9
Dy8
Dy7R7
10Dy6R6
3Dy5R5
11Dy4R4
2Dy3R3
12Dy2R2
14Dy1
-H.V: SHIELD CABLE (RED)SHV CONNECTOR
P
7
SIGNAL OUTPUT : RG-174/U (BLACK)BNC CONNECTOR
PMT SOCKETPIN No.
R14
R13
R12
28.0 ± 0.5
26.0 ± 0.3
44.0 ± 0.3
35.0 ± 0.3
30.0
± 0
.3
43.0
± 0
.5
7
450
± 10
2- 3.5
0.8
POTTINGCOMPOUND
HOUSING(INSULATOR)
TACCA0082EC
TACCA0084ED
TACCA0086EC
TACCA0166EC
E2183-500
E2183-501
The housing is internallyconnected to the GND.
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
C3
C2
C1
C4
10
9
8
7
6
5
4
3
2
1
14
11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
P
56.0 ± 0.3
450
± 10
64.0 ± 0.3
38.0
± 0
.5
HOUSING(METAL)
POWER SUPPLY GNDAWG22 (BLACK)
SIGNAL OUTPUTRG-174/U (BLACK)
R1R2 to R11C1 to C3
C4
: 680 kΩ: 330 kΩ: 10 nF: 4.7 nF
-HVAWG22 (VIOLET)
SIGNAL GNDSOCKETPIN No.
PMT
TACCA0220EB
12
K
R108
C5
R1
5
7
C4
Dy10
Dy9
Dy8R9
4Dy7R8
9Dy6R7
3Dy5R6
10Dy4R5
2Dy3R4
11Dy2R3
1Dy1R2
C2
C1
-H.V: SHIELD CABLE (RED)SHV CONNECTOR
P
6
SIGNAL OUTPUT: RG-174/U (BLACK)BNC CONNECTOR
R13R14
C3R11R12
PMT SOCKETPIN No.
R15 R1R2, R11, R13
R3 to R7, R14R8R9
R10R12R15C1C2C3C4C5
: 10 kΩ: 300 kΩ: 150 kΩ: 180 kΩ: 220 kΩ: 330 kΩ: 240 kΩ: 51 Ω:10 nF: 22 nF: 47 nF: 100 nF: 4.7 nF
K
SOCKETPIN NO.PMT
SIGNAL OUTPUT:RG-174/U (BLACK)BNC CONNECTOR
-HV: SHIELD CABLE(RED)SHV CONNECTOR
R1
C4
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
C3
C2
C1
P
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
6
7
5
8
4
9
3
10
2
11
1
12
R1R2
R3 to R12C1 to C3
C4
: 10 kΩ: 660 kΩ: 330 kΩ: 10 nF: 4.7 nF
34.0 ± 0.3
40.0
± 0
.545
0 ±
10
HOUSING(INSULATOR)
8.2
52.0 ± 0.5
POTTINGCOMPOUND
49.0
± 0
.545
0 ±
1010
5
4
13
K
9
R9 C3
C1
C2
R10 C45
R11 C5 C6Dy10 8
Dy9
Dy8R8
4Dy7R7
10Dy6R6
3Dy5R5
11Dy4R4
2Dy3R3
12R2
R114Dy1
Dy2
-H.V : AWG22/TFE(VIOLET)
P
SIGNAL OUTPUT : RG-174/U (BLACK)
GND : AWG22 (BLACK)
25.2 ± 0.5
32.0 ± 0.57
PMT SOCKETPIN No.
R14
R13
R12HOUSING(INSULATOR)
POTTINGCOMPOUND
SIGNAL GND
R1R2, R4 to R6
R3, R8R7R9
R10R11
R12 to R14C1
C2, C3C4 to C6
: 800 kΩ: 200 kΩ: 300 kΩ: 240 kΩ: 400 kΩ: 660 kΩ: 600 kΩ: 51 Ω: 10 nF: 22 nF: 33 nF
63
⁄6 E2979-500 ⁄7 E1198-05
⁄8 E1198-20
(Unit: mm)
3-M2
62.0 ± 0.5
164.
0 ±
0.5
82.0
± 0
.5
11
-H.V : SHV-R
-H.V
SIG
19
20KG1
G2ACC
R116
C1
R1
13
7C4
C5 C8
C6 C9C11
12
8
11
DY7
DY10
DY12
DY11
DY9
DY8
DY6
DY5
R1014
R95
R815DY4
DY3
DY2
R73
R617
R52DY1
R4
R3
R2
C2
P10
C3R12
R13
R14
R15R16
R17R18
R19
R20
R21C7 C10
R1R2, R5
R3, R7 to R12, R18R4, R6
R13 to R17R19 to R21
C1C2 to C8, C11
C9C10
: 10 kΩ: 240 kΩ: 200 kΩ: 360 kΩ: 300 kΩ: 51 Ω: 470 pF: 10 nF: 22 nF: 33 nF
The housing is internallyconnected to the GND.
MAGNETICSHILD CASE
HOUSING(METAL)
SIGNALOUTPUT: BNC-R
PMT SOCKETPIN No.
SIGNAL OUTPUTBNC CONNECTOR
-HVSHV CONNECTOR
TACCA0093EB TACCA0221EB
TACCA0223EC
⁄9 E1198-26, E1198-27
C4
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2 R1
C3
C2
C1
11
10
7
6
5
4
3
1
13
14
12
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
G
P
56.0 ± 0.3
450
± 10
64.0 ± 0.3
38.0
± 0
.5
HOUSING(METAL)
The housing is internallyconnected to the GND.
-HVSHIELD CABLE (RED)
POWER SUPPLY GND
R1R2, R3
R4 to R11C1 to C3
C4
: 10 kΩ: 680 kΩ: 330 kΩ: 10 nF: 4.7 nF
SIGNAL OUTPUTRG-174/U (BLACK)
SIGNAL GNDSOCKETPIN No.PMT
TACCA0224EB
The housing is internallyconnected to the GND.
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
R11R12
R13
C3
C2
C1
C4
C5
11
10
7
6
5
4
3
1
13
14
12
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
G
P
R1 to R2R3 to R11
R12R13
C1 to C3C4, C5
: 680 kΩ: 330 kΩ: 10 kΩ: 1 MΩ: 10 nF: 4.7 nF
+HVSHIELD CABLE (RED)
SIGNAL OUTPUTRG-174/U (BLACK)
SIGNAL GND
POWER SUPPLY GND
SOCKETPIN No.PMT
TACCA0225EB
E1198-26 E1198-27
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
R11
C3
C2
C1
C4
C5
8
7
6
5
4
3
2
1
13
14
11
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
G
P
56.0 ± 0.3
450
± 10
64.0 ± 0.3
38.0
± 0
.5
+HVSHIELD CABLE (RED)
SIGNAL OUTPUTRG-174/U (BLACK)
R1 to R11C1 to C3
C4, C5
: 330 kΩ: 10 nF: 4.7 nF
The housing is internallyconnected to the GND.
HOUSING(METAL)
SOCKETPIN No.PMT SIGNAL GND
POWER SUPPLY GND
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
C3
C2
C1
C4
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
G
P
56.0 ± 0.3
450
± 10
64.0 ± 0.3
38.0
± 0
.5
GNDAWG22 (BLACK)
SIGNAL OUTPUTRG-174/U (BLACK)
R1 to R10C1 to C3
C4
: 330 kΩ: 10 nF: 4.7 nF
-HVAWG22 (VIOLET)
HOUSING(METAL)
The housing is internallyconnected to the GND.
8
7
6
5
4
3
2
1
13
14
11
SOCKETPIN No.PMT
64
¤2 E6316-01
TACCA0089EB
-H.V : SHV-R
HOUSING(METAL)
THREADED HOLESFOR INSTALLATIONOF MAGNETICSHIELD CASE(e. g; E989-60 FOR R877
E989-61 FOR R878)
SIGNAL OUTPUT: BNC-R
-H.V
SIG
51.5
± 0
.5
64.0 ± 0.5
13
14K
G
R118
C4
R1
9
10C3
Dy10
Dy9
Dy8R10
7Dy7R9
6Dy6R8
5Dy5R7
4Dy4R6
3Dy3R5
2Dy2R4
1Dy1R3
R2
C1
-H.V: SHV-R
P11
SIGNAL OUTPUT : BNC-R
C2R12
R13
PMT SOCKETPIN No.
TO AL HOUSING
Note: Magnetic shield case is available to order separately.
The housing is internallyconnected to the GND.
R1R2 to R13C1 to C3
C4
: 10 kΩ: 330 kΩ: 10 nF: 4.7 nF
¤0 E5859, E5859-01
¤1 E1198-22, E1198-23
TACCA0176EC
E5859 E5859-01
E1198-22 E1198-23
TACCA0178EC
TACCA0168EB TACCA0169EC
58.0 ± 0.5
51.0 ± 0.4
60.0 ± 0.5
12.5
9
55.0
± 0
.5
-H.V:SHV-R
-H.V
SIG
3-M2(THREADED HOLESFOR INSTALLATIONOF MAGNETICSHIELD CASE)
HOUSING(METAL)
SIGNAL OUTPUT:BNC-R
R1R2, R12, R16, R17, R20, R21
R3, R13, R18, R19, R22 to R24R4, R5, R7, R8
R6, R9 to R11, R14, R15R25
R26, R27C1C2C3C4
C5 to C7
: 10 kΩ: 180 kΩ: 226 kΩ: 121 kΩ: 150 kΩ: 51 kΩ: 100 Ω: 470 pF: 22 nF: 47 nF: 100 nF: 220 nF
Dy12
Dy11
Dy10
Dy9
Dy7
Dy6Dy5
Dy4Dy3
Dy2Dy1
P
G
K
Dy8
R1
C1
R23
R24
R27
R18R19
R25
R20
R21
R22
R26
R16
R17
R15
R14
R13
R11
R12
R10
R9
R8
R7
R6R5R4R3R2
C2
C3
C4
C5
C6 C7
1
17
21
16
2
15
3
14
4
13
5
12
6
8
7
-HVSHV-R
SH 10
The housing is internallyconnected to the GND.
SIGNAL OUTPUT: BNC-R
PMT SOCKETPIN No.
R1R2 to R6,R9 to R13
R7,R8R14 to R21,R23,R24
R22R25
R26,R27C1
C2,C3C4
: 10 kΩ: 220 kΩ: 154 kΩ: 110 kΩ: 0 Ω: 51 Ω: 100 Ω: 470 pF: 10 nF: 22 nF
Dy12
Dy11
Dy10
Dy9
Dy7
Dy6Dy5
Dy4Dy3
Dy2Dy1
P
G
K
Dy8
R1
C1
R23
R24
R27
R18R19
R25
R20
R21
R22
R26
R16
R17
R15
R14
R13
R11
R12
R10
R9
R8
R7
R6R5R4R3R2
C2
C3
C4
1
17
21
16
2
15
3
14
4
13
5
12
6
8
7
-HVSHV-R
SH 10
The housing is internallyconnected to the GND.
SIGNAL OUTPUTBNC-R
PMT SOCKETPIN No.
56.0 ± 0.3
450
± 10
64.0 ± 0.3
38.0
± 0
.5
HOUSING(METAL)
SIGNAL GND
POWER SUPPLY GND
SIGNAL OUTPUTRG-174/U (BLACK)
SOCKETPIN No.PMT
R1R2 to R13C1 to C3
C4
: 10 kΩ: 330 kΩ: 10 nF: 4.7 nF
R1
C4
-HVSHIELD CABLE (RED)
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
C3
C2
C1
11
10
9
8
7
6
5
4
3
2
1
13
14
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
K
G
P
* The housing is internally connected to the GND.
** High voltage shielded cable can be connected to a connector for RG-174/U.
SIGNAL GNDSIGNAL OUTPUTRG-174/U (BLACK)
P
K
SOCKETPIN No.
G
PMT
C4 R14
C5
C6
+HVSHIELD CABLE (RED)
POWER SUPPLY GNDDY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
R1
11
10
9
8
7
6
5
4
3
2
1
13
14
C3
C2
C1
R1 to R12R13R14
C1 to C4C5, C6
: 330 kΩ: 1 MΩ: 10 kΩ: 10 nF: 4.7 nF
* The housing is internally connected to the GND.** High voltage shielded cable can be connected to
a connector for RG-174/U.
65
¤3 E7693, E7694
¤4 E5770 ¤5 E5780
¤6 E5996
(Unit: mm)
TACCA0227EC
E7693 E7694
TACCA0229EB
TACCA0057EF TACCA0060EE
TACCA0234ED
74.0 ± 0.5
100.
0 ±
0.5
-H.V: SHV-R
SIG
-H.V
HOUSING(METAL)
SIGNALOUTPUT: BNC-R
19
20K
7
R1912
R208
R21 R18
R17
R16
R15
R14
C5
C4
C3
C2
C1
C6
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4R3
R2 R1
Dy14 11
Dy13
Dy12
Dy11
13Dy10
6Dy9
14Dy8
3Dy3
16Dy4
4Dy5
15Dy6
5Dy7
17Dy2
2Dy1
P
10
G1
G2
R1R2, R18
R3R4R5R6
R7 to R14R15, R16
R17R19
R20, R21C1C2C3C4C5C6
: 10 kΩ: 240 kΩ: 360 kΩ: 390 kΩ: 120 kΩ: 180 kΩ: 100 kΩ: 150 kΩ: 300 kΩ: 51 Ω: 100 Ω: 22 nF: 47 nF: 100 nF: 220 nF: 470 nF: 0.47 nF
The housing is internallyconnected to the GND.
-HV: SHV-R
SIGNAL OUTPUT: BNC-R
PMT SOCKETPIN No.
192
20K
R18
R19
R20 R17
R16
R15
R14
C3
C2
C1
C4
R13
R12
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2 R1
12Dy10
7Dy9
13Dy8
3Dy3
16Dy4
4Dy5
14Dy6
5Dy7
17Dy2
1Dy1
F1F2F3
P
8
R1R2, R3, R7
R4, R9R5R6R8
R10R11 to R17R18 to R20
C1 to C3C4
: 10 kΩ: 750 kΩ: 200 kΩ: 91 kΩ: 510 kΩ: 300 kΩ: 100 kΩ: 150 kΩ: 51 Ω: 10 nF: 4.7 nF
18
The housing is internallyconnected to the GND.
-HV: SHV-R
SIGNAL OUTPUT: BNC-R
PMT SOCKETPIN No.
R1 to R3R4 to R11
R12 to R14R15
C1 to C3
: 330 kΩ: 220 kΩ: 51 Ω: 1 MΩ: 10 nF
DY10
30
24
23
22
21
20
19
7
6
5
4
1
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1K
C3P
POWER SUPPLY GND
C2
C1
R11
R9
R8
R7
R6
R5
R4
R3
R2
R1
R10
R14
R12
R15
R13
SIGNAL OUTPUTRG-174/U (BLACK)
-HVSHIELD CABLE (RED)
PMTSOCKETPIN No.
SIGNAL GND30.0 ± 0.5
30.0
± 0
.515
.0 ± 0
.545
0 ±
10
PIN No.1
HOUSING(INSULATOR)
POTTINGCOMPOUND
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
R9
R8
R7
R6
R5
R4
R3
R2
R1
C3
C2
C1
P
K
R1 to R8R9
C1 to C3
: 330 kΩ: 160 kΩ: 10 nF
15 ±
0.5
450
17 ± 0.2
GND (BLACK)
SOCKETRG-174/U
GUIDE MARK
6
SIGNAL OUTPUT: RG-174/U
GND: AWG22 (BLACK)
-HV: AWG22 (VIOLET)
-HV (VIOLET)
HOUSING(INSULATOR)
17±0.2
710
±0.5
2.54
10.16
5.08
-HV
GND
SIGNAL OUT
0.45
GUIDE MARK
Top View
Side View
Bottom View
2.54
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
R9
R8
R7
R6
R5
R4
R3
R2
R1
C3
C2
C1
GND or +HVP
K-HV or GND
R1 to R8R9
C1 to C3
: 330 kΩ: 160 kΩ: 10 nF/ 200 V
SIGNAL OUT6
For +HV, it will be necessary to use a coupling capacitor between the output and the customer's signal processing circuit.
66
¤8 E6736
¤9 E7514
TACCA0158EE
TACCA0236EC
26
10
24
8
2
18
31
15
32
16K
Dy10
Dy9
Dy8
Dy7
Dy6
Dy5
Dy4
Dy3
Dy2
Dy1
R7
R6
R5
R4
R3
R2
R1R15
R14
R13
R12
1213111972062152242332729
•
•
•
•
•
•
•
•
•
•
•
•
•
28
P16
P15
P14
P13
P12
P11
P10 P
9P
8P
7P
6P
5P
4P
3P
2P
1
P16
P8
P1
-HV: SHIELD CABLE (RED)
R1 to R11R12 to R14
R15C1 to C3
: 220 kΩ: 51 Ω: 1 MΩ: 10 nF
30.0 ± 0.5
30.0
± 0
.5
Pin No.1
15.0
± 0
.545
0 ±
10
HOUSING(INSULATOR)
R11
R10
R9
R8
C3
C2
C1
17
PMT SOCKETPIN No.
POWER SUPPLY GND
SIGNAL GND
SIGANL OUTPUT: 0.8D-QEV (GRAY)
P15 P16 P14GUIDE MARKE
-HV: SHIELD CABLE (RED)P3 P1 P2
P13 P11 P9 P7 P5
P12P10P8P6P4
P1 to P16 : SIGNAL OUTPUT0.8D-QEV (GRAY)
¤7 E7083
TACCA0162ED
30.0 ± 0.5
30.0
± 0
.515
.0 ±
0.5
450
± 10
PIN No.1
P4
P3
P1
GUIDE MARK
POTTINGCOMPUND
P2
-HV: SHIELD CABLE (RED)
R1 to R3R4 to R11
R12 to R14R15
C1 to C3
: 330 kΩ: 220 kΩ: 51 Ω: 1 MΩ: 10 nF
DY10
27
15
11
31
24
23
22
21
20
19
7
6
5
4
1
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1K
C3P4 P3 P2 P1
P4
P3
P2
P1
C2
C1
R11
R9
R8
R7
R6
R5
R4
R3
R2
R1
R10
R14
R12
R15
R13
SIGNAL OUTPUT: 0.8D-QEV (GRAY)
P1 to P4: SIGNAL OUTPUT0.8D-QEV (GRAY)
HOUSING(INSULATOR)
SIGNAL GND
POWER SUPPLY GND
-HV: SHIELD CABLE (RED)
PMTSOCKETPIN No.
25.4 ± 0.5PIN No. 1
25.4
± 0
.5
KG
: 110 kΩ: 330 kΩ: 220 kΩ: 1 MΩ: 51 Ω: 10 nF
R1, R14R2
R3 to R13R15
R16 to R18C1 to C3
PX4
PY4
PX3
PY3
PX2
PY2
PX1
PY1
PX4
PY4
PX3
PY3
PX2
PY2
PX1
PY1
DY11
DY10
DY9
DY8
DY7
DY6
DY5
DY4
DY3
DY2
DY1
R11
R10
R9
R8
R7
R6
R5
R4
R3
R2
C3
C2
C1
R14
R13
R12
R18
R17
R16
R15 R1
15.0
± 0
.545
0
HOUSING(INSULATOR)
GUIDE MARK
POTTINGCOMPOUND
-H.V: SHIELD CABLE (RED)
PY3PY2
PY4PY5PY6
PX3PX4
PX1PX2 PY1
PX6PX5
PX6
PY6
PX5
PY5
PX6
PY6
PX5
PY5
SIGNAL GNDPMTSOCKETPIN No.
-H.VSHIELD CABLE (RED)
POWER SUPPLY GND
SIGNAL OUTPUT: 0.8D-QEV (GRAY)
PX1 to PX6PY1 to PY6: SIGNAL OUTPUT
0.8D-QEV (GRAY)
28
6
29
5
30
4
31
3
1
32
8
27
7
10
19
11
20
12
14
22
23
15
16
24
13
67
‹0 E10411
‹1 E9349
(Unit: mm)
TACCA0298EA
TACCA0297EB
-HVSHIELD CABLE (RED)
POWER SUPPLY GND
R1, R12R2R3
R4 to R11R13 to R15
R16C1 to C3
: 110 kΩ: 330 kΩ: 430 kΩ: 220 kΩ: 51 Ω: 1 MΩ: 10 nF
15.0
± 0
.545
0
HOUSING(INSULATOR)
PIN No.125.4 ± 0.5
25.4
± 0
.5
DY1
K1
3
4
5
6
7
19
20
21
22
23
24
31
DY2
DY3
DY4
DY5
DY6
DY7
DY8
DY9
DY10
P
R3
R2
R1
R4
R5
R6
R7
R8
R9
R10
R11
R12
R13
R16
R14
R15
C1
C2
C3
SIGNAL GND
SIGNAL OUTPUTRG-174/U (BLACK)
SOCKETPIN No.
PMT
R1, R4R2, R3
R5 to R15R16
R17 to R19R20
C1 to C4
: 110 kΩ: 330 kΩ: 180 kΩ: 1 MΩ: 51 Ω: 10 kΩ: 10 nF
-HV P1 P5 P9 P13 DY OUT
P4 P8 P12
P16
P14P
15
P2P3
GND
GND
KG
R16
R17
R3
R2
R1
DY1
-HV
GND
R4
R5DY2
R6DY3
R7DY4
R8DY5
R9DY6
R10DY7
R11DY8
R12DY9
R18
R19
R20
R13DY10
R14DY11
R15
C1
C2
C3C4DY12
GND
DY
12
OU
TP
UTANODE OUTPUT
PMTSOCKETPIN No.
SOCKETPIN No.
P16
P16
P15
P15
P14
P14
P13
P13
P12
P12
P11
P11
P10
P10
P9
P9
P8
P8
P7
P7
P6
P6
P5
P5
P4
P4
P3
P3
P2
P2
P1
P1
PIN No.1
HOUSING(INSULATOR)
25.4 ± 0.5
5.08 5.08
2.54 × 3=7.62
21.0
± 0
.55.
5
19.5
19.5
7.62
5.08
GND
ANODE OUTPUTPIN ( 0.64)
GND
4-M2
-HV
DY12 OUTPUT4
5
6
7
12
14
19
20
21
22
23
24
34353637334243383241403931302928
1
3
68
Dimensional OutlineFor E678 Series SocketsE678-11N E678-12A, E678-12R* E678-12L
E678-13FE678-13E
E678-14TE678-14C
4.3
9.5
10.5
11
3
3
9.5
TACCA0043EA
40
47
58
15
17
2- 3.2
34
TACCA0009EB
E678-12V
6.0
1.83
2.54
12.7
4.2
3.2
2.8
0.5
10.16
TACCA0164EC
35
9
3.7
(23.
6)
28.6
13
6.
7360 13
9.5
3.3
10.5
(8)
18
2
7
18
13
2
2-R4
2- 3.2
TACCA0047EA
24
18
2- 2.2
13
11
3
3.4
10TACCA0005EA
5.5
11
12.4
3
710
.5
TACCA0013EB
TACCA0184EA
E678-14W
11
30
172
19.8
56
62
TACCA0200EA
72.5
26
11
.6
30
35
44
19.1
9
25
2- 3.5
TACCA0004EA
* Gold plating type
25.2
19.1
27.5
2
9.5
6.5
3.9
24.5
14
14
69
E678-15C E678-17A
E678-19J E678-20A
E678-21C E678-32B
(Unit: mm)
50
60
40
4
45
25
11.5
40
5
TACCA0201EA
21.9
24
.0
18
.0
22.8
12.0
16.3
14.00.1
TACCA0046EB
60
40
40
5
12
42
6.5
12
45
50
TACCA0203EA
58
52.5
56
1321
610
20
52
TACCA0003EA
R5 56
.8
19
51
54
136.
5
TACCA0066EC TACCA0094ED
22.86
20.32
20.3
2
22.8
6
12.7
2.54
12.7
2.92
4.45
1.57
0.51
MATERIAL: Glass Epoxy
70
Index by Type No.
Type Number Product Page Product PageType Number
R329-02 ................... 51mm (2") dia. PMT ......................... 22R331-05 ................... 51mm (2") dia. PMT ......................... 22R580 ........................ 38mm (1-1/2") dia. PMT ................... 20R647-01 ................... 13mm (1/2") dia. PMT ...................... 20E678 SERIES .......... Socket ........................................ 68, 69R750 ........................ 19mm (3/4") dia. PMT ...................... 21R760 ........................ 13mm (1/2") dia. PMT ...................... 21R762 ........................ 19mm (3/4") dia. PMT ...................... 21E849-68 ................... Socket Assembly .............................. 58E849-90 ................... Socket Assembly .............................. 58R877 ........................ 127mm (5") dia. PMT ....................... 22R877-01 ................... 127mm (5") dia. PMT ....................... 23R877-100 ................. 127mm (5") dia. PMT SBA Type ...... 26R960 ........................ 13mm (1/2") dia. PMT ...................... 21E974-17 ................... Socket Assembly .............................. 58E974-19 ................... Socket Assembly .............................. 58E974-22 ................... Socket Assembly .............................. 58R980 ........................ 38mm (1-1/2") dia. PMT ................... 20E990-29 ................... Socket Assembly .............................. 58R1166 ...................... 19mm (3/4") dia. PMT ...................... 20E1198-05 ................. Socket Assembly .............................. 58E1198-07 ................. Socket Assembly .............................. 58E1198-20 ................. Socket Assembly .............................. 58E1198-22 ................. Socket Assembly .............................. 59E1198-23 ................. Socket Assembly .............................. 59E1198-26 ................. Socket Assembly .............................. 58E1198-27 ................. Socket Assembly .............................. 58R1250 ...................... 127mm (5") dia. PMT ....................... 22R1288A-06 ............... 25mm (1") dia. PMT ......................... 20R1306 ...................... 51mm (2") dia. PMT ......................... 22R1306-15 ................. 51mm (2") dia. PMT ......................... 23R1307 ...................... 76mm (3") dia. PMT ......................... 22R1307-07 ................. 76mm (3") dia. PMT ......................... 23R1450 ...................... 19mm (3/4") dia. PMT ...................... 20R1512 ...................... 127mm (5") dia. PMT ....................... 22R1538 ...................... 60mm (2.5") Hexagon PMT .............. 24R1538-01 ................. 60mm (2.5") Hexagon PMT .............. 25R1548-07 ................. 25mm (1" Dual) Square PMT ........... 24R1584 ...................... 127mm (5") dia. PMT ....................... 22R1635 ...................... 10mm (3/8") dia. PMT ...................... 20E1761-21 ................. Socket Assembly .............................. 58E1761-22 ................. Socket Assembly .............................. 58R1828-01 ................. 51mm (2") dia. PMT ......................... 22R1840 ...................... 51mm (2") dia. PMT ......................... 22R1924A .................... 25mm (1") dia. PMT ......................... 20R1924A-01 ............... 25mm (1") dia. PMT ......................... 21H1949-50 ................. Hybrid Assembly .............................. 49H1949-51 ................. Hybrid Assembly .............................. 49E2037-02 ................. Socket Assembly ............................. 58R2059 ...................... 51mm (2") dia. PMT ......................... 23R2076 ...................... 19mm (3/4") dia. PMT ...................... 21R2083 ...................... 51mm (2") dia. PMT ......................... 22R2102 ...................... 13mm (1/2") Square PMT ................ 24R2154-02 ................. 51mm (2") dia. PMT ......................... 22E2183-500 ............... Socket Assembly .............................. 58E2183-501 ............... Socket Assembly .............................. 58R2238 ...................... 76mm (3") dia. PMT ......................... 22
R2238-01 ................. Hybrid Assembly .............................. 49R2248 ...................... 10mm (3/8") Square PMT ................. 24E2253-05 ................. Socket Assembly .............................. 58R2256-02 ................. 51mm (2") dia. PMT ......................... 23H2431-50 ................. Hybrid Assembly .............................. 49R2486-02 ................. Position Sensitive PMT .................... 44R2496 ...................... 10mm (3/8") dia. PMT ...................... 20E2624-04 ................. Socket Assembly .............................. 58E2624-14 ................. Socket Assembly .............................. 58E2924-11 ................. Socket Assembly .............................. 58E2924-500 ............... Socket Assembly .............................. 58E2979-500 ............... Socket Assembly .............................. 58R3149 ...................... 51mm (2") dia. PMT ......................... 23H3164-10 ................. Hybrid Assembly .............................. 48H3165-10 ................. Hybrid Assembly .............................. 48H3177-50 ................. Hybrid Assembly .............................. 49H3177-51 ................. Hybrid Assembly .............................. 49H3178-51 ................. Hybrid Assembly .............................. 48R3292-02 ................. Position Sensitive PMT .................... 44R3377 ...................... 51mm (2") dia. PMT ......................... 23H3378-50 ................. Hybrid Assembly .............................. 49R3478 ...................... 19mm (3/4") dia. PMT ...................... 20R3479 ...................... 19mm (3/4") dia. PMT ...................... 21R3600-02 ................. 508mm (20") dia. PMT ..................... 22R3600-06 ................. Hybrid Assembly .............................. 49H3695-10 ................. Hybrid Assembly .............................. 48R3878 ...................... 10mm (3/8") dia. PMT ...................... 21R3886 ...................... 38mm (1-1/2") dia. PMT ................... 20R3991A-04 .............. 19mm (3/4") dia. PMT ...................... 20R3998-02 ................. 28mm (1-1/8") dia. PMT ................... 20R3998-100-02 .......... 28mm (1-1/8") dia. PMT SBA Type... 26R4004 ...................... 51mm (2") dia. PMT ......................... 23H4022-50 ................. Hybrid Assembly .............................. 49H4022-51 ................. Hybrid Assembly .............................. 49R4124 ...................... 13mm (1/2") dia. PMT ...................... 20R4125 ...................... 19mm (3/4") dia. PMT ...................... 20R4141 ...................... 13mm (1/2") dia. PMT ...................... 21R4143 ...................... 76mm (3") dia. PMT ......................... 22R4177-04 ................. 13mm (1/2") dia. PMT ...................... 21R4177-06 ................. 13mm (1/2") dia. PMT ...................... 20R4607-06 ................. 51mm (2") dia. PMT ......................... 22R4885 ...................... 76mm (3") dia. PMT ......................... 23R4998 ...................... 25mm (1") dia. PMT ......................... 20R5113-02 ................. 51mm (2") dia. PMT ......................... 23R5320 ...................... 25mm (1") dia. PMT ......................... 21R5330 ...................... 38mm (1-1/2") dia. PMT ................... 20R5505-70 ................. 25mm (1") dia. PMT ......................... 20R5505-70 ................. Fine Mesh PMT ................................ 24R5611A .................... 19mm (3/4") dia. PMT ...................... 21R5611A-01 ............... 19mm (3/4") dia. PMT ...................... 20E5770 ...................... Socket Assembly .............................. 59E5780 ...................... Socket Assembly .............................. 59E5859 ...................... Socket Assembly .............................. 58E5859-01 ................. Socket Assembly .............................. 58E5859-02 ................. Socket Assembly .............................. 58E5859-03 ................. Socket Assembly .............................. 58R5900U-00-L16 ....... Metal Package PMT ......................... 24
71
Type Number Type NumberProduct Page
R5900U-100-L16.......Metal Package PMT SBA Type ........ 26R5900U-200-L16.......Metal Package PMT UBA Type ........ 26R5912 ...................... 204mm (8") dia. PMT ....................... 22R5912-02 ................. 204mm (8") dia. PMT ....................... 22R5924-70 ................. 51mm (2") dia. PMT ......................... 22R5924-70 ................. Fine Mesh PMT ................................ 24E5996 ...................... Socket Assembly .............................. 59R6091 ...................... 76mm (3") dia. PMT ......................... 22E6133-03 ................. Socket Assembly .............................. 58E6133-04 ................. Socket Assembly .............................. 58H6152-70 ................. Hybrid Assembly .............................. 48R6231 ...................... 51mm (2") dia. PMT ......................... 22R6231-01 ................. 51mm (2") dia. PMT ......................... 23R6231-100 ............... 51mm (2") dia. PMT SBA Type ........ 26R6232 ...................... 60mm (2.5") dia. PMT ...................... 22R6232-01 ................. 60mm (2.5") dia. PMT ...................... 23R6233 ...................... 76mm (3") dia. PMT ......................... 22R6233-01 ................. 76mm (3") dia. PMT ......................... 23R6233-100 ............... 76mm (3") dia. PMT SBA Type ........ 26R6234 ...................... 60mm (2.5") Hexagon PMT .............. 24R6234-01 ................. 60mm (2.5") Hexagon PMT .............. 25R6235 ...................... 76mm (3") Hexagon PMT ................. 24R6235-01 ................. 76mm (3") Hexagon PMT ................. 25R6236 ...................... 60mm Square PMT .......................... 24R6236-01 ................. 60mm Square PMT .......................... 25R6237 ...................... 76mm (3") Square PMT .................... 24R6237-01 ................. 76mm (3") Square PMT .................... 25E6316-01 ................. Socket Assembly .............................. 59H6410 ...................... Hybrid Assembly .............................. 49R6427 ...................... 28mm (1-1/8") dia. PMT ................... 20H6520 ...................... Hybrid Assembly .............................. 48H6521 ...................... Hybrid Assembly .............................. 49H6522 ...................... Hybrid Assembly .............................. 49H6524 ...................... Hybrid Assembly .............................. 48H6525 ...................... Hybrid Assembly .............................. 49H6526 ...................... Hybrid Assembly .............................. 49H6527 ...................... Hybrid Assembly .............................. 49H6528 ...................... Hybrid Assembly .............................. 49H6533 ...................... Hybrid Assembly .............................. 48H6559 ...................... Hybrid Assembly .............................. 49E6572 ...................... Socket Assembly .............................. 59R6594 ...................... 127mm (5") dia. PMT ....................... 22H6610 ...................... Hybrid Assembly .............................. 48H6612 ...................... Hybrid Assembly .............................. 48H6613 ...................... Hybrid Assembly .............................. 48H6614-70 ................. Hybrid Assembly .............................. 49E6736 ...................... Socket Assembly .............................. 59R7056 ...................... 28mm (1-1/8") dia. PMT ................... 21R7081 ...................... 254mm (10") dia. PMT ..................... 22R7081-20 ................. 254mm (10") dia. PMT ..................... 22E7083 ...................... Socket Assembly .............................. 59R7111 ...................... 28mm (1-1/8") dia. PMT ................... 20H7195 ...................... Hybrid Assembly .............................. 49R7250 ...................... 508mm (20") dia. PMT ..................... 22H7260K .................... Hybrid Assembly ........................ 24, 49H7260K-100 ............. Hybrid Assembly SBA Type ............. 26H7260K-200 ............. Hybrid Assembly UBA Type ............. 26
R7373A-01 ............... 2π Shape PMT ................................. 24R7400U .................... Metal Package PMT ......................... 24R7400U-03 .............. Metal Package PMT ......................... 25R7400U-06 .............. Metal Package PMT ......................... 24H7415 ...................... Hybrid Assembly .............................. 48H7416 ...................... Hybrid Assembly .............................. 48E7514 ...................... Socket Assembly .............................. 59R7525 ...................... 28mm (1-1/8") dia. PMT ................... 20H7546B .................... Hybrid Assembly ........................ 24, 49H7546B-100 ............. Hybrid Assembly SBA Type ............. 26H7546B-200 ............. Hybrid Assembly UBA Type ............. 26R7600U ................... Metal Package PMT ......................... 24R7600U-100............. Metal Package PMT SBA Type ........ 26R7600U-200............. Metal Package PMT UBA Type ........ 26R7600U-00-M4 ........ Metal Package PMT ......................... 24R7600U-100-M4 ...... Metal Package PMT SBA Type ........ 26R7600U-200-M4 ...... Metal Package PMT UBA Type ........ 26R7600U-03 .............. Metal Package PMT ......................... 25E7693 ...................... Socket Assembly .............................. 59E7694 ...................... Socket Assembly ............................. 59E7694-01.................. Socket Assembly ............................. 59R7723 ...................... 51mm (2") dia. PMT ......................... 22R7724 ...................... 51mm (2") dia. PMT ......................... 22R7725 ...................... 51mm (2") dia. PMT ......................... 22R7761-70 ................. 38mm (1-1/2") dia. PMT ................... 20R7761-70 ................. Fine Mesh PMT ................................ 24R7899 ...................... 25mm (1") dia. PMT ......................... 21R7899-01 ................. 25mm (1") dia. PMT ......................... 20R8055 ...................... 332mm (13") dia. PMT ..................... 22H8135 ...................... Hybrid Assembly .............................. 48R8143 ...................... 2π Shape PMT ................................. 24H8409-70 ................. Hybrid Assembly .............................. 48H8500C .................... Hybrid Assembly ........................ 24, 49R8619 ...................... 25mm (1") dia. PMT ......................... 20H8643 ...................... Hybrid Assembly .............................. 48H8711 ...................... Hybrid Assembly ........................ 24, 49H8711-100 ............... Hybrid Assembly SBA type ............... 26H8711-200 ............... Hybrid Assembly UBA type............... 26H8804 ...................... Hybrid Assembly ........................ 24, 49R8900U .................... Metal Package PMT ......................... 24R8900U-100............. Metal Package PMT SBA Type ........ 26R8900U-00-M4 ........ Metal Package PMT ......................... 24R8900U-100-M4 ...... Metal Package PMT SBA ype .......... 26R8900-00-M16 ......... Metal Package PMT ......................... 24R8900-100-M16 ....... Metal Package PMT SBA ype .......... 26R8900U-00-C12 ....... Position Sensitive PMT .................... 44R8900U-100-C12 ..... Metal Package PMT SBA ype .......... 26R8997 ...................... 38mm (1-1/2") dia. PMT ................... 24E9349 ...................... Socket Assembly .............................. 59R9420 ...................... 38mm (1-1/2") dia. PMT ................... 20R9420-100 ............... 38mm (1-1/2") dia. PMT SBA Type... 26H9500 ...................... Hybrid Assembly ........................ 24, 49R9779 ...................... 51mm (2") dia. PMT ......................... 22R9800 ...................... 25mm (1") dia. PMT ......................... 20E10411 .................... Socket Assembly .............................. 59H10570......................Hybrid Assembly .............................. 49H10580......................Hybrid Assembly .............................. 48
Product Page
72
CAUTIONS AND WARRANTY
WARNING
PRECAUTIONS FOR USE
WARRANTY
Take sufficient care to avoid an electric shock hazardA high voltage used in photomultiplier tube opera-tion may present a shock hazard. Photomultiplier tubes should be installed and handled only by qualified personnel that have been instructed in handling of high voltages. Designs of equipment utilizing these devices should incorporate appropri-
ate interlocks to protect the operator and service personnel.The metal housing of the Metal Package PMT R7400 series, R5900 series and R7600 series are connected to the photo-cathode (potential) so that it becomes a high voltage potential when the product is operated at a negative high voltage (anode grounded).
HIGHVOLTAGE
Handle tubes with extreme carePhotomultiplier tubes have evacuated glass envelopes. Al-lowing the glass to be scratched or to be subjected to shock can cause cracks. Extreme care should be taken in handling, especially for tubes with graded sealing of synthetic silica.
Keep faceplate and base cleanDo not touch the faceplate and base with bare hands. Dirt and fingerprints on the faceplate cause loss of transmittance and dirt the base may cause ohmic leakage. Should they be-come soiled, wipe it clean using alcohol.
Do not expose to strong lightDirect sunlight and other strong illumination may cause dam-age the Photocathode. They must not be allowed to strike the photocathode, even when the tube is not operated.
Handling of tubes with a glass baseA glass base (also called button stem) is less rugged than a plastic base, so care should be taken in handling this type of
tube. For example, when fabricating the voltage-divider cir-cuit, solder the divider resistors to socket lugs while the tube is inserted in the socket.
Cooling of tubesWhen cooling a photomultiplier tube, the photocathode sec-tion is usually cooled. However, if you suppose that the base is also cooled down to -30 °C or below, please consult our sales office in advance.
Helium permeation through silica bulbHelium will permeate through the silica bulb, leading to an in-crease in noise. Avoid operating or storing tubes in an envir-onment where helium is present.
Data and specifications listed in this catalog are subject to change due to product improvement and other factors. before specifying any of the types in your production equipment, please consult our sales office.
All Hamamatsu photomultiplier tubes and related products are warranted to the original purchaser for a period of 12 months following the date of shipment. The warranty is lim-ited to repair or replacement of any defective material due to defects in workmanship or materials used in manufacture.
A: Any claim for damage of shipment must be made directly to the delivering carrier within five days.
B: Customers must inspect and test all detectors within 30 days after shipment. Failure to accomplish said incoming inspection shall limit all claims to 75 % of invoice value.
C: No credit will be issued for broken detectors unless in the opinion of Hamamatsu the damage is due to a bulb crack or a crack in a graded seal traceable to a manufacturing defect.
D: No credit will be issued for any detector which in the judg-ment of Hamamatsu has been damaged, abused, modified or whose serial number or type number have been obliter-ated or defaced.
E: No detectors will be accepted for return unless permission has been obtained from Hamamatsu in writing, the ship-ment has been returned prepaid and insured, the detec-tors are packed in their original box and accompanied by the original data sheet furnished to the customer with the tube, and a full written explanation of the reason for rejec-tion of each detector.
F: When products are used at a condition which exceeds the specified maximum ratings or which could hardly be antici-pated, Hamamatsu will not be the guarantor of the prod-ucts.
73
Typical Photocathode Spectral Response and Emission Spectrum of Scintillators
TPMHB0342ED
A: Borosilicate GlassB: UV GlassC: Synthetic SilicaD: Bialkali PhotocathodeE: High Temp. Bialkali PhotocathodeF: Super BialkaliG: Ultra Bialkali
0
100
WAVELENGTH (nm)
QU
AN
TU
M E
FF
ICIE
NC
Y (
%)
8060
40
20
100.1
RE
LAT
IVE
INT
EN
SIT
Y (
%)
100
10
1
700100 200 300 400 500 600
A
BaF2
LaBr3
Nal (Tl)
LSOCsI (Tl)
BGO
D
G
E
C
F
B
TPMO0007E02JUN. 2009 IPPrinted in Japan (4000)
www.hamamatsu.com
HAMAMATSU PHOTONICS K.K., Electron Tube Division314-5, Shimokanzo, Iwata City, Shizuoka Pref., 438-0193, JapanTelephone: (81)539/62-5248, Fax: (81)539/62-2205
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Swiss Office:Dornacherplatz 74500 Solothurn, SwitzerlandTelephone: (41)32/625 60 60, Fax: (41)32/625 60 61E-mail: [email protected]
Belgian Office:Scientic Park, 7, Rue du BosquetB-1348 Louvain-La-Neuve, BelgiumTelephone: (32)10 45 63 34Fax: (32)10 45 63 67E-mail: [email protected]
Spanish Office:C. Argenters, 4 edif 2Parque Tecnológico del VallésE-08290 Cerdanyola, (Barcelona) SpainPhone: +34 93 582 44 30Fax: +34 93 582 44 31e-mail [email protected]
Germany, Denmark, The Netherlands, Poland:HAMAMATSU PHOTONICS DEUTSCHLAND GmbHMain OfficeArzbergerstr. 10,D-82211 Herrsching am Ammersee, GermanyTelephone: (49)8152-375-0, Fax: (49)8152-2658E-mail: [email protected]
Danish Office:Please contact Hamamatsu Photonics Deutschland GmbH.
The Netherlands Office:PO Box 50.075, NL-1305 AB Almere NetherlandsTelephone: (31)36-5382-123, Fax: (31)36-5382-124E-mail: [email protected]
Poland Office:ul. sw. A. Boboli 8,02-525 Warszawa, PolandTelephone: (48)22-646-00-16, Fax: (48)22-646-00-18E-mail: [email protected]
North Europe and CIS:HAMAMATSU PHOTONICS NORDEN ABMain OfficeSmidesvägen 12,SE-171 41 Solna, SwedenTelephone: (46)8-509-031-00, Fax: (46)8-509-031-01E-mail: [email protected]
Russian Office:Vyatskaya St. 27, bld. 15RU-127015, Moscow, RussiaPhone: +7-(495)-258-85-18, Fax: +7-(495)-258-85-19E-mail: [email protected]
Italy:HAMAMATSU PHOTONICS ITALIA S.R.L.Main OfficeStrada della Moia, 1/E20020 Arese (Milano), ItalyTelephone: (39)02-93 58 1733, Fax: (39)02-93 58 1741E-mail: [email protected]
Rome Office:Viale Cesare Pavese, 435, 00144 Roma, ItalyTelephone: (39)06-50513454, Fax: (39)06-50513460E-mail: [email protected]
Information in this catalog isbelieved to be reliable. However,no responsibility is assumed forpossible inaccuracies or omission.Specifications are subject tochange without notice. No patentrights are granted to any of thecircuits described herein.© 2009 Hamamatsu Photonics K.K.
Quality, technology, and service are part of every product.
REVISED JUN. 2009