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EERF 6396 RF AND MOCROWAVE SYSTEMS
PREDICTIVE E-MAINTENANCE SYSTEM
TEAM MEMBERS APURVA KULKARNI - Receiver 5.8GHz HARSHA CHALLA - Receiver 2.4GHz NISHANT GUMBER Transmitter 2.4GHz SHRADHA SHARMA - Transmitter 2.4GHz
WHAT IS PREDICTIVE E-MAINTENANCE • Refers to “the right information at the right time”
• Maintenance after the system breaks down is expensive, so it is better to avoid the situation.
• Breakdown of machines is unaffordable.
• Required for an in service equipment.
• It allows corrective maintenance of the system.
• Useful for manufacturing industries because of critical machines, in terms of both production and financially.
SYSTEM OVERVIEW
• The system design uses 3 communication channels.
• 1st communication channel , machines in the manufacturing plant send asignal conveying they are faulty to the control room.
• The control room is assumed to be present in the plant arena.
• The second channel transmits this signal further to the concernedcompany. ( manufacturer of the machine).
• Once the signal is received by the concerned personnel, anacknowledgment is sent back to the plant through the third channel.
• How will it help?
SYSTEM OVERVIEW Predictive failure information
Transmitter 1 Receiver 1
Transmitter 2 Receiver 2
Channel 1 – 2.4 GHz
Channel 2 – 5.8 GHz
Channel 3 – 5.4 GHz
BLOCK DIAGRAM OF COMMUNICATION CHANNEL 1
Band Pass Filter
LO
Band Pass Filter
Amp Driver Amp
Power Amp
Band Pass Filter
LO
Image Reject Filter
Amp Driver Amp
Amp Low Pass Filter
TRANSMITTER BLOCK DIAGRAM
RECIEVER BLOCK DIAGRAM
BLOCK DIAGRAM OF COMMUNICATION CHANNEL 2
Band Pass Filter
LO
Band Pass Filter
Amp Driver Amp
Power Amp
Band Pass Filter
LO
Image Reject Filter
Amp Driver Amp
Amp Low Pass Filter
TRANSMITTER BLOCK DIAGRAM
RECIEVER BLOCK DIAGRAM
TOP LEVEL SPECIFICATIONS CHANNEL 1 Parameter Specification
Antenna type Dipole Antenna
Bandwidth 2 – 2.4GHz
Transmit power 5.6 dBm
Gain of transmitter Antenna(Gt) 2.2 dBi
Gain of Receiver Antenna (Gr) 2.2 dBi
Modulation Technique QPSK
Minimum detectable signal(MDS) - 90 dBm
3 dB Beamwidth +/- 35 degrees
Distance 1000 meters
TOP LEVEL SPECIFICATIONS CHANNEL 2Parameter Specification
Antenna type Horn Antenna
Bandwidth 5 – 5.8GHz
Transmit power 15.8 dBm
Gain of transmitter Antenna(Gt) 8 dBi
Gain of Receiver Antenna (Gr) 8 dBi
Modulation Technique QPSK
Minimum detectable signal(MDS) - 90 dBm
3 dB Beamwidth +/- 35 degrees
Distance 5000 meters
CHANNEL 2.4GHz ANTENNA
Frequency 2.4 GHz
Gain 2.2 dBi
Cross Polarization 20 dB
Impedance 50 ΩDipole Antenna
Sunol Sciences Precision Dipole AntennasModel No . PD2450
CHANNEL 5.8GHz ANTENNA
Frequency 5 – 6 GHz
Gain 8
Cross Polarization 20 dB
Impedance 50 ΩHorn Antenna
Broadband Horn Antenna BHA 9118
TRANSMIITTER OF COMMUNICATION CHANNEL 1
TONEID=A1FRQ=.04 GHzPWR=-15 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
AMP_BID=A2GAIN=18 dBP1DB=8 dBmIP3= IP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
BPFBID=F1LOSS=1.1 dBN=3FP1=5.78 GHzFP2=5.85 GHzAP=3.0103 dBNOISE=Auto
AMP_BID=A3GAIN=35 dBP1DB=33 dBmIP3= IP2= MEASREF= OPSAT= NF=6 dBNOISE=AutoRFIFRQ=
TPID=TP2
IN OUT
LO
MIXER_BID=A4MODE=SUMLOMULT=1FCOUT= RFIFRQ= GCONV=-7.5 dBP1DB=10 dBmIP3=30 dBmLO2OUT=-25 dBIN2OUT=-20 dBLO2IN=-25 dBOUT2IN=-25 dBPLO= PLOUSE=Spur reference onlyPIN= PINUSE=IN2OUTH OnlyNF=7.5 dBNOISE=Auto
TONEID=A6FRQ=5.76 GHzPWR=10 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TPID=TP3
TPID=TP4
TPID=TP5
TPID=TP6
BPFBID=F2LOSS=1.1 dBN=3FP1=.035 GHzFP2=.049 GHzAP=3.0103 dBNOISE=Auto
TPID=TP1
fc = 0.04 GHz
P1 = -15 dBm
fc = 0.04 GHz
P1= -16.1 dBm fc = 0.04 GHz
P1 =1.9 dBm
fc = 5.8 GHz
P1 = -5.6 dBm
fc = 5.8 GHz
P1 = -6.7 dBm
fc = 5.8 GHz
P1 =28.3 dBm
CASCADED GAIN
Gain
-10
0
10
20
30
40
50
BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
DB(C_GA(TP.TP1,TP.TP6,1,0,0))[1]transmitter58
p2: Available Gain, Cumulative, dBFreq = 5.8 GHz Gain
-20
0
20
40
60
BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
DB(C_GA(TP.TP1,TP.TP6,1,0,0))[1]transmitter58
p2: Available Gain, Cumulative, dBFreq = 5.8 GHz
CASCADED POWER
Power
-20
-10
0
10
20
30
TONE (A1@1) BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
p1
TONE.A1@1-15 dBm
DB(|P_node(TP.TP1,TP.TP6,0,1,0)|)[1] (dBm)transmitter58
p1: Signal Node Power, dBmFreq = 5.8 GHz
Power
-20
0
20
40
60
TONE (A1@1) BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
p1
TONE.A1@1-15 dBm
DB(|P_node(TP.TP1,TP.TP6,0,1,0)|)[1] (dBm)transmitter58
p1: Signal Node Power, dBmFreq = 5.8 GHz
COMM CHANNEL 1 TX HAND CALCULATIONS
MDS = -90dBm , Gt=Gr=8dBi , f= 5.8GHz => λ = 0.051 m FSPL = 121.69
Using Friis’ equation
Pr = Pt + Gt + Gr – FSPL
Pt = 15.69 dBm EIRP = Pt(dBm) + Gt (dBi) = 15.69 +8 => EIRP = 23.69 dBm
TRANSMITTER COMPONENTS – BAND PASS FILTER
Mini Circuits PIF-40
Features
Centre Frequency 42 MHz
Passbands 39 – 42 MHz
TRANSMITTER COMPONENTS – AMPLIFIER
IF Amplifier
Avago technologies MGA – 665P8
Features
Gain 18.4 dB
Noise Figure 1.2 dB
P1 dB 8 dBm
IP3 point 18.2 dBm
TRANSMITTER COMPONENTS – MIXER
Mixer
Marki Microwave – M2-0226
Features
Conversion Loss 7.5 dB
LO / RF Frequency range 2 to 26.5 GHz
LO to RF Isolation 25 dB
IF Range 0.001 to 6.0 GHz
TRANSMITTER COMPONENTS –POWER AMPLIFIER
Genesis Microwave GPA228-33-35
Features
Frequency Range 2 – 8 GHz
Gain 35 dB
P1 dB point 33 dB
Noise figure 6 dB
RECIEVER OF COMMUNICATION CHANNEL 1 – 5.8 GHz
AMP_BID=A1GAIN=18 dBP1DB=8 dBmIP3=25 dBmIP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
BPFBID=F1LOSS=1.1 dBN=3FP1=5.79 GHzFP2=5.86 GHzAP=3.0103 dBNOISE=Auto
IN OUT
LO
MIXER_BID=A3MODE=DIFFLOMULT=1FCOUT= RFIFRQ= GCONV=-7.5 dBP1DB=10 dBmIP3=30 dBmLO2OUT=-25 dBIN2OUT=-10 dBLO2IN=-25 dBOUT2IN=-25 dBPLO=10 dBmPLOUSE=Spur reference onlyPIN= PINUSE=IN2OUTH OnlyNF=7.5 dBNOISE=Auto
TONEID=A4FRQ=5.76 GHzPWR=10 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TONEID=A5FRQ=5.8 GHzPWR=-90 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TPID=TP1
TPID=TP3
TPID=TP4
AMP_BID=A2GAIN=15 dBP1DB=14.5 dBmIP3= IP2= MEASREF= OPSAT= NF=2.9 dBNOISE=AutoRFIFRQ=
TPID=TP6
TPID=TP5
TPID=TP7
BPFBID=F3LOSS=1.1 dBN=3FP1=5.79 GHzFP2=5.86 GHzAP=3.0103 dBNOISE=Auto
TPID=TP2
AMP_BID=A6GAIN=18 dBP1DB=8 dBmIP3=25 dBmIP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
LPFBID=F4LOSS=1.1 dBN=3FP=.04 GHzNOISE=Auto
Fc = 5.8GHz
P1 = -90 dBm
Fc = 5.8GHz
P1 = -91.1 dBm
Fc = 5.8GHz
P1 = -73.1 dBm Fc = 5.8GHz
P1 = -55.1 dBm
Fc = 5.8GHz
P1 = -56.2 dBm Fc = 0.004 GHz
P1 = -63.7 dBm
Fc = 0.004 GHz
P1 = -64.8dBm
Fc = 0.004 GHz
P1 = -49.8dBm
CASCADED GAIN
GAIN
-10
0
10
20
30
40
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1
DB(C_GA(TP.TP1,TP.TP7,1,0,0))[1]reciever58
p1: Available Gain, Cumulative, dBFreq = 0.04 GHz
GAIN
-20
0
20
40
60
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1
DB(C_GA(TP.TP1,TP.TP7,1,0,0))[1]reciever58
p1: Available Gain, Cumulative, dBFreq = 0.04 GHz
CASCADED NODE POWER
P1_node
-100
-50
0
50
TONE (A5@1) BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1
TONE.A5@1-90 dBm
[email protected] dBm MIXER_B.A3@2
-65.16 dBm
DB(|P_node(TP.TP1,TP.TP7,0,1,0)|)[1] (dBm)reciever58
p1: Signal Node Power, dBmFreq = 0.04 GHz
IP3
10
15
20
25
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1
AMP_B.A1@225 dBm
DB(C_IP3(TP.TP1,TP.TP7,1,1,0,0))[1] (dBm)reciever58
p1: Cascaded OIP3, dBmFreq = 0.04 GHz
CASCADED IP3
COMM CHANNEL 1 RX HAND CALCULATIONS
MDS = -90dBm , Gt=Gr=8dBi , f= 5.8GHz => λ = 0.051 m FSPL = 121.69
Using Friis’ equation
Pr = Pt + Gt + Gr – FSPL
Pt = 15.69 dBm EIRP = Pt(dBm) + Gt (dBi) = 15.69 +8 => EIRP = 23.69 dBm
RECIEVER COMPONENTS – BAND PASS FILTER
Band Pass Filter
Taoglas antenna solutions BPF.58.01
Features
Centre Frequency 5.8 GHz
Insertion Loss Less than 2.1
Pass band Width 70MHz
RECIEVER COMPONENTS – AMPLIFIER
Low Noise Amplifier
Avago Technologies MGA 665P8
Features
Gain 16 dB
P1 dB 8 dBm
Nominal Noise figure 1.45
TRANSMITTER COMPONENTS – MIXER
Mixer
Marki Microwave – M2-0226
Features
Conversion Loss 7.5 dB
LO / RF Frequency range 2 to 26.5 GHz
LO to RF Isolation 25 dB
IF Range 0.001 to 6.0 GHz
TRANSMITTER COMPONENTS – LOW PASS FILTER
Mini Circuits ZX75LP-40
Features
Passband frequency 40 MHz
RF Input power 0.5 W
Insertion loss 1.01 dB
TRANSMITTER COMPONENTS – IF AMPLIFIER
SKY65450-92LF
Features
Gain 15 dB
Typical noise Figure 2.9 dB
Input/ Output Impedance 75 Ω
TRANSMITTER OF COMMUNICATION CHANNEL 2 – 2.4 GHz
AMP_BID=A2GAIN=18 dBP1DB=8 dBmIP3= IP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
AMP_BID=A3GAIN=31 dBP1DB=30 dBmIP3= IP2= MEASREF= OPSAT= NF=6 dBNOISE=AutoRFIFRQ=
BPFBID=F1LOSS=1.1 dBN=3FP1=2.34 GHzFP2=2.53 GHzAP=3.0103 dBNOISE=Auto
BPFBID=F2LOSS=1.1 dBN=3FP1=.035 GHzFP2=.049 GHzAP=3.0103 dBNOISE=Auto
IN OUT
LO
MIXER_BID=A4MODE=SUMLOMULT=1FCOUT= RFIFRQ= GCONV=-7.5 dBP1DB=10 dBmIP3=30 dBmLO2OUT=-25 dBIN2OUT=-20 dBLO2IN=-25 dBOUT2IN=-25 dBPLO= PLOUSE=Spur reference onlyPIN= PINUSE=IN2OUTH OnlyNF=7.5 dBNOISE=Auto
TONEID=A1FRQ=.04 GHzPWR=-15 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TONEID=A6FRQ=2.36 GHzPWR=10 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TPID=TP1
TPID=TP2
TPID=TP4
TPID=TP5
TPID=TP6TP
ID=TP3
fc = 5.8 GHz
P1 =24.3 dBm
fc = 0.04 GHz
P1= -16.1 dBm
fc = 5.8 GHz
P1 = -6.7 dBm
fc = 0.04 GHz
P1 =1.9 dBm
fc = 0.04 GHz
P1 = -15 dBm
fc = 2.4 GHz
P1 = -5.6 dBm
CASCADED GAIN
Gain
-10
0
10
20
30
40
BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
p1
DB(C_GA(TP.TP1,TP.TP6,1,0,0))[1]
transmitter24final
p1: Available Gain, Cumulative, dBFreq = 2.4 GHz
CASCADED NODE POWER
P_Node
-20
-10
0
10
20
30
TONE (A1@1) BPFB (F2@2) AMP_B (A2@2) MIXER_B (A4@2) BPFB (F1@2) AMP_B (A3@2)
p1
TONE.A1@1-15 dBm
DB(|P_node(TP.TP1,TP.TP6,0,1,0)|)[1] (dBm)transmitter24final
p1: Signal Node Power, dBmFreq = 2.4 GHz
COMM CHANNEL 1 TX HAND CALCULATIONS
MDS = -90dBm , Gt=Gr=8dBi , f= 5.8GHz => λ = 0.051 m FSPL = 121.69
Using Friis’ equation
Pr = Pt + Gt + Gr – FSPL
Pt = 15.69 dBm EIRP = Pt(dBm) + Gt (dBi) = 15.69 +8 => EIRP = 23.69 dBm
TRANSMITTER COMPONENTS – BAND PASS FILTER
Mini Circuits PIF-40
Features
Centre Frequency 42 MHz
Passbands 35– 49 MHz
TRANSMITTER COMPONENTS – AMPLIFIER
IF Amplifier
Avago technologies MGA – 665P8
Features
Gain 18.4 dB
Noise Figure 1.2 dB
P1 dB 8 dBm
IP3 point 18.2 dBm
TRANSMITTER COMPONENTS – MIXER
Mixer
Marki Microwave – M2-0226
Features
Conversion Loss 7.5 dB
LO / RF Frequency range 2 to 26.5 GHz
LO to RF Isolation 25 dB
IF Range 0.001 to 6.0 GHz
TRANSMITTER COMPONENTS – DRIVER AMPLIFIER
Genesis Microwave Inc. GPA228-30-31
Features
Gain 31 dB
Noise Figure 6 dB
Frequency of operation 2 – 8 GHz
RECIEVER OF COMMUNICATION CHANNEL 2 – 2.4 GHz
AMP_BID=A1GAIN=18 dBP1DB=8 dBmIP3=25 dBmIP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
BPFBID=F1LOSS=1.1 dBN=3FP1=2.39 GHzFP2=2.48 GHzAP=3.0103 dBNOISE=Auto
IN OUT
LO
MIXER_BID=A3MODE=DIFFLOMULT=1FCOUT= RFIFRQ= GCONV=-7.5 dBP1DB=10 dBmIP3=30 dBmLO2OUT=-25 dBIN2OUT=-10 dBLO2IN=-25 dBOUT2IN=-25 dBPLO=10 dBmPLOUSE=Spur reference onlyPIN= PINUSE=IN2OUTH OnlyNF=7.5 dBNOISE=Auto
TONEID=A4FRQ=2.36 GHzPWR=10 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TONEID=A5FRQ=2.4 GHzPWR=-90 dBmPHS=0 DegCTRFRQ= SMPFRQ= ZS=_Z0 OhmTN=_TAMB DegKNOISE=AutoPNMASK= PNOISE=No phase noise
TPID=TP1
TPID=TP3
TPID=TP4
AMP_BID=A2GAIN=15 dBP1DB=14.5 dBmIP3= IP2= MEASREF= OPSAT= NF=2.9 dBNOISE=AutoRFIFRQ=
TPID=TP6
TPID=TP5
TPID=TP7
BPFBID=F3LOSS=1.1 dBN=3FP1=2.39 GHzFP2=2.48 GHzAP=3.0103 dBNOISE=Auto
TPID=TP2
AMP_BID=A6GAIN=18 dBP1DB=8 dBmIP3=25 dBmIP2= MEASREF= OPSAT= NF=1.2 dBNOISE=AutoRFIFRQ=
LPFBID=F4LOSS=1.1 dBN=3FP=0.04 GHzNOISE=Auto
Fc=2.4GHz
P1=-90 dBm
Fc=2.4GHz
P1=-91.1 dBm
Fc=2.4GHz
P1=-73.1 dBm
Fc=2.4GHz
P1=-55.1 dBm
Fc=2.4GHz
P1=-56.2 dBm
Fc=0.04GHz
P1=-63.7 dBm
Fc=0.04GHz
P1=-64.8 dBm
Fc=0.04GHz
P1=-49.8 dBm
CASCADED GAIN
C_GAIN
-10
0
10
20
30
40
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
DB(C_GA(TP.TP1,TP.TP7,1,0,0))[1]reciever24ghz
p1: Available Gain, Cumulative, dBFreq = 0.04 GHz C_GAIN
-20
0
20
40
60
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
DB(C_GA(TP.TP1,TP.TP7,1,0,0))[1]
reciever24ghz
p1: Available Gain, Cumulative, dBFreq = 0.04 GHz
CASCADED NODE POWER
Power_at_Node
-100
-90
-80
-70
-60
-50
TONE (A5@1) BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
[email protected] dBmAMP_B.A6@2
-56.01 dBm
TONE.A5@1-90 dBm
DB(|P_node(TP.TP1,TP.TP7,0,1,0)|)[1] (dBm)reciever24ghz
p1: Signal Node Power, dBmFreq = 0.04 GHz Power_at_Node
-100
-50
0
50
TONE (A5@1) BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1
TONE.A5@1-90 dBm
DB(|P_node(TP.TP1,TP.TP7,0,1,0)|)[1] (dBm)reciever24ghz
p1: Signal Node Power, dBmFreq = 0.04 GHz
CASCADED P1dB
P1dB
-10
-5
0
5
10
BPFB (F3@2) AMP_B (A1@2) AMP_B (A6@2) BPFB (F1@2) MIXER_B (A3@2) LPFB (F4@2) AMP_B (A2@2)
p1AMP_B.A1@28 dBm
DB(C_P1DB(TP.TP1,TP.TP7,0,1,0))[1] (dBm)reciever24ghz
p1: OP1dB, dBmFreq = 0.04 GHz
COMM CHANNEL 1 RX HAND CALCULATIONS
MDS = -90dBm , Gt=Gr=8dBi , f= 5.8GHz => λ = 0.051 m FSPL = 121.69
Using Friis’ equation
Pr = Pt + Gt + Gr – FSPL
Pt = 15.69 dBm EIRP = Pt(dBm) + Gt (dBi) = 15.69 +8 => EIRP = 23.69 dBm
RECIEVER COMPONENTS – BAND PASS FILTER
Features
Centre Frequency 2.4 GHz
Insertion Loss 2 dB
Pass band Width 92MHz
SKY33106-360LF
RECIEVER COMPONENTS – AMPLIFIER
Low Noise Amplifier
Avago Technologies MGA 665P8
Features
Gain 16 dB
P1 dB 8 dB
Nominal Noise figure 1.45
TRANSMITTER COMPONENTS – MIXER
Mixer
Marki Microwave – M2-0226
Features
Conversion Loss 7.5 dB
LO / RF Frequency range 2 to 26.5 GHz
LO to RF Isolation 25 dB
IF Range 0.001 to 6.0 GHz
TRANSMITTER COMPONENTS – LOW PASS FILTER
Mini Circuits ZX75LP-40
Features
Passband frequency 40 MHz
RF Input power 0.5 W
Insertion loss 1.01 dB
TRANSMITTER COMPONENTS – IF AMPLIFIER
SKY65450-92LF
Features
Gain 15 dB
Typical noise Figure 2.9 dB
Input/ Output Impedance 75 Ω
PROJECT SUMMARY - COMPLIANT MATRIX
Parameters Estimated value
Actual value Compliant
Frequency Range
2 -3 GHz 2 – 3 GHz Yes
Transmitted Power
6.98 dBm 28.53 Yes
Received Power
-65 dBm -54.63 dBm Yes
Free Space Path loss
100 dB 100 dB Yes
Channel 1 – 2.4 GHz
Parameters Estimated value
Actual value Compliant
Frequency Range
5-6GHz 5-6 GHz Yes
Transmitted Power
6.98 dBm 22.56 Yes
Received Power
-70 dBm -54.63 dBm Yes
Free Space Path loss
121 dB 121 dB Yes
Channel 2 – 5.8 GHz
Schedule for Development and Production
Problem Analysis
Building Schematic Hardware
Implementationand
Testing
Ready forProduction
SimulationAnd
Verifying Results
Quality Analysis
Ready to be
Launched
Oct-Nov 2016
Sept 2016
Sept 2016
Dec-Mar 2016-17
April 2017
April-May 2017
June 2017