013405_10_UDS1100Konverter_GB_0307

Page 1 of 38 Report Number: LANTR-060108CE Revision Number: A3

Test Report Pertaining To:

Equipment Under Test 1Model Number(s)

External Device Server UDS1100

MEASUREMENTS PERFORMED IN ACCORDANCE WITH THE FOLLOWING HARMONIZED EUROPEAN STANDARD (S)

Regulatory Standard(s)

EN55022: 1998 + A1: 2000 + A2: 2003 CLASS A – Limits and Methods of Measurement of Radio Disturbance Characteristics of Information Technology Equipment EN61000-3-2: 2000 Class A - ELECTROMAGNETIC COMPATIBILITY (EMC) – Part 3-2: Limits – Limits for harmonic current emissions (equipment input current up to and including 16 A per phase) EN61000-3-3: 1995 +A1: 2001 - ELECTROMAGNETIC COMPATIBILITY (EMC) – Part 3: Limits – Section 3: Limitation of voltage changes, voltage fluctuations and flicker in low-voltage public supply systems, for equipment with rated current < 16 A per phase and not subject to conditional connection EN55024: 1998 +A1: 2001 +A2: 2003 – Information Technology Equipment - Immunity characteristics – Limits and Methods of Measurement

Certificate Number: 1111.01

PREPARED FOR: PREPARED BY: Lantronix Aegis Labs, Inc. 15353 Barranca Parkway 22431 Antonio Parkway B160-417 Irvine, CA 92618 Rancho S. Margarita, CA 92688 Contact(s): Mr. Daryl Miller

Agent(s): Mr. Steve Kuiper Mr. Rick Candelas Mr. Ralph Jimenez Mr. Powen Cheng

Test Report #: LANTR-060108CE

Test Report Revision: A3

APPENDICES REPORT

BODY A B C D E F G TOTAL PAGES

PAGES 38 22 14 18 3 1 4 2 102

The contents of this report shall not be reproduced except in full, without the written approval of Aegis Labs, Inc. The Lantronix logo is used for identification purposes only and is a registered trademark of Lantronix.

1 Additional Model Numbers by similarity listed under Appendix G


TABLE OF CONTENTS

SECTION TITLE PAGE

COVER SHEET……………………………..……………………………………….... 01 TABLE OF CONTENTS.........................................................................................…... 02

1.0 EU REGULATORY COMPLIANCE GUIDELINES……………………………..... 04 1.01 Guidelines for testing to EN55022 Standard…………………………………………..... 04 1.02 Guidelines for testing to EN55024 Standard…………………………………………..... 05 1.03 Guidelines for testing to EN61000-3-2 and EN61000-3-3 Standards…………………... 06

2.0 SUMMARY OF TEST DOCUMENTS………………………..................................... 07

3.0 DEFINITIONS……………………………………..............................................……... 11

4.0 APPROVAL SIGNATURES…………….………..............................................……... 13

5.0 ADMINISTRATIVE DATA AND TEST DESCRIPTION.............................………. 14

6.0 DESCRIPTION OF EUT CONFIGURATION………………........................……… 15 6.1 Arrangement and Location of EUT and Host Equipment……………………………….. 15 6.2 EUT Description and Configuration.......................................................................……... 16 6.2.1 Product Description.............…..........................................................................……….... 16 6.2.2 EUT Configuration..........................…...............................................................………... 17 6.3 List of Internal EUT Sub-Assemblies and Host Equipment…..................................…… 18 6.4 I/O Cabling Diagram and Description.......................................................................…… 19 6.5 List of Accessory / Host Equipment – Power Cables................................................…… 21 6.6 EMI Test Hardware and Software Measurement Equipment..................................…….. 22 6.7 Operating Modes…………………………..………….............................................……. 25 6.7.1 Emissions and Immunity………………………………………………………………… 25 6.8 Harmonic / Flicker Requirements……………………………………………………….. 26

7.0 TEST EQUIPMENT SETTINGS AND FUNCTIONS (RF emissions)……………. 27 7.1 Test Equipment “State of the Instrument for Conducted Emission Measurements……. 27 7.2 Decision Tree for Peak Detector Measurements……………………………………...…. 29 7.3 Test Equipment “State of the Instrument for Radiated Emissions 30 7.4 Conducted Emissions Test Setup………………………………………………………... 31 7.5 Conducted Emissions Site Diagram.............................................................................…………… 32

7.6 Radiated Emissions Test Setup.................................................................................……………… 33

7.7 Radiated Emissions Site Diagram - Side View and Plan View.................................……………… 34


TABLE OF CONTENTS (Continued)

SECTION TITLE PAGE 8.0 SAMPLE CALCULATIONS………………………………………………………………… 36

9.0 IMMUNITY TEST REQUIREMENTS…………………………….……………………….. 37 9.1 General………………………………………………………………………………………….. 37 9.2 Performance Criteria……………………………………………………………………………. 38

APPENDICES A Test Data (12VDC Group West Power supply, MN: TRC-12-0830)

B Test Data (12VDC CUI Power Supply, MN: 3A-161WP12)

C Photographs – Test Setups

D Calibration Correction Table

E Modifications And Recommendations

F Accreditation Certificate

G Additional Models Considered Under Similarities


1.0 EU REGULATORY COMPLIANCE GUIDELINES 1.01 Guidelines for testing to EN55022 standard Aegis Labs, Inc. operates as both a Nevada and California Corporation with no organizational or financial relationship with any company, institution, or private individual. Testing and engineering functions provided by Aegis Labs are furnished by RF technicians and engineers with accredited qualifications and training credentials to carry out their duties. The purpose of this EN55022 standard is to protect the radio frequency spectrum 9kHz. – 400 GHz. from unwanted interference generated from electrical/digital systems that intentionally or unintentionally generated RF energy. The object of this report is to publish verifiable test results of an EUT subjected to the following tests: (1) power line conducted (2) telecommunication conducted and (3) radiated emissions. The test requirements and results are specified for each power or signal port tested. The following emissions standard, normative documents and/or publications were used to conduct all tests performed on the equipment herein referred to as “Equipment Under Test”. Council Directive: 89/336/EEC (May 3, 1989) European Standards Organization: CENELEC Publication in the Official Journal: OJ C 246 of 2005-10-05 Reference of: 2Harmonized Standard:

EN_55022:1998+A1: 2000+A2: 2003 3Normative References: CISPR 11:1990 CISPR 13:2001 CISPR 16-1:1993 CISPR 16-2:1996

2 Date of cessation of presumption of conformity of the superseded standard 01/10/2004. Generally the date of cessation of presumption of conformity will be the date of withdrawal (“dow”), set by the European Standards body, but attention of users of these standards is drawn to the fact that in certain exceptional cases this can be otherwise. Also note that this standard incorporates by dated or undated reference, provisions from other publications. For dated references, subsequent amendments to or revisions of any of these publications apply to this EN55024 European Standard only when incorporated in it by amendment or revision. 3 The normative documents contain provisions, which, through reference in this text, constitute provisions of this International Standard. It is recommended by CISPR that parties to agreements based upon this International Standard are encouraged to investigate the possibility of applying the most recent editions of the IEC normative documents indicated in the above passage.


1.0 EU REGULATORY COMPLIANCE GUIDELINES (Continued) 1.02 Guidelines for testing to EN55024 standard Aegis Labs, Inc. operates as both a Nevada and California Corporation with no organizational or financial relationship with any company, institution, or private individual. Testing and engineering functions provided by Aegis Labs are furnished by RF technicians and engineers with accredited qualifications and training credentials to carry out their duties. The purpose of this report is to present information in order to prove that an adequate level of intrinsic immunity exists on the equipment under test (EUT) and shall operate as intended in its environment. The object of this report is to publish verifiable test results on an EUT defined in this report as it relates to continuous and transient, conducted and radiated disturbances, including electrostatic discharges. The test requirements and results are specified for each port considered. The following harmonized standards, normative documents and/or publications were used to conduct all tests performed on the equipment herein referred to as “Equipment Under Test”. Council Directive: 89/336/EEC (May 3, 1989) European Standards Organization: CENELEC Publication in the Official Journal: OJ C 246 of 2005-10-05 Reference of: 4Harmonized Standard:

EN_55024: 1998 +A1:2001 +A2:2003 5Normative References: IEC_61000-4-2:1995 IEC_61000-4-3:1995 IEC_61000-4-4:1995 IEC_61000-4-5:1995 IEC_61000-4-6:1996 IEC_61000-4-8:1993 IEC_61000-4-11:1994 Note: All test data contained in this report is based upon following the European Normative Standards. In regard to the IEC_61000-4-X series of normative references, Aegis Labs followed the latest equivalent EN_61000-4-X harmonized standards.

4 Date of cessation of presumption of conformity of the superseded standard 01/10/2004. Generally the date of cessation of presumption of conformity will be the date of withdrawal (“dow”), set by the European Standards body, but attention of users of these standards is drawn to the fact that in certain exceptional cases this can be otherwise. Also note that this standard incorporates by dated or undated reference, provisions from other publications. For dated references, subsequent amendments to or revisions of any of these publications apply to this EN55024 European Standard only when incorporated in it by amendment or revision. 5 The normative documents contain provisions, which, through reference in this text, constitute provisions of this International Standard. It is recommended by CISPR that parties to agreements based upon this International Standard are encouraged to investigate the possibility of applying the most recent editions of the IEC normative documents indicated in the above passage.


1.0 EU REGULATORY COMPLIANCE GUIDELINES (Continued) 1.03 Guidelines for testing to EN61000-3-2, AND EN61000-3-3 standard(s) Regarding Harmonics and Flicker emissions of the equipment under test detailed in this report, the purpose of this report is as follows: (1) to publish verifiable test results on an EUT that meets the set limits for harmonic emissions of equipment within its scope, so that, with due allowance for the emissions from other equipment, compliance with the limits ensures that harmonic disturbance levels do not exceed the compatibility levels defined in IEC61000-2-2. And (2) to publish verifiable test results that the EUT does not exceed the limits as it relates to voltage changes experienced by consumers connected at the interface between the public supply low-voltage network and the equipment user’s installation. The following harmonized standards; normative documents and/or publications were used to conduct all tests performed on the equipment herein referred to as “Equipment Under Test”. Council Directive: 89/336/EEC (May 3, 1989) European Standards Organization: CENELEC Publication in the Official Journal: OJ C 246 of 2005-10-05 Reference of 6Harmonized Standard:

EN61000-3-2: 2000 Normative References: EN61000-4-7: 2002 Reference of 7Harmonized Standard:

EN61000-3-3: 1995+A1: 2001 Normative References: IEC61000-4-15: 1997 +A1: 2003 Note: All test data contained in this report is based upon following the European Normative Standards. In regard to the IEC61000-4-XX series of normative references, Aegis Labs followed the latest equivalent EN61000-4-X harmonized standards.

6 Date of cessation of presumption of conformity of the superseded standard 01/04/2004. Generally the date of cessation of presumption of conformity will be the date of withdrawal (“dow”), set by the European Standards body, but attention of users of these standards is drawn to the fact that in certain exceptional cases this can be otherwise. Also note that this standard incorporates by dated or undated reference, provisions from other publications. For dated references, subsequent amendments to or revisions of any of these publications apply to this European Standard only when incorporated in it by amendment or revision. 7 Date of cessation of presumption of conformity of the superseded standard 01/05/04. The normative documents contain provisions, which through reference in this text, constitute provisions of this International Standard. It is recommended by CISPR that parties to agreements based upon this International Standard are encouraged to investigate the possibility of applying the most recent editions of the IEC normative documents indicated in the above passage.


2.0 SUMMARY OF TEST DOCUMENTS

Index Standard Test Limits / Levels Results Power Line Conducted Emissions 0.15 MHz. – 0.5 MHz. (79.0 dBuV (QP)) 0.15 MHz. – 0.5 MHz. (66.0 dBuV (AVG)) 0.5 MHz. – 30.0 MHz. (73.0 dBuV (QP)) 0.5 MHz. – 30.0 MHz. (60.0 dBuV (AVG))

PASSED

Telecommunication Conducted Emissions Voltage Limits 0.15 MHz. – 0.5 MHz. (97.0 – 87.0 dBuV (QP)) 0.15 MHz. – 0.5 MHz. (84.0 – 74.0 dBuV (AVG)) 0.5 MHz. – 30.0 MHz. (87.0 dBuV (QP)) 0.5 MHz. – 30.0 MHz. (74.0 dBuV (AVG))

PASSED 1

EN55022: 1998+ A1: 2000 + A2: 2003

(Class A Device Limits)

Radiated Emissions (Rx Antenna 10m distance) 30.0 MHz. – 230.0 MHz. (40.0 dBuV (QP)) 230.0 MHz. – 1000.0 MHz. (47.0 dBuV (QP))

PASSED

IEC 61000-4-2: 1995 +A1: 1998 +A2: 2000 Max 8 kV Air Discharge Max 4 kV Contact Discharge

PASSED

IEC 61000-4-3: 2002 80 MHz - 1000 MHz, 3 V/m (unmodulated, R.M.S), 80% AM (1 kHz)

PASSED

IEC 61000-4-4: 1995 + A1: 2000 + A2: 2001 1.0 kV Power Lines 0.5 kV I/O Lines

PASSED

IEC 61000-4-5: 1995 + A1: 2000 1.0 kV Line to Line (1.2/50) – AC Mains 2.0 kV Line to Ground (1.2/50) – AC Mains

PASSED

IEC 61000-4-6: 1996 + A1: 2000 0.15 MHz – 80 MHz, 3 V (unmodulated, R.M.S), 80% AM (1 kHz) – AC Mains and Telecommunications Port

PASSED

IEC 61000-4-8: 1993 + A1: 2000 50 Hz, 1 A/m (rms) PASSED

2 EN55024: 1998+ A1: 2001 +A2: 2003 Section 4.0

IEC 61000-4-11: 1994 + A1: 2000 Voltage Dips - <95% reduction for 0.5 periods 30% reduction for 25 periods Voltage Interruptions - <95% reduction for 250 periods

PASSED


2.0 SUMMARY OF TEST DOCUMENTS (Continued)

Index Standard Test Limits / Levels Results For Class A equipment the EUT maximum permissible harmonic current per watt (mA/W) shall not exceed. Odd Harmonics: n=3, Max mA/W=2.30 n=5, Max mA/W=1.14 n=7, Max mA/W=0.77 n=9, Max mA/W=0.40 n=11, Max mA/W=0.33 n=13, Max mA/W=0.21 15</= n </=39, Max mA/W=0.15,15/n

PASSED

3

EN61000-3-2: 2000 (Class A Device Limits)

For Class A equipment the EUT maximum permissible harmonics of the input current shall not exceed: Even Harmonics: n=2, Max A=1.08 n=4, Max A=0.43 n=6, Max A=0.30 8</= n </=40, Max A=0.23, 8/n

PASSED

4 EN61000-3-3: 1995 +A1: 2001

The following limits apply: The value of Pst shall not be greater than 1.0 The value of Plt shall not be greater than 0.65 The value of d(t) during a voltage change shall not exceed 3.3% for more than 500ms. The relative steady state voltage change, dc, shall not exceed 3.3% The maximum relative voltage change dmax shall not exceed 4%, 6% or 7% depending on equipment type

PASSED


2.0 SUMMARY OF TEST DOCUMENTS (Continued) Conducted Emissions 6 Highest Measurements (Group West Power Supply)

6 Highest AC Conducted Emissions Data Frequency Measured

(MHz)

Meter Reading (dBuV)

Detector Function

(PK/QP/AV)

Average Limit

(dBuV)

Average Delta (dB)

Quasi-Peak Limit

(dBuV)

Quasi-Peak

Delta (dB) Line Voltage /

Freq.

0.8200 59.97 PK 60.00 -0.03 73.00 -13.03 L2 230 / 50 1.0900 59.81 PK 60.00 -0.19 73.00 -13.19 L2 230 / 50 0.8200 59.69 PK 60.00 -0.31 73.00 -13.31 L1 230 / 50 1.1100 59.64 PK 60.00 -0.36 73.00 -13.36 L1 230 / 50 0.5500 59.55 PK 60.00 -0.45 73.00 -13.45 L2 230 / 50 0.5500 59.19 PK 60.00 -0.81 73.00 -13.81 L1 230 / 50

Radiated Emissions 6 Highest Measurements (Group West Power Supply)

6 Highest Radiated Emissions Data

Freq. (MHz)


Antenna Height (cm)

Azimuth (degrees)

Quasi pk or AVG (dBuV)

Cable Factor (dB)

Antenna Factor (dB)

Corrected Reading

(dBuV/m) Limits

(dBuV/m) Diff (dB) +=FAIL Polarity

375.00 18.64 375 270 3.10 15.10 36.84 47.00 -10.16 H 229.99 8.35 100 225 2.49 17.52 28.36 40.00 -11.64 V 750.00 8.27 400 315 4.43 22.00 34.70 47.00 -12.30 H 336.01 15.99 375 270 2.94 15.36 34.29 47.00 -12.71 H 110.67 13.42 100 315 1.79 12.08 27.29 40.00 -12.71 V 750.00 6.95 100 135 4.43 22.00 33.38 47.00 -13.62 V


2.0 Summary of Regulatory Limits (Continued) Conducted Emissions 6 Highest Measurements (CUI Power Supply)

6 Highest AC Conducted Emissions Data Frequency Measured

(MHz)


Detector Function

(PK/QP/AV)

Average Limit

(dBuV)

Average Delta (dB)

Quasi-Peak Limit

(dBuV)

Quasi-Peak

Delta (dB) Line Voltage /

Freq.

0.4200 41.74 PK 66.00 -24.26 79.00 -37.26 L2 120 / 60 22.8200 35.14 PK 60.00 -24.86 73.00 -37.86 L2 100 / 60 18.0800 34.95 PK 60.00 -25.05 73.00 -38.05 L1 120 / 60 22.8200 34.82 PK 60.00 -25.18 73.00 -38.18 L1 230 / 50 0.4000 40.79 PK 66.00 -25.21 79.00 -38.21 L2 100 / 60

22.8200 34.39 PK 60.00 -25.61 73.00 -38.61 L2 230 / 50

Radiated Emissions 6 Highest Measurements (CUI Power Supply)

6 Highest Radiated Emissions Data

Freq. (MHz)


Antenna Height (cm)

Azimuth (degrees)

Quasi pk or AVG (dBuV)

Cable Factor (dB)

Antenna Factor (dB)

Corrected Reading

(dBuV/m) Limits

(dBuV/m) Diff (dB) +=FAIL Polarity

375.00 18.76 300 270 3.10 15.10 36.96 47.00 -10.04 H 336.01 15.99 300 0 2.94 15.36 34.29 47.00 -12.71 H 110.77 14.07 400 0 1.79 10.65 26.51 40.00 -13.49 H 750.00 5.30 100 180 4.43 22.00 31.73 47.00 -15.27 V 375.00 12.81 100 0 3.10 15.30 31.21 47.00 -15.79 V 288.00 8.14 300 90 2.70 20.17 31.01 47.00 -15.99 H


3.0 8DEFINITIONS Digital device: An unintentional radiator (device or system) that uses digital techniques and generates and uses timing signals or pulses at a rate in excess of 9000 pulses (cycles) per second; inclusive of telephone equipment that uses digital techniques or any device or system that generates and uses RF energy for the purpose of performing data processing functions, such as electronic computations, operations, transformations, recording, filing, sorting, storage, retrieval, or transfer (FCC 47CFG Part 15). Electromagnetic disturbance: Any electromagnetic phenomena that may degrade the performance of a device, piece of equipment, or system, or adversely affect living or inert matter. Equipment under test: A device or system being evaluated for compliance that is representative of a product to be marketed. Host: A device to which other devices (peripherals) are connected and that generally controls those devices. Incidental radiator: A device that produces RF energy during the course of its operation, although the device is not intentionally designed to generate or emit RF energy. Examples of incidental radiators are dc motors, mechanical light switches and so on. Normalized site attenuation: Site attenuation divided by the antenna factors of the radiating and receiving antennas (all in linear units) Reference ground plane: A conducting flat surface or plate that is used as a common reference point for circuit returns and electric or signal potentials and that reflects electromagnetic waves. Tabletop device: A device designed to be placed and normally operated on the raised surface of a table, e.g., most personal computers. Unintentional radiator: A device that generates RF energy for use within the device, or that sends RF signals by conduction to associated equipment via connecting wiring, but which is not intended to emit RF energy by radiation or induction. (FCC 47CFR Part 15). Circuit power factor: the circuit power factor is the ratio of the measured active input power to the product of the supply voltage (r.m.s.) and the supply current (r.m.s.) Active power: the mean value, taken over one period, of the instantaneous power. Note: the active input power is the active power measured at the input supply terminals of the equipment under test. Total harmonic current: the total r.m.s. value of the harmonic current components of orders 2 to 40. Partial odd harmonic current: the total r.m.s. value of the odd harmonic current components of orders 21 to 39. Voltage fluctuation: series of changes of r.m.s. voltage evaluated as a single value for each successive half-period between zero crossing of the source voltage. Flicker: impression of unsteadiness of visual sensation induced by a light stimulus whose luminance or spectral distribution fluctuates with time. r.m.s. Voltage shape: the time function of the r.m.s. voltage, evaluated as a single value for each successive half period between zero-crossings or the source voltage

8 Refer to IEC 60050(161):1990 for additional definitions and vocabulary concerning Electro-magnetic Compatibility


3.0

9DEFINITIONS (Continued) degradation: The unwanted change in operational performance of an EUT due to electromagnetic disturbances. This does not necessarily mean malfunction or catastrophic failure. port: particular interface of the specified equipment with the external electromagnetic environment. May include one or more of the following inputs: AC/DC power, earth port, signal port and/or telecommunication port. Voltage change characteristic: the time function of the r.m.s. voltage change evaluated as a single value for each successive half period between zero-crossings of the source voltage between time intervals in which the voltage is in a steady-state condition for at least 1 s. Flickermeter: an instrument designed to measure any quantity representative of flicker. Note: measurements are normally Pst and Plt. equipment under test: a representative ITE or functionally interactive group of ITE (that is a system), which includes one or more host units and is used for evaluation purposes normative: Annexes designated “normative” are part of the body of the standard. In this standard, Annex ZA is normative. degradation: the unwanted change in operational performance of an EUT due to electromagnetic disturbances this does not necessarily mean malfunction or catastrophic failure. multifunction equipment: information technology equipment in which two or more functions subject to this standard and/or to other standards are provided in the same unit.

9 Refer to IEC 60050(161):1990 for additional definitions and vocabulary concerning Electro-magnetic Compatibility


4.0 APPROVAL SIGNATURES TEST & REPORT SIGNATORIES:

Test Performed By: _____ __02/02/06 Ralph Jimenez Date: Test Technician Aegis Labs, Inc.

Report Approved By: 02/10/06 Rick Candelas Date Lab Manager Aegis Labs, Inc.

Test and Report Completed By: _____ __02/06/06 Powen Cheng Date: Test Engineer Aegis Labs, Inc.

Report Approved By: _02/10/06 Steve J. Kuiper Date Quality Assurance Manager Aegis Labs, Inc.


5.0 ADMINISTRATIVE DATA AND TEST DESCRIPTION

DEVICE TESTED: ITE Type: External Device Server Model Number(s): UDS1100 Serial Number: N/A

DATE EUT RECEIVED: January 22nd, 2006 TEST DATE(S): January 23rd, 24th, 26th, 27th, 30th, 31st, February 1st, 2006

ORIGIN OF TEST SAMPLE(S): Production

EQUIPMENT CLASS: EUT tested as CLASS A device

RESPONSIBLE PARTY: Lantronix 15353 Barranca Parkway Irvine, CA 92618

CLIENT CONTACT: Mr. Daryl Miller

MANUFACTURER: Lantronix

TEST LOCATION:

Aegis Labs, Inc. Aegis Labs, Inc. 23091 Antonio Pkwy #310 32231 Trabuco Creek Road RSM, CA 92688 Trabuco Canyon, CA 92678 Chamber #1 Open Area Test Site #1

ACCREDITATION CERTIFICATE(s): A2LA Certificate Number: 1111.01, Valid through February 28, 2006

PURPOSE OF TEST: To demonstrate compliance with the standards as described in Sections 1.0 & 2.0 of this report.

UNCERTAINTY BUDGET:

Proficiency Testing and Uncertainty Calculations for all tests indicated in this report have been conducted in accordance with ISO 17025:1999 requirements Section 5.5.4, 5.5.1 and 5.9. Uncertainty Budgets and Proficiency Test results available upon request.

STATEMENT OF CALIBRATION:

All accredited equipment calibrations were performed by Liberty Labs, Inc. and World Cal. with typical calibration uncertainty estimates derived from ISO Guide to the determination of uncertainties with a Coverage Factor of k=2 for 95% level of confidence.


EUTSerial Port

To 12VDC Power Adapter

Keyboard

MonitorComputer

Mouse

Ethernet C

able

Seria

l Cab

le

Ethernet Port

6.0 DESCRIPTION OF EUT CONFIGURATION 6.1 Arrangement and Location of EUT and Host Equipment


6.2 EUT Description and Configuration

Equipment Under Test (EUT): External Device Server

Test Routine Software Programs used during testing of EUT and Peripherals: Lantronix Test Software

Number of External Test Ports Exercised: 1 Serial (Exercised) 1 Ethernet (Exercised)

Power Supply Voltage applied to EUT during qualification measurements:

Conducted Emissions: 230VAC / 50 Hz Radiated Emissions: 230VAC / 50 Hz Harmonic & Flicker: 230 VAC / 50Hz Immunity: 230VAC / 50 Hz

Clocks and/or Crystal Oscillator(s): 25 MHz

6.2.1 Product Description

The UDS1100 external device server can remotely monitor, manage and share connected devices over a network or the Internet. It lets you replace limited distance, point-to-point serial connections. Using a method called serial tunneling; the EUT encapsulates serial data into packets and transports it over 10Base-T/100Base-TX Ethernet. The EUT can also be set up locally through its serial port, or remotely over a network using Telnet or a web browser.


6.2.2 EUT Configuration The EUT (External Device Server, Model Number: UDS1100) and host peripherals were operated according to Section 6.1 of this report. For all tests performed, the EUT had devices connected to all its external ports. In addition, all appropriate test ports were exercised to simulate, as closely as possible, the end user environment. The EUT was tested in three different configurations: Configuration 1: The EUT was configured to receive power from a 12VDC Group West Power Adapter. The EUT’s DB-25 type serial port and Ethernet port were connected to the host computer’s DB-9 type serial and Ethernet ports through serial cable with a DB-25 to DB-9 converter and Ethernet cables. The Dell computer was then connected to a Dell monitor, Dell keyboard, and Microsoft mouse via its video, keyboard, and mouse ports respectively. In this configuration the EUT was sending and receiving data packet from the Dell computer via its Ethernet and serial ports. Full testing was performed for this configuration and can be found in Appendix A. Configuration 2: In this configuration the EUT was receiving power from a 12VDC CUI Power Adapter. All the other connections and operations were the same as configuration 1. Partial testing was performed for this configuration and can be found in Appendix B.


6.3 List of EUT, Sub-Assemblies, and Host Equipment

Equipment Under Test Manufacturer Equipment Name Model or Part

Number Serial Number

Lantronix, Inc. External Device Server UDS1100 N/A Sub-assemblies Group West Power Adapter TRC-12-0830 N/A CUI, Inc. Power Adapter 3A-161WP12 N/A

Host Equipment Manufacturer Equipment Name Model or Part

Number Serial Number

Computer System DELL Computer MMS 4ZFAW DELL Monitor M780 5322DE78XR89 DELL Keyboard SK-1000REW 12710-8AC-1500

Microsoft Mouse Intellimouse 1.2A PS/2 Compatible 4005705-9


6.4 I/O Cabling Diagram and Description

EUTSerial Port

To 12VDC Power Adapter

Keyboard

MonitorComputer

Mouse

Ethernet C

able

Seria

l Cab

le

Ethernet Port

1

2

3

4

5


6.4 I/O Cabling Diagram and Description (Continued) The following cables were attached to the EUT during all testing. Cable Grouping 1:

These are 3m braid and foil shielded round cables connecting the EUT’s serial ports to the host computer. The EUT’s metallic DB-25 type serial port was connected to a DB-25 to DB-9 converter then connected to the host DELL computer by a DB-9 serial cable at both end.

Cable 2:

This is a 10m unshielded Ethernet cable connecting the EUT’s Ethernet port to the host computer. It has a plastic RJ-45 type connector at both ends.

Cable 3:

These are 5-foot braid and foil round shielded cable connecting the Computers to the Monitors. The cables have metallic DB-15 connector at the computer end and are hardwired into the monitor. The shield of the cables is grounded to the chassis via the connector shell.

Cable 4:

These are 1-meter foil shielded round cables connecting the Computers to the Keyboards. The cables have metallic 8-pin Mini-Din connector at the computer end and are hardwired into the keyboard. The shield of the cable is grounded to the chassis via the connector shell.

Cable 5:

These are 1-meter foil shielded round cables connecting the Computers to the Mice. The cables have metallic 8-pin Mini-Din connector at the computer end and are hardwired into the mice. The shield of the cable is grounded to the chassis via the connector shell.


6.5 List of Accessory / Host Equipment – Power Cables

MAXIMUM POWER CABLE CONFIGURATION OF EUT AND ACCESSORY

/ HOST EQUIPMENT

Power Cable FROM Equipment

to “PO or PS”

CABLE DESCRIPTION

LENGTH (m)

SHIELDED? FERRITE?

LOCATION? PO/PS: Abbreviation for Power Outlet or Power Strip (PO/PS)

EUT Generic, bundled to 1 meter for conducted testing only 1.5 None

Computer Generic 1.5 None Monitor Generic 1.5 None


6.6 EMC Test Hardware and Software Measurement Equipment

TEST EQUIPMENT LIST - Emissions

Equipment

Name Manufacturer Asset

Number Serial

Number Calibration Due Date

Maintenance Calibration

Cycle

EMI Receiver - RF Section Hewlett Packard A322 3704A00399 09/02/06 1 Year

EMI Receiver - RF Filter Section Hewlett Packard A349 3737A00407 09/02/06 1 Year

10dB Attenuator Radiall A336 Lot 9624 07/09/06 1 Year

LISN (EUT) Solar Electronics A001 961025 04/01/06 1 Year

LISN (Access) Solar Electronics A002 961024 07/05/06 1 Year

ISN Fischer Custom Communications None 20220 07/18/06 1 Year

Antenna - Biconical EMCO A206 3383 03/18/06 1 Year

Antenna - Log Periodic EMCO None 00047943 05/23/06 1 Year

Spectrum Analyzer Agilent A341 4046A00387 08/15/06 1 Year Antenna - Horn ETS None 57423 12/21/06 1 Year

Amplifier Miteq None 815980 07/21/06 1 Year Temperature / Humidity

Monitor Dickson A012 7255185 N/A N/A


6.6 EMC Test Hardware and Software Measurement Equipment (Continued)

TEST EQUIPMENT LIST- Immunity

Equipment

Name Manufacturer Asset

Number Serial

Number Calibration Due Date

Maintenance Calibration

Cycle

Power Analyzer & Flicker Meter Keytek A333 04800202 01/11/07 1 Year

Precision Impedance Source Keytek A334 A0202344 01/11/07 1 Year

AC Power Source Pacific Power A294 143132 01/11/07 1 Year

Immunity Test Generator Keytek A296 0102381 06/28/06 1 Year External 80% PQF Tap KeyTek A359 0505227 06/28/06 1 Year

Capacitive Clamp Keytek A026 9706338 NCR N/A

Electrostatic Discharge Simulator Schaffner A354 464 09/07/06 1 Year

Magnetic Field Immunity Loop Fischer Custom Communications, Inc. A198 9853 NCR N/A

RF Signal Generator Giga-Tronics A013 9809906 05/09/06 1 Year

Antenna – Bilog Schaffner A084 2568 NCR N/A RF Amplifier

1MHz-1000MHz Amplifier Research A078 25374 NCR N/A

RF Amplifier 10 kHz-220MHz Amplifier Research A077 25427 NCR N/A

Bulk Current Injection Probe Fischer Custom Communications, Inc. A124 124 05/05/07 1 Year

Coupling / Decoupling Network

Fischer Custom Communications, Inc. A258 01052 03/16/07 1 Year

EM Injection Clamp Fischer Custom Communications, Inc. A361 486 12/05/06 1 Year

Power Meter Agilent A338 GB40207646 07/07/06 1 Year

Power Sensor Agilent A339 US39211209 07/06/06 1 Year Directional Coupler Amplifier Research A079 25390 NCR N/A Directional Coupler Amplifier Research A080 25315 NCR N/A

Isotropic Probe Amplifier Research A357 310921 04/25/06 1 Year

Immunity Software Schaffner A351 Not Available NCR N/A


6.7 Operating Modes 6.7.1 Emissions and Immunity The EUT was configured in a mode consistent with its operation by the end-user. The EUT (External Device Server, Model Number: UDS1100) was exercised continuously by a test program provided by Lantronix, which exercised all the appropriate ports. The EUT operated continuously during all facets of testing. All measurements and or levels were recorded using the following software and peripherals as follows:

I/O PORT(S) / ACCESSORY EQUIPMENT EXERCISED DURING TESTING

Lantronix Software Peripherals or Components 10Passive 11Active

EUT Serial Port √ EUT Ethernet Port √ Computer √ Monitor √ Keyboard √ Mouse √

10 For the purposes of this report, ACTIVE refers to any device or component that will receive, transmit or pass through data without the need for the user to manually activate the device. 11 For the purpose of this report, PASSIVE refers to any device tested that is idle of any data transmission and functions primarily as “dummy” termination.


6.8 HARMONIC / FLICKER REQUIREMENTS The test requirements for the EUT as described within this report were conducted in a well-defined and reproducible manner. A description of the test, the AC Source, Impedance Source and Flickermeter design parameters, test methods and test set-up are stipulated in the IEC / EN Standards. As such, all testing was performed to those standards listed in Section 2.0 of this report.

• Harmonic and Flicker testing shall be performed on the EUT’s power supply according to the appropriate IEC/EN standard.


7.0 TEST EQUIPMENT SETTINGS AND FUNCTIONS (RF Emissions) 7.1 Test Equipment “State of the Instrument for Conducted Emission Measurements” Conducted Test: SITE #1 & #2: The Agilent EMI 8546A Receiver Series is a high-performance test receiver especially designed for making commercial EMI (Electro-Magnetic Interference) measurements. It fully conforms to the receiver standards described in CISPR (Comite’ International Special Des Perturbations Radioelectriques) Publication 16, C.I.S.P.R. Specification for Radio Interference Measuring Apparatus and Measurement Methods. This type of receiver is used for making measurements according to various governmental standards, such as FCC, EN and VCCI regulations. The HP 8546A tunes from 9kHz. To 6.5 GHz. making it suitable for testing a wide variety of products including but not limited to intentional and unintentional radiators.

HP 8546A Standard Test Configurations

MENU LABEL Start/Stop Frequency

IF Bandwidth

Averaging Bandwidth

Reference Level

9 kHz-150 kHz 200 Hz. CISPR 300 Hz 70 dBuV 150 kHz – 30 MHz 9 kHz CISPR 30 kHz 75 dBuV 30 MHz – 300 MHz 120 kHz CISPR 300 kHz 80 dBuV 200 MHz – 1 GHz. 120 kHz CISPR 300 kHz 80 dBuV


7.1 Test Equipment “State of the Instrument for Conducted Emission Measurements” (Continued) User-defined test parameters based upon the previous table were loaded into the instrument for pre-qualification and qualification testing. The peak, quasi-peak and/or average detector were used according to Section 7.2. For testing performed between 150 kHz and 30 MHz. the EMI Receiver performed a swept frequency measurement with the following EMI Receiver settings:

Function Setting REF OFFST 10.0 dB REF 85.0 dBuV ATTEN 10 dB IF BW 9.0 kHz AVG BW 30 kHz SWP 2.49 SEC SPAN 30 MHz ACTIVE DETECTOR PK

In reference to the LISN used during testing, the 1uF capacitor in combination with the 50uH inductor is the filter that isolated the mains from the EUT. Consequently, the 50uH inductor isolated the noise generated by the EUT from the mains. The 0.1uV couples the noise generated by the EUT to the EMI Receiver. At frequencies above 150 kHz, the EUT signals are presented with a 50-ohm impedance. The purpose of using the transient limiter is to protect the input of the EMI Receiver from large transients when connected to the LISN. The transient limiter incorporates a limiter, high pass filter, and an attenuator. Lastly, a low loss 50-ohm cable was connected between the transient limiter and LISN. After the swept frequency scan was performed for both Line 1 and Line 2 the six highest readings against the Limit were recorded in the data sheet along with a snapshot image of the sweep scan. Upon completion of the swept frequency scan, the six highest peaks against the reference level were re-measured in manual mode and recorded in the Microsoft Windows Excel “.xls.” spreadsheet. The graphical scans in Appendix A only reflect peak readings while the tabulated data sheets reflect either peak, average, and/or quasi-peak measurements. Upon completion of the swept frequency scan, the six highest peaks against the reference level were re-measured in manual mode and recorded in the Microsoft Windows Excel “xls.” spreadsheet. The graphical scans in the appropriate Appendix only reflect peak readings while the tabulated data sheets reflect either peak, average, and/or quasi-peak measurements.


7.2 Decision Tree for Peak Detector Measurements

Yes No

No Yes

Yes No

Yes No

No Yes

PK detector

PK < AVG limit ?

AVG < AVG limit ?

QP detector

QP < QP limit ?

PK < QP limit ?

QP < AVG limit ?

AVG detector

PASS FAIL PK – Peak QP – Quasi-Peak AVG – Average


7.3 Test Equipment “State of the Instrument for Radiated Emission Measurements” Radiated Test: (30 MHz. – 1000 MHz.) SITE #1 & SITE #2: The Agilent EMI 8546A Receiver and 8568B/85460A/85685A Series Receiver(s) were independently certified to meet the CISPR-16 requirements by the German BZT (Bundesamt fur Zulassungen der Telkommunikution, the German Appeals Office for Telecommunications). Additionally the receiver characteristics were verified/calibrated by an independent third party ISO 17025 calibration laboratory. Because of the added complexity of the open-air ambient environment, which can interfere with the device under test, the receiver in conjunction with a low ambient environment facility and trained personnel were an excellent combination to ensure accurate and repeatable measurements. Specifically, to make an accurate measurement when necessary, the receiver was placed in linear mode and caution was exercised to ensure that the receiver was not in saturation at the front-end mixer because of potential large narrowband or broadband emissions. A useful overload detection scheme was employed to alert the measurement technician of any overload conditions in all frequency ranges and in all modes of receiver operation. The advanced overload detection and measurement scheme were “autoranged” or automatically put in enough attenuation prior to the first mixer to measure the signal in non-overload conditions. However, the ambient noise floor level of the Aegis Labs Open Area Test Sites (OATS) is substantially lower than most thereby requiring little attention to be paid to the overload condition. The receiving (Rx) antenna(s) was placed 10m from the nearest side of the EUT facing the Rx antenna. The EUT (if floor-standing) was placed directly on the flush-mounted 360 degree rotating turntable. The EUT (if table-top) was placed directly on an 80cm high non-metallic table, and the table was placed on the rotating turntable. During the initial EMI scan, all the suspect frequencies, i.e.; harmonics, broadband signals were checked with the Rx broadband antennas in both vertical and horizontal polarities. The biconical Rx and log periodic Rx antennas were used from 30 MHz. – 299.99 MHz. and from 300 MHz. – 999.99 MHz. Upon completion of all harmonic and broadband measurements, the balance of any remaining frequencies was checked between 30 MHz. – 999.99 MHz. Any signals appearing within 20 dB of the classification limit A or B were measured. Each signal was maximized by first rotating the turntable at least 360 degrees and recording the azimuth in the data sheet. Lastly, the Rx antenna was raised and/or lowered to maximize the signal elevation. If the measured signal was obtained using the peak detector and that signal appeared within 3 dB of the regulatory limit line, then the same signal was re-measured using the quasi-peak detector on the EMI receiver. Both meter readings if necessary were recorded on the data sheet. In the case of measuring around ambient signals several methods were employed to ensure accuracy including but not limited to using the “Signal Substitution Method” with the Rx antenna placed at 3m from the EUT, the “Marker Delta Method” or a “Logarithmic Calculation Method” for either broadband or narrowband signals.


7.4 Conducted Emissions Test Setup The Equipment Under Test (EUT) shall be configured as a system with peripherals connected, so that at least one interface port of each type is connected to one external peripheral when tested for conducted emissions according to ANSI C63.4-2003. The EUT shall have a minimum of at least one test configuration identified on the Engineering Data Sheets of said report. These are either in a tabletop setup as shown on following page or in a freestanding configuration as required for floor-standing systems. The test data shall be collected using the appropriate EMI Receiver System as described in Section 7.1. The Conducted Test for tabletop configurations shall be performed on 2 each galvanized sheets measuring 10mm thickness X 8.0 FT.X 10.0 FT. situated in a vertical and horizontal position diagramed in Section 7.5 of this report. The horizontal-conducting plane extends at least 1.5 meters beyond the all four sides of the EUT. For tabletop equipment, a non-metallic table rests on top of the ground plane extending 40 cm from and parallel to the vertical plane. The EUT shall be powered through an appropriate Line Impedance Stabilization Network (LISN), bonded to the ground plane as described in ANSI C63.4-2003. The LISN power shall be isolated from other filtered power via an additional filter to ensure that RFI from the auxiliary instrumentation or support equipment does not influence the readings obtained. The power input cables to the LISN and the EMI equipment shall be arranged so that they will not influence the measurement results. Any excess power cord shall be folded back and forth to form a 30-cm non-inductive bundle. When applicable the telecom port of the EUT shall be connected to the accessory equipment via a two balanced telecom pairs ISN, which is bonded to the horizontal ground plane as described in CISPR22. The Automated Aegis/LabView Software (ALVS) measurement system was located outside the sphere during the test.


7.5 Conducted Emissions Site Diagram


7.6 Radiated Emissions Test Setup The Open Area Test Sites (OATS) shall be used for radiated emission testing. These test sites are designed according to ANSI C63.4-2003 and ANSI C63.7-1992 guidelines. The OATS facilities are periodically tested using a calibrated field site source with the resultant test data compiled into a statistical data based used to check the integrity of the test site measurements. The Measurement procedure shall be in accordance with ANSI C63.4-2003 and ANSI C63.7-1992 requirements. The EUT shall be placed in the prescribed spot of the OATS, (either atop the turntable, or atop the ground plane) where applicable. The following page refers to the setup depicting a typical test configuration; exact EUT set-up is detailed in the Engineering Data Sheets. The turntable shall rotate a minimum of 360 deg. to obtain the highest emissions. During rotation the antenna (s), supported by the mast array shall also be raised and lowered at the test personnel’s discretion to identify the maximum energy lobe. See diagram on following page for graphical representation. For short and permanently connected conductors who cannot be extended by the user with commercially available cables, the EUT shall be tested only with the manufacturer’s furnished cables.


7.7 Radiated Emissions Site Diagram - Side View and Plan View


7.7 Radiated Emissions Site Diagram – Side View and Plan View (Continued)

Note: Aegis Labs Open Area Test Sites exceed the 2 R Frensel Ellipse measurement zone as defined under ANSI C63.4: 2003 to minimize possible reflection issues from surrounding structures.


8.0 SAMPLE CALCULATIONS If a preamplifier is used during the Radiated Emissions Testing, it is required that the amplifier gain be subtracted from the Spectrum Analyzer (Meter) Reading. In addition, a correction factor for the antenna, cable and a distance factor, if any, must be applied to the Meter Reading before a true field strength reading can be obtained. In the Automatic Mode of A.R.M.S. measurements, these considerations are automatically presented as a part of the printout. In the case of manual measurements and for greater efficiency and convenience, usage of the calibration correction factors in the Appendices is necessary to calculate the Corrected Meter Reading. These correlation factors for each meter reading, shall be modified to reflect these correlation factors at each frequency value so that the meter readings can be compared directly to the modified specification limit. This modified specification limit is referred to as the “Corrected Meter Reading Limit” (CML). The equation shall be derived in the following manner: Corrected Meter Reading = Meter Reading + F +C –G - D Where, F = Antenna Factor C = Cable Factor G = Amplifier Gain D = Distance Factor Therefore, the equation for determining the Corrected Meter Reading Limit (CML) is: CML = Specification Limit - F - C + G + D For the manual mode of measurement, a table of corrected meter reading limits shall be used to permit immediate comparison of the meter reading to determine if the measured emission amplitude exceeded the specification limit at that specific frequency. There shall be two calculation sheets done, one for three meter and one for ten-meter measurement distances, where applicable. The correction factors for the antenna and the amplifier gain are attached in the Appendices.


9.0 IMMUNITY TEST REQUIREMENTS 9.1 GENERAL

The immunity test requirements for the equipment under test as described within this report were conducted in a well-defined and reproducible manner. A description of the test, the test generator design parameters, test methods and test set-up are stipulated in the IEC / EN standards. As such, all testing was performed in accordance with the standards listed in Section 1.0 of this report.

• Static electricity discharges shall be applied to those points and surfaces of the EUT, which are

expected to be touched during usual operation, including user access, as specified by the manufacturer.

• Electrical fast transient tests shall be conducted on the power supply and signal ports. When necessary, for equipment containing identical ports, only one shall be tested. Interface ports, which are intended by the manufacturer to be connected to data cables not longer than 3m shall not be tested.

• Continuous radio frequency disturbance testing shall be performed and the manufacturer shall configure the EUT in such a manner that the dwell time set at each frequency not to be less than the time necessary for the EUT to be exercised and to be able to respond. Additionally, the dwell time shall not exceed 5 s at each of the frequencies during the scan.

• Continuous conducted disturbance shall be performed on the EUT’s power supply and signal cables in accordance with appropriate IEC/EN standard.

• Power frequency magnetic field testing shall be conducted with the EUT placed in the center of the H-coil system (immersion method). The cables supplied by the manufacturer shall be used.

• Surge testing shall be performed on the EUT’s power supply according to the appropriate IEC/EN standard.

• Voltage dips and interrupts shall be applied to the EUT, and there shall be no deviation from the appropriate IEC/EN standard used for this test.


9.2 PERFORMANCE CRITERIA

TEST

PERFORMANCE CRITERIA

Electrostatic Discharge

B

Radio-Frequency Electromagnetic Field

A

Electrical Fast Transients

B

High Energy Transients

B

Radio Frequency Conducted Susceptibility

A

Power Frequency Magnetic Field

A

Voltage Dips B - >95% reduction for 0.5 periods & C – 30% reduction for 25 periods

Voltage Interrupts

C - > 95% reduction for 250 periods


9.2 Performance Criteria (Continued) The manufacturer has the obligation to express the performance criteria in terms, which relate to the performance of his specific product when used as intended. The following performance criteria are applicable, and shall only be evaluated when the functions referred to are implemented. Performance Criterion A

The equipment shall continue to operate as intended without operator intervention. No degradation of performance or loss of function is allowed below a performance level specified by the manufacturer when the equipment is used as intended. The performance level may be replaced by a permissible loss of performance. If the minimum performance level or the permissible performance loss is not specified by the manufacturer, then either of these may be derived from the product description and documentation, and by what the user may reasonably expect from the equipment if used as intended.

Performance Criterion B

After the test, the equipment shall continue to operate as intended without operator intervention. No degradation of performance or loss of function is allowed after the application of the phenomena below a performance level specified by the manufacturer, when the equipment is used as intended. The performance level may be replaced by a permissible loss of performance.

Performance Criterion C Loss of function is allowed, provided the function is self-recoverable, or can be restored by the operation of the controls by the user in accordance with the manufacturer’s instructions. Functions, and/or information stored in non-volatile memory, or protected by a battery backup, shall not be lost.

Page 1 of 22 (Appendix A) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX A

TEST DATA

EUT Configuration #1 Model Number UDS-1100 Serial Number N/A Power Supply Manufacturer: Group West

Model Number: TRC-12-0830 Serial Number: N/A


CONDUCTED EMISSIONS TEST RESULTS

CLIENT: Lantronix DATE: 01/24/06

EUT: External Device Server PROJECT NUMBER: LANTR-060108

MODEL NUMBER: UDS1100 TEST ENGINEER: RJ

SERIAL NUMBER: N/A SITE #: 1

TEMPERATURE: 21 deg. C HUMIDITY: 13% CONFIGURATION: 230 VAC / 50Hz

TIME: 10:40 AM

Description: Conducted Power RF Emissions (150 kHz – 30 MHz) Results: PASSED LINE 1 and LINE 2 Class A Limits


Conducted Emissions Test Results (Continued)

230VAC/50Hz (LANTR-060108-08) CISPR22 CLASS A CONDUCTED EMISSIONS – LINE 1

Freq. (MHz)


Detector (PK/QP/AV)

Average Limit (dBuV)

Average Delta(dB)

Quasi-Peak Limit (dBuV)

Quasi-Peak Delta(dB)

0.2700 60.70 PK 66.00 -5.30 79.00 -18.30 0.5500 59.19 PK 60.00 -0.81 73.00 -13.81 0.5500 58.54 AV 60.00 -1.46 73.00 -14.46 0.8200 59.69 PK 60.00 -0.31 73.00 -13.31 0.8200 50.89 AV 60.00 -9.11 73.00 -22.11 1.1100 59.64 PK 60.00 -0.36 73.00 -13.36 1.1100 56.18 AV 60.00 -3.82 73.00 -16.82 1.3800 56.46 PK 60.00 -3.54 73.00 -16.54 2.4600 52.03 PK 60.00 -7.97 73.00 -20.97



230VAC/50Hz (LANTR-060108-08) CISPR 22 CLASS A CONDUCTED EMISSIONS - LINE 2

Freq. (MHz)


Detector (PK/QP/AV)


Average Delta(dB)



0.2700 60.80 PK 66.00 -5.20 79.00 -18.20 0.5500 59.55 PK 60.00 -0.45 73.00 -13.45 0.5500 58.92 AVG 60.00 -1.08 73.00 -14.08 0.8200 59.97 PK 60.00 -0.03 73.00 -13.03 0.8200 50.79 AVG 60.00 -9.21 73.00 -22.21 1.0900 59.81 PK 60.00 -0.19 73.00 -13.19 1.0900 37.82 AVG 60.00 -22.18 73.00 -35.18 1.3800 56.27 PK 60.00 -3.73 73.00 -16.73 2.7500 52.92 PK 60.00 -7.08 73.00 -20.08



CLIENT: Lantronix Inc. DATE: 01/26/06 EUT: External Device Server PROJECT NUMBER: LANTR-060108 MODEL NUMBER: UDS1100 TEST ENGINEER: JC/PC SERIAL NUMBER: N/A SITE #: 2

TEMPERATURE: 17 deg C HUMIDITY: 41% RH CONFIGURATION: 230 VAC / 50Hz

TIME: 2:30 PM

Description: Conducted Telecommunication Port “Ethernet" RF Emissions (150 kHz – 30 MHz) Results: PASSED Voltage Limits



TELECOM (QUANT-060108-10) CISPR22 CLASS A CONDUCTED EMISSIONS – TELECOM LINE

Freq. (MHz)


Detector (PK/QP/AV)


Average Delta(dB)



0.82 62.53 PK 74.00 -11.47 87.00 -24.47 1.11 65.80 PK 74.00 -8.20 87.00 -21.20 1.38 64.66 PK 74.00 -9.34 87.00 -22.34

2.4900 61.80 PK 74.00 -12.20 87.00 -25.20 2.79 62.41 PK 74.00 -11.59 87.00 -24.59

2.7900 62.41 PK 74.00 -11.59 87.00 -24.59


RADIATED EMISSIONS TEST RESULTS

CLIENT: Lantronix Inc. DATE: 01/23/06

EUT: External Device Server PROJECT NUMBER: LANTR-060108 MODEL NUMBER: UDS1100 TEST ENGINEER: RJ SERIAL NUMBER: N/A SITE #: 1

TEMPERATURE: 16 deg. C HUMIDITY: 11% RH CONFIGURATION: 230 VAC / 50.

TIME: 9:55 AM

Description: Radiated RF Emissions (30 MHz – 1000 MHz) Results: PASSED Horizontal and Vertical Antenna Polarizations Class A Limits


Radiated Emissions Test Results (Continued)

230VAC/50Hz (LANTR-060108-01) CISPR22 CLASS A RADIATED EMISSIONS - Horizontal Antenna Polarization

Freq. (MHz)


Antenna Height (cm)

Azimuth (Degrees)

Quasi Pk Or AVG (dBuV)

Corrected Reading

(dBuV/m)

Limits (dBuV/m)

Diff (dB) +=FAIL

66.25 9.80 400 180 20.68 40.00 -19.32 110.77 11.96 375 270 24.40 40.00 -15.60 130.00 8.07 400 180 21.74 40.00 -18.27 150.03 7.75 400 135 22.29 40.00 -17.71 240.00 11.85 400 45 31.33 47.00 -15.67 244.10 10.89 400 315 30.56 47.00 -16.44 246.01 6.74 400 45 26.50 47.00 -20.50 260.00 6.39 350 135 27.26 47.00 -19.74 288.00 8.69 400 315 31.56 47.00 -15.44 300.00 8.91 400 315 25.97 47.00 -21.03 336.01 15.99 375 270 34.29 47.00 -12.71 375.00 18.64 375 270 36.84 47.00 -10.16 400.00 7.00 375 135 26.09 47.00 -20.91 423.67 4.40 400 45 23.76 47.00 -23.24 445.42 3.26 375 135 23.61 47.00 -23.39 450.00 3.89 400 225 24.46 47.00 -22.54 750.00 8.27 400 315 34.70 47.00 -12.30


230VAC/50Hz (LANTR-060108-01)

CISPR22 CLASS A RADIATED EMISSIONS - Vertical Antenna Polarization Freq. (MHz)


Antenna Height (cm)

Azimuth (Degrees)


Corrected Reading

(dBuV/m)

Limits (dBuV/m)

Diff (dB) +=FAIL

66.25 12.40 100 0 22.90 40.00 -17.10 79.98 8.70 100 45 20.05 40.00 -19.95

110.67 13.42 100 315 27.29 40.00 -12.71 149.97 8.67 100 225 22.20 40.00 -17.80 229.99 8.35 100 225 28.36 40.00 -11.64 240.00 9.21 100 270 29.69 47.00 -17.31 244.10 6.84 100 270 27.51 47.00 -19.49 246.01 7.27 100 270 28.03 47.00 -18.97 288.00 9.42 100 180 33.28 47.00 -13.72 300.00 6.22 100 180 23.18 47.00 -23.82 336.01 9.26 100 135 27.60 47.00 -19.40 375.00 13.96 100 0 32.36 47.00 -14.64 400.00 6.51 100 270 25.70 47.00 -21.30 423.67 6.10 100 225 25.66 47.00 -21.34 445.42 10.72 100 135 31.27 47.00 -15.73 450.00 6.42 100 270 27.19 47.00 -19.81 750.00 6.95 100 135 33.38 47.00 -13.62



HARMONIC CURRENT EMISSIONS – EN61000-3-2 CLIENT: Lantronix DATE: 01/02/06

EUT: External Device Server TEST ENGINEER: RJ

MODEL NUMBER: UDS1100 BAROMETRIC PRESSURE: 29.84n

SERIAL NUMBER: N/A TEMPERATURE: 20 deg C SPECIFICATION: EN61000-3-2 HUMIDITY: 50% RH

TEST LEVEL: Class A Device Limits TIME: 04:00 PM

SYS61K Version 1.25 was used The measuring setup consists of a LMG95, SN 04800202, Rev. 3.108 according to the standard: EN61000-4-7:2002 Compliance was tested against EN61000-3-2:1995 limits The smoothing filter was switched on The measuring ranges 250.0 V, scaling 1.0 for voltage and 10.0 A, scaling 1.0 for current were used. Class A was chosen Measuring time was: 00:02:30 Voltage check: Phase 1 All voltage harmonics within the limit : ok Voltage +/-2% of nominal value : ok Frequency within +/-0.5% : ok Current check: All current harmonics within the limit : ok All fluctuating harmonics within the time limit: ok Global values from chosen frame at 00:00:00 before end of measuring (informative): Phase 1 U = 230.1223 V I = 0.0426 A P = 2.9727 W PF = 0.3031 f = 49.9961 Hz


HARMONIC CURRENT EMISSIONS – EN61000-3-2 (Continued) Phase 1 n Iaver fluc% Imax Iall I/Ilim,% Umax -------------------------------------------------------------------------------------------------- 0 0.0125 NaN 0.0128 0.0327 1 0.0207 NaN 0.0208 0.0000 230.1124 2 0.0001 0.0000 0.0001 0.0000 0.0399 3 0.0123 0.0000 0.0125 0.5415 0.1013 4 0.0001 0.0000 0.0001 0.0000 0.0148 5 0.0122 0.0000 0.0123 1.0818 0.0323 6 0.0001 0.0000 0.0001 0.0000 0.0110 7 0.0118 0.0000 0.0119 1.5504 0.0173 8 0.0001 0.0000 0.0001 0.0000 0.0076 9 0.0115 0.0000 0.0115 2.8848 0.0115 10 0.0001 0.0000 0.0001 0.0000 0.0058 11 0.0109 0.0000 0.0110 3.3206 0.0050 12 0.0001 NaN 0.0001 0.0000 0.0057 13 0.0103 0.0000 0.0104 4.9393 0.0074 14 0.0001 NaN 0.0001 0.0000 0.0043 15 0.0096 0.0000 0.0097 6.4425 0.0040 16 0.0001 NaN 0.0001 0.0000 0.0037 17 0.0089 0.0000 0.0090 6.7694 0.0059 18 0.0001 NaN 0.0001 0.0000 0.0044 19 0.0082 0.0000 0.0082 6.9437 0.0059 20 0.0001 0.0000 0.0001 0.0000 0.0031 21 0.0074 NaN 0.0074 6.9515 0.0063 22 0.0001 NaN 0.0001 0.0000 0.0031 23 0.0066 NaN 0.0066 6.7868 0.0083 24 0.0001 NaN 0.0001 0.0000 0.0025 25 0.0058 NaN 0.0059 6.5325 0.0100 26 0.0001 NaN 0.0001 0.0000 0.0028 27 0.0050 NaN 0.0051 6.1119 0.0066 28 0.0001 NaN 0.0001 0.0000 0.0024 29 0.0043 NaN 0.0044 0.0000 0.0048 30 0.0001 NaN 0.0001 0.0000 0.0028 31 0.0036 NaN 0.0037 0.0000 0.0032 32 0.0001 NaN 0.0001 0.0000 0.0019 33 0.0029 NaN 0.0030 0.0000 0.0068 34 0.0001 NaN 0.0001 0.0000 0.0020 35 0.0023 NaN 0.0024 0.0000 0.0043 36 0.0001 NaN 0.0001 0.0000 0.0040 37 0.0018 NaN 0.0019 0.0000 0.0023 38 0.0001 NaN 0.0001 0.0000 0.0018 39 0.0014 NaN 0.0015 0.0000 0.0035 40 0.0001 NaN 0.0001 0.0000 0.0017


HARMONIC CURRENT EMISSIONS – EN61000-3-2 (Continued)

Certification of Test Data:


VOLTAGE FLUCTUATIONS AND FLICKER – EN61000-3-3


EUT: External Device Server TEST ENGINEER: RJ

MODEL NUMBER: UDS1100 BAROMETRIC PRESSURE: 29.84n

SERIAL NUMBER: 6732448 TEMPERATURE: 20 deg C SPECIFICATION: EN61000-3-3 HUMIDITY: 50% RH

TEST LEVEL: Per Annex A TIME: 06:10 PM SYS61K Version 1.25 was used The measuring setup consists of a LMG95, SN 04800202, Rev. 3.108 according to the standard: EN61000-4-15 Compliance was tested against EN61000-3-3+A1 limits The measuring ranges 250.0 V, scaling 1.0 for voltage and 10.0 A, scaling 1.0 for current were used. Short time : 00:01:00 Number of periods : 24 Flicker check: Phase 1 Pst always < 1.0 : ok Plt < 0.65 : ok dmax < 4.0% : ok d(t) < 3.3% for <500ms : ok dc < 3.3% : ok Values from chosen frame at 00:00:00 before end of long time interval (informative): Phase 1 Pst = 0.0000 Plt = 0.0000 dmax = 0.0418 % dc = 0.0000 % U = 230.0382 V I = 0.0409 A P = 2.9764 W PF = 0.3165 f = 49.9963 Hz


n Pst 1 Plt 1 n Pst 1 Plt 1 ----------------------------------------------------------------------------------------------------- 1 0.0000 13 0.0000 2 0.0000 14 0.0000 3 0.0000 15 0.0000 4 0.0000 16 0.0000 5 0.0000 17 0.0000 6 0.0000 18 0.0000 7 0.0000 19 0.0000 8 0.0000 20 0.0000 9 0.0000 21 0.0000 10 0.0000 22 0.0000 11 0.0000 23 0.0000 12 0.0000 24 0.0000 0.0000


VOLTAGE FLUCTUATIONS AND FLICKER – EN61000-3-3 (Continued)


Electro-static Discharge – Test Results

COMPANY: LANTRONIX DATE: 02/02/06

EUT: External Device Server ENGINEER: RJ

MODEL TESTED: UDS1100 S/N: N/A

SPEC.: EN 61000-4-2: A2/2001 AIR TEMPERATURE: 15 deg C

LEVEL: 8.0 kV Air Discharge (Direct) 4.0 kV Contact Discharge (Direct/Indirect)

BAROMETRIC PRESSURE: 30.29 in

PERFORMANCE CRITERIA: B RELATIVE

HUMIDITY: 60% RH

TABLE 1: AIR DISCHARGE (Direct) Number of discharges per test point = 25ea, +2kV, +4kV, +6kV, +8kV.

Direct Discharge Location (EUT)

+ 8.0 kV Pass / Fail/No Discharge

Performance Criterion

Power Connector X Pass B

Serial Connector X Pass B

Ethernet Plastic Connector (discharge to RJ-45 connector shell)

X Pass B

TABLE 2: CONTACT DISCHARGE (Direct) Number of discharges per test point = 25ea, +2kV & +4kV.


+ 4.0 kV Pass / Fail Performance

Criterion

Left Side of EUT X Pass B

Right Side of EUT X Pass B

Bottom Side of EUT X Pass B

Serial Connector Shell X Pass B

Ethernet Connector Shell X Pass B Certification of Test Data:


Electro-static Discharge – Test Results (Continued)








HUMIDITY: 61% RH

TABLE 3: CONTACT DISCHARGE (Indirect) Number of discharges per test point = 25ea. +2kV & +4kV.

Indirect Discharge Location (EUT)


Criterion

HCP (All 4 Sides) X Pass B

VCP (All 4 Sides) X Pass B Certification of Test Data:


Radiated Susceptibility – Test Results




SPEC. EN 61000-4-3: A1/2003 AIR TEMPERATURE: 12 C

LEVEL: 3.0 V/m, 1 kHz AM sine wave at 80%. BAROMETRIC PRESSURE: 30.29 in

PERFORMANCE CRITERIA: A RELATIVE

HUMIDITY: 62%

TABLE 4: RADIATED IMMUNITY

Frequency Range Front V/H

Back V/H

Left Side V/H

Right Side V/H

Pass Fail Perform. Criteria

80 – 1000 MHz. X X X X X A

Measurements were taken in a fully lined anechoic chamber at 3.0 V/m. Certification of Test Data:


Electrical Fast Transient / Burst – Test Results




SPEC. EN 61000-4-4: A2 2002 AIR TEMPERATURE: 17.1 deg C

LEVEL: 1.0 kV Power Lines 0.5 kV I/O Lines



HUMIDITY: 42% RH

TABLE 5: Electrical Fast Transient Burst (Power Lines)

+ 1.0 kV - 1.0 kV EFT insertion point

Pass Fail Pass Fail Performance

Criteria

Line X X B

Neutral X X B

Protective Earth X X B

Line to Protective Earth X X B

Neutral to Protective Earth X X B

Line to Neutral X X B

Line to Neutral to Protective Earth X X B

TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)

TEST DURATION (minutes) TIME BETWEEN TESTS (seconds)

1.0 0.500 0.500 1.0 60.0 TABLE 6: Electrical Fast Transient Burst (I/O Lines)

+ 0.5 kV -0.5 kV EFT insertion point


Criteria

Ethernet Cable X X B

Serial Cable X X B

TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)

TEST DURATION (minutes)

TIME BETWEEN TESTS (seconds)

1.0 0.250 0.250 1.0 60.0 Certification of Test Data:


Surge – Test Results COMPANY: LANTRONIX DATE: 1/27/06



SPEC. EN 61000-4-5: A1/A2 2001 AIR TEMPERATURE: 17.1 deg C

LEVEL: 2.0 kV Common Mode 1.0 kV Differential Mode



HUMIDITY: 39% RH

TABLE 7: Power Line Transients (Common Mode)

+ 2.0 kV - 2.0 kV Surge insertion point


Criteria

Line to Ground X X B

Neutral to Ground X X B

Line & Neutral to Ground X X B

TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)


2.0 0.500 0.500 1.0 50.0 TABLE 8: Power Line Transients (Differential Mode)



Criteria


TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)




Conducted Immunity – Test Results COMPANY: LANTRONIX DATE: 02/01/06



SPEC. EN 61000-4-6: A1/A2 2001 AIR TEMPERATURE: 14 C

LEVEL: 3.0 Vrms, 80% AM Modulated (1kHz) BAROMETRIC PRESSURE: N/A


HUMIDITY: 60%

TABLE 9: RF Conducted Susceptibility Test

3.0 Vrms Location Frequency range

Pass Fail Performance

Criteria

Power line 0.15 – 80 MHz X A

Ethernet Cable 0.15 – 80 MHz X A

Serial Cable 0.15 – 80 MHz X A Certification of Test Data:


Magnetic Field Immunity – Test Results COMPANY: LANTRONIX DATE: 02/02/06



SPEC. EN 61000-4-8: 1993 AIR TEMPERATURE: 12 C

LEVEL: 50 Hz 1.0 A(rms)/m



HUMIDITY: 71%

TABLE 10: Power Frequency Magnetic Field Test

1.0 A(rms)/m Frequency (Hz)


Criteria

50 x A Certification of Test Data:


Voltage Dips and Interrupts – Test Results COMPANY: Lantronix DATE: 1/27/06



SPEC. EN61000-4-11: A1 2002 AIR TEMPERATURE: 17.1 deg C

LEVEL: >95%, 0.5 periods, 30%, 25 periods, >95%, 250 periods


PERFORMANCE CRITERIA:

B (>95%, 0.5 periods), C (30%, 25 periods), C (>95%, 250 periods)

RELATIVE HUMIDITY: 42% RH

Table 11: Voltage Dips and Interrupts Test (EN55024)

Results Environmental Phenomenal

Voltage Level Reduction Duration


Criteria

Voltage Dip 230 VAC 50Hz >95% reduction 0.5 periods X B

Voltage Dip 230 VAC 50 Hz 30% reduction 25 periods X C

Voltage Interruption 230 VAC 50 Hz >95% reduction 250 periods X C


Page 1 of 14 (Appendix B) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX B

TEST DATA

EUT Configuration #2 Model Number UDS1100 Serial Number N/A Power Supply Manufacture: CUI Inc.

Model Number: 3A-161WP12 Serial Number: N/A



CLIENT: Lantronix DATE: 01/23/06 EUT: External Device Server PROJECT NUMBER: LANTR-060108 MODEL NUMBER: UDS100 TEST ENGINEER: RJ SERIAL NUMBER: N/A SITE #: 1

TEMPERATURE: 21 deg. C HUMIDITY: 17% CONFIGURATION: 230 VAC / 50Hz.

TIME: 04:20 PM

Description: Conducted RF Emissions (150 kHz – 30 MHz) Results: PASSED LINE 1 and LINE 2 Class A Limits



230VAC/50Hz (LANTR-060108-04) CISPR22 CLASS A CONDUCTED EMISSIONS – LINE 1

Freq. (MHz)


Detector (PK/QP/AV)


Average Delta(dB)



0.1500 38.48 PK 66.00 -27.52 79.00 -40.52 0.1700 34.70 PK 66.00 -31.30 79.00 -44.30 0.1700 33.40 PK 66.00 -32.60 79.00 -45.60 0.1800 33.82 PK 66.00 -32.18 79.00 -45.18 0.4600 37.47 PK 66.00 -28.53 79.00 -41.53

22.8200 34.82 PK 60.00 -25.18 73.00 -38.18



230VAC/50HZ (LANTR-060108-04) CISPR22 CLASS A CONDUCTED EMISSIONS - LINE 2

Freq. (MHz)


Detector (PK/QP/AV)


Average Delta(dB)



0.1600 39.57 PK 66.00 -26.43 79.00 -39.43 0.1700 37.79 PK 66.00 -28.21 79.00 -41.21 0.2000 33.38 PK 66.00 -32.62 79.00 -45.62 0.4300 36.38 PK 66.00 -29.62 79.00 -42.62

18.3200 34.13 PK 60.00 -25.87 73.00 -38.87 22.8200 34.39 PK 60.00 -25.61 73.00 -38.61



CLIENT: Lantronix DATE: 01/24/06 EUT: External Device Server PROJECT NUMBER: LANTR-060108 MODEL NUMBER: UDS1100 TEST ENGINEER: RJ SERIAL NUMBER: N/A SITE #: 1

TEMPERATURE: 18 deg C HUMIDITY: 16% RH CONFIGURATION: 230 VAC / 50Hz

TIME: 8:40 AM

Description: Conducted Telecommunication Port “Ethernet" RF Emissions (150 kHz – 30 MHz) Results: PASSED Voltage Limits



TELECOM (QUANT-060108-05a) CISPR22 CLASS A CONDUCTED EMISSIONS – TELECOM LINE

Freq. (MHz)


Detector (PK/QP/AV)


Average Delta(dB)



0.46 63.89 PK 75.14 -11.25 88.14 -24.25 1.11 56.73 PK 74.00 -17.27 87.00 -30.27 2.03 56.25 PK 74.00 -17.75 87.00 -30.75

11.76 56.93 PK 74.00 -17.07 87.00 -30.07 13.35 57.67 PK 74.00 -16.33 87.00 -29.33 16.14 56.91 PK 74.00 -17.09 87.00 -30.09


RADIATED EMISSIONS TEST RESULTS


EUT: External Device Server PROJECT NUMBER: LANTR-060108 MODEL NUMBER: UDS1100 TEST ENGINEER: RJ SERIAL NUMBER: N/A SITE #: 1

TEMPERATURE: 21 deg. C HUMIDITY: 8% RH CONFIGURATION: 230 VAC / 50Hz

TIME: 03:15 AM

Description: Radiated RF Emissions (30 MHz – 1000 MHz) Results: PASSED Horizontal and Vertical Antenna Polarizations Class A Limits



(LANTR-060108-03)

CISPR22 CLASS A RADIATED EMISSIONS - Horizontal Antenna Polarization Freq. (MHz)


Antenna Height (cm)

Azimuth (Degrees)


Corrected Reading

(dBuV/m)

Limits (dBuV/m)

Diff (dB) +=FAIL

110.77 14.07 400 0 26.51 40.00 -13.49 240.00 8.01 400 0 27.49 47.00 -19.51 288.00 8.14 300 90 31.01 47.00 -15.99 336.01 15.99 300 0 34.29 47.00 -12.71 375.00 18.76 300 270 36.96 47.00 -10.04 750.00 3.94 300 0 30.37 47.00 -16.63

(LANTR-060108-03)

CISPR22 CLASS A RADIATED EMISSIONS - Vertical Antenna Polarization Freq. (MHz)


Antenna Height (cm)

Azimuth (Degrees)


Corrected Reading

(dBuV/m)

Limits (dBuV/m)

Diff (dB) +=FAIL

110.67 9.63 100 0 23.50 40.00 -16.50 229.99 3.70 100 90 23.71 40.00 -16.29 288.00 4.95 100 90 28.81 47.00 -18.19 375.00 12.81 100 0 31.21 47.00 -15.79 445.42 6.66 100 90 27.21 47.00 -19.79 750.00 5.30 100 180 31.73 47.00 -15.27


Electro-static Discharge – Test Results








HUMIDITY: 60% RH

TABLE 1: AIR DISCHARGE (Direct) Number of discharges per test point = 25ea, +2kV, +4kV, +6kV, +8kV.


+ 8.0 kV Pass / Fail/No Discharge

Performance Criterion

Power Connector X Pass B

Serial Connector X Pass B

Ethernet Plastic Connector (discharge to RJ-45 connector shell)

X Pass B

TABLE 2: CONTACT DISCHARGE (Direct) Number of discharges per test point = 25ea, +2kV & +4kV.



Criterion

Left Side of EUT X Pass B

Right Side of EUT X Pass B

Bottom Side of EUT X Pass B

Serial Connector Shell X Pass B

Ethernet Connector Shell X Pass B Certification of Test Data:


Electro-static Discharge – Test Results (Continued)








HUMIDITY: 61% RH

TABLE 3: CONTACT DISCHARGE (Indirect) Number of discharges per test point = 25ea. +2kV & +4kV.

Indirect Discharge Location (EUT)


Criterion

HCP (All 4 Sides) X Pass B

VCP (All 4 Sides) X Pass B Certification of Test Data:


Electrical Fast Transient / Burst – Test Results




SPEC. EN 61000-4-4: A2 2002 AIR TEMPERATURE: 4 deg C

LEVEL: 1.0 kV Power Lines BAROMETRIC PRESSURE: 30.29 in


HUMIDITY: 100% RH

TABLE 4: Electrical Fast Transient Burst (Power Lines)

+ 1.0 kV - 1.0 kV EFT insertion point


Criteria

Line X X B

Neutral X X B

Protective Earth X X B

Line to Protective Earth X X B

Neutral to Protective Earth X X B


Line to Neutral to Protective Earth X X B

TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)




Surge – Test Results COMPANY: LANTRONIX DATE: 1/30/06



SPEC. EN 61000-4-5: A1/A2 2001 AIR TEMPERATURE: 9 deg C

LEVEL: 2.0 kV Common Mode 1.0 kV Differential Mode



HUMIDITY: 90% RH

TABLE 5: Power Line Transients (Common Mode)



Criteria

Line to Ground X X B

Neutral to Ground X X B

Line & Neutral to Ground X X B

TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)


2.0 0.500 0.500 1.0 50.0 TABLE 6: Power Line Transients (Differential Mode)



Criteria


TEST LEVEL (kV)

START VOLTAGE (kV)

STEP VOLTAGE (kV)




Conducted Immunity – Test Results COMPANY: LANTRONIX DATE: 02/01/06



SPEC. EN 61000-4-6: A1/A2 2001 AIR TEMPERATURE: 15 C

LEVEL: 3.0 Vrms, 80% AM Modulated (1kHz) BAROMETRIC PRESSURE: N/A


HUMIDITY: 60%

TABLE 7: RF Conducted Susceptibility Test

3.0 Vrms Location Frequency range


Criteria

Power line 0.15 – 80 MHz X A Certification of Test Data:


Voltage Dips and Interrupts – Test Results COMPANY: LANTRONIX DATE: 1/30/06



SPEC. EN61000-4-11: A1 2002 AIR TEMPERATURE: 9 deg C

LEVEL: >95%, 0.5 periods, 30%, 25 periods, >95%, 250 periods


PERFORMANCE CRITERIA:

B (>95%, 0.5 periods), C (30%, 25 periods), C (>95%, 250 periods)

RELATIVE HUMIDITY: 90% RH

Table 8: Voltage Dips and Interrupts Test (EN55024)

Results Environmental Phenomenal

Voltage Level Reduction Duration


Criteria

Voltage Dip 230 VAC 50Hz >95% reduction 0.5 periods X B

Voltage Dip 230 VAC 50 Hz 30% reduction 25 periods X C

Voltage Interruption 230 VAC 50 Hz >95% reduction 250 periods X C


Page 1 of 18 (Appendix C) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX C

PHOTOGRAPHS – TEST SETUPS


AC CONDUCTED EMISSIONS – EN55022

CONDUCTED EMISSIONS – FRONT VIEW

FOR

EUT: External Device Server MODEL NUMBER: UDS1100


CONDUCTED EMISSIONS – SIDE VIEW

FOR



RADIATED EMISSIONS – FRONT VIEW

FOR



RADIATED EMISSIONS – REAR VIEW

FOR



AC HARMONIC EMISSIONS / FLICKER – EN61000-3-2 / EN61000-3-3

AC Harmonic Emissions / Flicker Tests Per EN61000-3-2 / EN61000-3-3


ELECTROSTATIC DISCHARGE IMMUNITY TEST – EN61000-4-2

Electrostatic Discharge Tests Per EN61000-4-2

Direct Air Discharge


Electrostatic Discharge Immunity Test – EN61000-4-2 (Continued)


Direct Contact Discharge




Indirect Contact Discharge (Vertical Coupling Plane)




Indirect Contact Discharge (Horizontal Coupling Plane)


RADIATED, RADIO-FREQUENCY, ELECTROMAGNETIC FIELD IMMUNITY TEST – EN61000-4-3

Radiated Field Susceptibility Tests Per EN61000-4-3

Radiated Immunity


ELECTRICAL FAST TRANSIENTS/BURST IMMUNITY TEST – EN61000-4-4

Electrical Fast Transients/Burst Tests Per EN61000-4-4

Injection to Power Cable


ELECTRICAL FAST TRANSIENTS/BURST IMMUNITY TEST – EN61000-4-4

Electrical Fast Transients/Burst Tests Per EN61000-4-4

Injection to Signal Cable


SURGE IMMUNITY TEST – EN61000-4-5

Surge Immunity Tests Per EN61000-4-5



IMMUNITY TO CONDUCTED DISTURBANCES, INDUCED BY RADIO FREQEUNCY FIELDS – EN61000-4-6

RF Conducted Susceptibility Tests Per EN61000-4-6



IMMUNITY TO CONDUCTED DISTURBANCES, INDUCED BY RADIO FREQEUNCY FIELDS – EN61000-4-6

RF Conducted Susceptibility Tests Per EN61000-4-6

Injection to Signal Cable


POWER FREQUENCY MAGNETIC FIELD IMMUNITY TEST – EN61000-4-8

Power Frequency Magnetic Field Immunity Test per EN61000-4-8

Injection on Enclosure


VOLTAGE DIPS, SHORT INTERRUPTIONS AND VOLTAGE VARIATIONS IMMUNITY TEST – EN61000-4-11

Voltage Dips and Interruptions Tests Per EN61000-4-11

Injection to Power Port

Page 1 of 3 (Appendix D) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX D

CALIBRATION CORRECTION TABLE


Calibration Correction Table Freq Index Cable Loss

10m Horz. Ant

10m Total Vert. Ant

10m Total

30.00 0.00 0.89 13.50 -14.39 13.70 -14.59 40.00 1.00 0.98 11.50 -12.48 10.70 -11.68 50.00 2.00 1.07 10.40 -11.47 9.30 -10.37 60.00 3.00 1.14 9.80 -10.94 8.80 -9.94 70.00 4.00 1.24 9.60 -10.84 9.60 -10.84 80.00 5.00 1.45 9.40 -10.85 9.90 -11.35 90.00 6.00 1.51 9.60 -11.11 9.80 -11.31

100.00 7.00 1.64 10.10 -11.74 10.60 -12.24 110.00 8.00 1.78 10.60 -12.38 12.20 -13.98 120.00 9.00 1.92 11.20 -13.12 10.40 -12.32 130.00 10.00 1.97 11.70 -13.67 9.60 -11.57 140.00 11.00 2.01 12.00 -14.01 9.80 -11.81 150.00 12.00 2.14 12.40 -14.54 11.40 -13.54 160.00 13.00 2.26 12.90 -15.16 13.90 -16.16 170.00 14.00 2.33 13.30 -15.63 13.70 -16.03 180.00 15.00 2.40 14.10 -16.50 14.40 -16.80 190.00 16.00 2.39 14.50 -16.89 14.20 -16.59 200.00 17.00 2.37 15.10 -17.47 14.50 -16.87 225.00 18.00 2.48 16.30 -18.78 17.30 -19.78 250.00 19.00 2.55 17.40 -19.95 18.40 -20.95 275.00 20.00 2.64 19.60 -22.24 20.90 -23.54 299.99 21.00 2.76 20.70 -23.46 21.40 -24.16 300.00 22.00 2.76 14.30 -17.06 14.20 -16.96 325.00 23.00 2.89 15.40 -18.29 15.40 -18.29 350.00 24.00 3.01 15.30 -18.31 15.40 -18.41 375.00 25.00 3.10 15.10 -18.20 15.30 -18.40 400.00 26.00 3.19 15.90 -19.09 16.00 -19.19 425.00 27.00 3.28 16.10 -19.38 16.30 -19.58


Calibration Correction Table (Continued) Freq Index Cable Loss

10m Horz. Ant 10m Total Vert. Ant

10m Total

450.00 28.00 3.37 17.20 -20.57 17.40 -20.77 475.00 29.00 3.48 18.00 -21.49 17.80 -21.29 500.00 30.00 3.60 18.60 -22.20 18.50 -22.10 525.00 31.00 3.70 18.90 -22.61 18.80 -22.51 550.00 32.00 3.81 19.00 -22.81 18.90 -22.71 575.00 33.00 3.92 19.50 -23.42 19.50 -23.42 600.00 34.00 4.02 19.10 -23.12 19.50 -23.52 625.00 35.00 4.10 20.20 -24.30 20.00 -24.10 650.00 36.00 4.18 21.00 -25.18 20.70 -24.88 675.00 37.00 4.16 22.10 -26.26 21.60 -25.76 700.00 38.00 4.14 23.00 -27.14 22.30 -26.44 725.00 39.00 4.28 22.60 -26.89 22.00 -26.29 750.00 40.00 4.43 22.00 -26.43 22.00 -26.43 775.00 41.00 4.49 22.70 -27.19 22.60 -27.09 800.00 42.00 4.54 22.40 -26.94 22.20 -26.74 825.00 43.00 4.61 22.50 -27.11 22.00 -26.61 850.00 44.00 4.68 22.90 -27.58 22.30 -26.98 875.00 45.00 4.89 23.20 -28.09 22.70 -27.59 900.00 46.00 5.10 24.00 -29.10 23.50 -28.60 925.00 47.00 5.13 24.00 -29.13 23.70 -28.83 950.00 48.00 5.15 23.90 -29.05 23.40 -28.55 975.00 49.00 5.22 24.00 -29.22 23.40 -28.62

1000.00 50.00 5.28 24.00 -29.28 23.50 -28.78

Page 1 of 1 (Appendix E) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX E

MODIFICATIONS AND RECOMMENDATIONS

1.0 None

Page 1 of 4 (Appendix F) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX F

ACCREDITATION CERTIFICATE(S)




Page 1 of 2 (Appendix G) Report Number: LANTR-060108CE Revision Number: A3

APPENDIX G

ADDITIONAL MODELS CONSIDERED UNDER SIMILARITY

Page 2 of 2 (Appendix G) Report Number: LANTR-060108CE Revision Number: A3

Model Configuration Notes

UDS1100 Tested All Three Configurations Device Tested

VDS100 N/A Not Tested (See Note 1) NETCOM-1S N/A Not Tested (See Note 2)

NOTE 1: • According to the manufacturer this model is a lesser configuration than the UDS1100 that was

tested. Because of their similarity it was decided by the manufacturer that the UDS1100 is “worst-case” test configuration when compared to the VDS100 since the UDS1100 has a DC-DC converter 3.3V output and VDS100 does not. The VDS100 directly uses an external 3.3V source.

NOTE 2:

• Identical to the UDS1100 that was tested.

Documents

013405_10_UDS1100Konverter_GB_0307