Test report

FCC ID: XKB-L5000CLV3

Test Report

Download: PDF
FCCID_4380449

TEST REPORT Test report no.: 1-8662/19-01-02-A BNetzA-CAB-02/21-102 Testing laboratory Applicant CTC advanced GmbH Ingenico Group Untertuerkheimer Strasse 6 – 10 9 Avenue de la Gare Rovaltain 66117 Saarbruecken / Germany 26958 Valence Cedex 9 / FRANCE Phone: + 49 681 5 98 - 0 Phone: -/- Fax: + 49 681 5 98 - 9075 Contact: Nicolas Jacquemont Internet: http://www.ctcadvanced.com e-mail: nicolas.jacquemont@ingenico.com e-mail: mail@ctcadvanced.com Phone: +33475842123 Accredited Testing Laboratory: The testing laboratory (area of testing) is accredited according to DIN EN ISO/IEC 17025 (2005) by the Deutsche Akkreditierungsstelle GmbH (DAkkS) Manufacturer The accreditation is valid for the scope of testing Ingenico Group procedures as stated in the accreditation certificate 9 Avenue de la Gare Rovaltain starting with the registration number: D-PL-12076-01. 26958 Valence Cedex 9 / FRANCE Test standard/s FCC - Title 47 CFR FCC - Title 47 of the Code of Federal Regulations; Chapter I; Part 15 - Radio Part 15 frequency devices Spectrum Management and Telecommunications Radio Standards Specification - RSS - 210 Issue 9 Licence-Exempt Radio Apparatus: Category I Equipment Spectrum Management and Telecommunications Radio Standards Specification RSS - Gen Issue 5 - General Requirements for Compliance of Radio Apparatus For further applied test standards please refer to section 3 of this test report. Test Item Kind of test item: Payment Terminal Model name: Lane/5000 FCC ID: XKB-L5000CLV3 IC: 2586D-L50000CLV3 Frequency: 13.56 MHz Technology tested: RFID Antenna: Integrated loop antenna Power supply: 8.0 V DC via external AC/DC adaptor Temperature range: 0°C to +45°C This test report is electronically signed and valid without handwritten signature. For verification of the electronic signatures, the public keys can be requested at the testing laboratory. Test report authorized: Test performed: cn=Marco Bertolino, o=CTC advanced Digital unterschrieben von David Lang GmbH, ou=BTL-161128, DN: cn=David Lang, o=CTC advanced GmbH, email=Marco.Bertolino@ctcadvanced.com, ou=LNG-161129, c=DE email=david.lang@ctcadvanced.com, c=DE Datum: 2019.07.18 16:52:54 +02'00' 2019.07.18 15:31:54 +02'00' Marco Bertolino David Lang Lab Manager Lab Manager Radio Communications & EMC Radio Communications & EMC

Test report no.: 1-8662/19-01-02-A 1 Table of contents 1 Table of contents ............................................................................................................................................2 2 General information .......................................................................................................................................3 2.1 Notes and disclaimer ..........................................................................................................................3 2.2 Application details ...............................................................................................................................3 2.3 Test laboratories sub-contracted ......................................................................................................3 3 Test standard/s and references ....................................................................................................................4 4 Test environment............................................................................................................................................5 5 Test item ..........................................................................................................................................................5 5.1 General description .............................................................................................................................5 5.2 Additional information ........................................................................................................................5 6 Description of the test setup .........................................................................................................................6 6.1 Shielded semi anechoic chamber ......................................................................................................7 6.2 Shielded fully anechoic chamber ......................................................................................................8 6.3 AC conducted ......................................................................................................................................9 6.4 Conducted measurements normal and extreme conditions.........................................................10 7 Sequence of testing .....................................................................................................................................11 7.1 Sequence of testing radiated spurious 9 kHz to 30 MHz ...............................................................11 7.2 Sequence of testing radiated spurious 30 MHz to 1 GHz ..............................................................12 7.3 Sequence of testing radiated spurious above 1 GHz ....................................................................13 8 Measurement uncertainty ............................................................................................................................14 9 Summary of measurement results .............................................................................................................15 10 Additional comments ...............................................................................................................................15 11 Measurement results ................................................................................................................................16 11.1 Occupied bandwidth......................................................................................................................16 11.2 Field strength of the fundamental ................................................................................................18 11.3 Field strength of the harmonics and spurious ...........................................................................19 11.4 Conducted limits ............................................................................................................................22 11.5 Frequency error .............................................................................................................................25 12 Observations .............................................................................................................................................26 Annex A Glossary ..........................................................................................................................................26 Annex B Document history ..........................................................................................................................27 Annex C Accreditation Certificate – D-PL-12076-01-04 .............................................................................27 Annex D Accreditation Certificate – D-PL-12076-01-05 .............................................................................28 © CTC advanced GmbH Page 2 of 28

Test report no.: 1-8662/19-01-02-A 2 General information 2.1 Notes and disclaimer The test results of this test report relate exclusively to the test item specified in this test report. CTC advanced GmbH does not assume responsibility for any conclusions and generalizations drawn from the test results with regard to other specimens or samples of the type of the equipment represented by the test item. The test report may only be reproduced or published in full. Reproduction or publication of extracts from the report requires the prior written approval of CTC advanced GmbH. The testing service provided by CTC advanced GmbH has been rendered under the current "General Terms and Conditions for CTC advanced GmbH". CTC advanced GmbH will not be liable for any loss or damage resulting from false, inaccurate, inappropriate or incomplete product information provided by the customer. Under no circumstances does the CTC advanced GmbH test report include any endorsement or warranty regarding the functionality, quality or performance of any other product or service provided. Under no circumstances does the CTC advanced GmbH test report include or imply any product or service warranties from CTC advanced GmbH, including, without limitation, any implied warranties of merchantability, fitness for purpose, or non-infringement, all of which are expressly disclaimed by CTC advanced GmbH. All rights and remedies regarding vendor’s products and services for which CTC advanced GmbH has prepared this test report shall be provided by the party offering such products or services and not by CTC advanced GmbH. In no case this test report can be considered as a Letter of Approval. This test report is electronically signed and valid without handwritten signature. For verification of the electronic signatures, the public keys can be requested at the testing laboratory. This test report replaces the test report with the number 1-8662/19-01-02 and dated 2019-07-15. 2.2 Application details Date of receipt of order: 2019-06-11 Date of receipt of test item: 2019-07-09 Start of test: 2019-07-10 End of test: 2019-07-11 Person(s) present during the test: -/- 2.3 Test laboratories sub-contracted None © CTC advanced GmbH Page 3 of 28

Test report no.: 1-8662/19-01-02-A 3 Test standard/s and references Test standard Date Description FCC - Title 47 of the Code of Federal Regulations; Chapter I; Part FCC - Title 47 CFR Part 15 -/- 15 - Radio frequency devices Spectrum Management and Telecommunications Radio Standards August RSS - 210 Issue 9 Specification - Licence-Exempt Radio Apparatus: Category I 2016 Equipment Spectrum Management and Telecommunications Radio Standards RSS - Gen Issue 5 April 2018 Specification - General Requirements for Compliance of Radio Apparatus Guidance Version Description American National Standard for Methods of Measurement of ANSI C63.4-2014 -/- Radio-Noise Emissions from Low-Voltage Electrical and Electronic Equipment in the Range of 9 kHz to 40 GHz American National Standard of Procedures for Compliance ANSI C63.10-2013 -/- Testing of Unlicensed Wireless Devices Accreditation Description D-PL-12076-01-04 Telecommunication and EMC Canada https://www.dakks.de/as/ast/d/D-PL-12076-01-04.pdf D-PL-12076-01-05 Telecommunication FCC requirements https://www.dakks.de/as/ast/d/D-PL-12076-01-05.pdf © CTC advanced GmbH Page 4 of 28

Test report no.: 1-8662/19-01-02-A 4 Test environment Tnom +20 °C during room temperature tests Temperature : Tmax +45 °C during high temperature tests Tmin 0 °C during low temperature tests Relative humidity content : 42 % Barometric pressure : 1019 hpa Vnom 8.0 V DC via external AC/DC adaptor Power supply : Vmax 9.2 V Vmin 7.1 V 5 Test item 5.1 General description Kind of test item : Payment Terminal Type identification : Lane/5000 HMN : -/- PMN : Lane/5000 HVIN : Lane/5000 CLv3 FVIN : -/- S/N serial number : 190517323031012503981498 Hardware status : Not provided! Software status : Not provided! Firmware status : Not provided! Frequency band : 13.56 MHz Type of radio transmission : modulated carrier Use of frequency spectrum : Type of modulation : ASK Number of channels : 1 Antenna : Integrated loop antenna Power supply : 8.0 V DC via external AC/DC adaptor Temperature range : 0°C to +45°C 5.2 Additional information The content of the following annexes is defined in the QA. It may be that not all of the listed annexes are necessary for this report, thus some values in between may be missing. Test setup and EUT photos are included in test report: 1-8662/19/01-01_AnnexA 1-8662/19/01-01_AnnexD © CTC advanced GmbH Page 5 of 28

Test report no.: 1-8662/19-01-02-A 6 Description of the test setup Typically, the calibrations of the test apparatus are commissioned to and performed by an accredited calibration laboratory. The calibration intervals are determined in accordance with the DIN EN ISO/IEC 17025. In addition to the external calibrations, the laboratory executes comparison measurements with other calibrated test systems or effective verifications. Weekly chamber inspections and range calibrations are performed. Where possible, RF generating and signaling equipment as well as measuring receivers and analyzers are connected to an external high-precision 10 MHz reference (GPS-based or rubidium frequency standard). In order to simplify the identification of the equipment used at some special tests, some items of test equipment and ancillaries can be provided with an identifier or number in the equipment list below (Lab/Item). Agenda: Kind of Calibration k calibration / calibrated EK limited calibration ne not required (k, ev, izw, zw not required) zw cyclical maintenance (external cyclical maintenance) ev periodic self verification izw internal cyclical maintenance Ve long-term stability recognized g blocked for accredited testing vlkI! Attention: extended calibration interval NK! Attention: not calibrated *) next calibration ordered / currently in progress © CTC advanced GmbH Page 6 of 28

Test report no.: 1-8662/19-01-02-A 6.1 Shielded semi anechoic chamber The radiated measurements are performed in vertical and horizontal plane in the frequency range from 30 MHz to 1 GHz in semi-anechoic chambers. The EUT is positioned on a non-conductive support with a height of 0.80 m above a conductive ground plane that covers the whole chamber. The receiving antennas are conform to specifications ANSI C63. These antennas can be moved over the height range between 1.0 m and 4.0 m in order to search for maximum field strength emitted from EUT. The measurement distances between EUT and receiving antennas are indicated in the test setups for the various frequency ranges. For each measurement, the EUT is rotated in all three axes until the maximum field strength is received. The wanted and unwanted emissions are received by spectrum analyzers where the detector modes and resolution bandwidths over various frequency ranges are set according to requirement ANSI C63. Measurement distance: tri-log antenna 10 meter; EMC32 software version: 10.30.0 FS = UR + CL + AF (FS-field strength; UR-voltage at the receiver; CL-loss of the cable; AF-antenna factor) Example calculation: FS [dBµV/m] = 12.35 [dBµV/m] + 1.90 [dB] + 16.80 [dB/m] = 31.05 [dBµV/m] (35.69 µV/m) Equipment table: Lab / Kind of Last Next No. Equipment Type Manufacturer Serial No. INV. No. Item Calibration Calibration Calibration 1 A Switch-Unit 3488A HP 2719A14505 300000368 ev -/- -/- 2 A Meßkabine 1 HF-Absorberhalle MWB AG 300023 300000551 ne -/- -/- 3 A EMI Test Receiver ESCI 3 R&S 100083 300003312 k 12.12.2018 11.12.2019 Analyzer-Reference- A3509 07/0 4 A System (Harmonics ARS 16/1 SPS 300003314 vlKI! 15.01.2018 14.01.2020 0205 and Flicker) 5 A Antenna Tower Model 2175 ETS-Lindgren 64762 300003745 izw -/- -/- Positioning 6 A Model 2090 ETS-Lindgren 64672 300003746 izw -/- -/- Controller Turntable Interface- 7 A Model 105637 ETS-Lindgren 44583 300003747 izw -/- -/- Box TRILOG Broadband Schwarzbeck Mess - 8 A Test-Antenna 30 VULB9163 371 300003854 vlKI! 24.11.2017 23.11.2020 Elektronik MHz - 3 GHz 9 A Switch-Unit 3488A HP 2719A14505 300000368 ev -/- -/- © CTC advanced GmbH Page 7 of 28

Test report no.: 1-8662/19-01-02-A 6.2 Shielded fully anechoic chamber Measurement distance: loop antenna 3 meter FS = UR + CA + AF (FS-field strength; UR-voltage at the receiver; CA-loss of the signal path; AF-antenna factor) Example calculation: FS [dBµV/m] = 40.0 [dBµV/m] + (-35.8) [dB] + 32.9 [dB/m] = 37.1 [dBµV/m] (71.61 µV/m) Equipment table: Lab / Kind of Last Next No. Equipment Type Manufacturer Serial No. INV. No. Item Calibration Calibration Calibration Active Loop Antenna 1 A 6502 EMCO 2210 300001015 vlKI! 13.06.2019 12.06.2021 9 kHz to 30 MHz 2 A Anechoic chamber FAC 3/5m MWB / TDK 87400/02 300000996 ev -/- -/- 3 A Switch / Control Unit 3488A HP * 300000199 ne -/- -/- EMI Test Receiver 4 A ESU26 R&S 100037 300003555 k 14.09.2018 13.12.2019 20Hz- 26,5GHz 4U RF Switch 5 A L4491A Agilent Technologies MY50000037 300004509 ne -/- -/- Platform NEXIO EMV- 6 A BAT EMC V3.19.1.8 EMCO -/- 300004682 ne -/- -/- Software 7 A PC ExOne F+W -/- 300004703 ne -/- -/- © CTC advanced GmbH Page 8 of 28

Test report no.: 1-8662/19-01-02-A 6.3 AC conducted FS = UR + CF + VC (FS-field strength; UR-voltage at the receiver; CR-loss of the cable and filter; VC-correction factor of the ISN) Example calculation: FS [dBµV/m] = 37.62 [dBµV/m] + 9.90 [dB] + 0.23 [dB] = 47.75 [dBµV/m] (244.06 µV/m) Equipment table: Lab / Kind of Last Next No. Equipment Type Manufacturer Serial No. INV. No. Item Calibration Calibration Calibration Two-line V-Network 1 A (LISN) 9 kHz to 30 ESH3-Z5 R&S 892475/017 300002209 vlKI! 13.12.2017 12.12.2019 MHz 2 A RF-Filter-section 85420E HP 3427A00162 300002214 NK! -/- -/- 3 A Hochpass 150 kHz EZ-25 R&S 100010 300003798 ev -/- -/- MXE EMI Receiver 4 A N9038A Agilent Technologies MY51210197 300004405 k 12.12.2018 11.12.2019 20 Hz to 26,5 GHz Two-line V-Network 5 A (LISN) 9 kHz to 30 ESH3-Z5 R&S 892475/017 300002209 vlKI! 13.12.2017 12.12.2019 MHz 6 A RF-Filter-section 85420E HP 3427A00162 300002214 NK! -/- -/- © CTC advanced GmbH Page 9 of 28

Test report no.: 1-8662/19-01-02-A 6.4 Conducted measurements normal and extreme conditions OP = AV + CA (OP-output power; AV-analyzer value; CA-loss signal path) Example calculation: OP [dBm] = 6.0 [dBm] + 11.7 [dB] = 17.7 [dBm] (58.88 mW) Equipment table: Lab / Kind of Last Next No. Equipment Type Manufacturer Serial No. INV. No. Item Calibration Calibration Calibration Signal Analyzer 40 1 B FSV40 R&S 101353 300004819 vlKI! 12.12.2017 11.12.2019 GHz EMI Test Receiver 9 2 A kHz - 3 GHz incl. ESPI3 R&S 101713 300004059 k 13.12.2018 12.12.2019 Preselector Temperature Test 3 A VT 4002 Heraeus Voetsch 521/84193 300003889 ev 07.05.2018 06.05.2020 Chamber RF-Cable WLAN- ST18/SMAm/SMAm/ Batch no. 4 A+B Huber & Suhner 400001216 g -/- -/- Tester Port 1 36 601494 © CTC advanced GmbH Page 10 of 28

Test report no.: 1-8662/19-01-02-A 7 Sequence of testing 7.1 Sequence of testing radiated spurious 9 kHz to 30 MHz Setup  The equipment is set up to simulate normal operation mode as described in the user manual or defined by the manufacturer.  If the EUT is a tabletop system, it is placed on a table with 0.8 m height.  If the EUT is a floor standing device, it is placed directly on the turn table.  Auxiliary equipment and cables are positioned to simulate normal operation conditions as described in ANSI C 63.4.  The AC power port of the EUT (if available) is connected to a power outlet below the turntable.  Measurement distance is 3 m (see ANSI C 63.4) – see test details.  EUT is set into operation. Premeasurement*  The turntable rotates from 0° to 315° using 45° steps.  The antenna height is 1 m.  At each turntable position the analyzer sweeps with positive-peak detector to find the maximum of all emissions. Final measurement  Identified emissions during the pre-measurement are maximized by the software by rotating the turntable from 0° to 360°.  Loop antenna is rotated about its vertical axis for maximum response at each azimuth about the EUT. (For certain applications, the loop antenna plane may also need to be positioned horizontally at the specified distance from the EUT)  The final measurement is done in the position (turntable and elevation) causing the highest emissions with quasi-peak (as described in ANSI C 63.4).  Final levels, frequency, measuring time, bandwidth, turntable position, correction factor, margin to the limit and limit will be recorded. A plot with the graph of the premeasurement and the limit is stored. *)Note: The sequence will be repeated three times with different EUT orientations. © CTC advanced GmbH Page 11 of 28

Test report no.: 1-8662/19-01-02-A 7.2 Sequence of testing radiated spurious 30 MHz to 1 GHz Setup  The equipment is set up to simulate normal operation mode as described in the user manual or defined by the manufacturer.  If the EUT is a tabletop system, a table with 0.8 m height is used, which is placed on the ground plane.  If the EUT is a floor standing device, it is placed on the ground plane with insulation between both.  Auxiliary equipment and cables are positioned to simulate normal operation conditions as described in ANSI C 63.4.  The AC power port of the EUT (if available) is connected to a power outlet below the turntable.  Measurement distance is 10 m or 3 m (see ANSI C 63.4) – see test details.  EUT is set into operation. Premeasurement  The turntable rotates from 0° to 315° using 45° steps.  The antenna is polarized vertical and horizontal.  The antenna height changes from 1 m to 3 m.  At each turntable position, antenna polarization and height the analyzer sweeps three times in peak to find the maximum of all emissions. Final measurement  The final measurement is performed for at least six highest peaks according to the requirements of the ANSI C63.4.  Based on antenna and turntable positions at which the peak values are measured the software maximize the peaks by changing turntable position ± 45° and antenna height between 1 and 4 m.  The final measurement is done with quasi-peak detector (as described in ANSI C 63.4).  Final levels, frequency, measuring time, bandwidth, antenna height, antenna polarization, turntable angle, correction factor, margin to the limit and limit are recorded. A plot with the graph of the premeasurement with marked maximum final results and the limit is stored. © CTC advanced GmbH Page 12 of 28

Test report no.: 1-8662/19-01-02-A 7.3 Sequence of testing radiated spurious above 1 GHz Setup  The equipment is set up to simulate normal operation mode as described in the user manual or defined by the manufacturer.  If the EUT is a tabletop system, a 2-axis positioner with 1.5 m height is used.  If the EUT is a floor standing device, it is placed directly on the turn table.  Auxiliary equipment and cables are positioned to simulate normal operation conditions as described in ANSI C 63.4.  The AC power port of the EUT (if available) is connected to a power outlet below the turntable.  Measurement distance is 3 m (see ANSI C 63.4) – see test details.  EUT is set into operation. Premeasurement  The turntable rotates from 0° to 315° using 45° steps.  The antenna is polarized vertical and horizontal.  The antenna height is 1.5 m.  At each turntable position and antenna polarization the analyzer sweeps with positive peak detector to find the maximum of all emissions. Final measurement  The final measurement is performed for at least six highest peaks according to the requirements of the ANSI C63.4.  Based on antenna and turntable positions at which the peak values are measured the software maximizes the peaks by rotating the turntable from 0° to 360°. This measurement is repeated for different EUT-table positions (0° to 150° in 30°-steps) and for both antenna polarizations.  The final measurement is done in the position (turntable, EUT-table and antenna polarization) causing the highest emissions with Peak and RMS detector (as described in ANSI C 63.4).  Final levels, frequency, measuring time, bandwidth, turntable position, EUT-table position, antenna polarization, correction factor, margin to the limit and limit are recorded. A plot with the graph of the premeasurement with marked maximum final results and the limit is stored. © CTC advanced GmbH Page 13 of 28

Test report no.: 1-8662/19-01-02-A 8 Measurement uncertainty Measurement uncertainty Test case Uncertainty Occupied bandwidth ± used RBW Field strength of the fundamental ± 3 dB Field strength of the harmonics and spurious ± 3 dB Receiver spurious emissions and cabinet radiations ± 3 dB Conducted limits ± 2.6 dB © CTC advanced GmbH Page 14 of 28

Test report no.: 1-8662/19-01-02-A 9 Summary of measurement results ☒ No deviations from the technical specifications were ascertained ☐ There were deviations from the technical specifications ascertained This test report is only a partial test report. The content and verdict of the performed test cases ☐ are listed below. TC Identifier Description Verdict Date Remark CFR Part 15 RF-Testing RSS 210 Issue 9 See table! 2019-07-18 -/- RSS Gen Issue 5 Test Temperature Power source specification Test case C NC NA NP Remark conditions conditions clause RSS Gen Issue 5 Occupied bandwidth Nominal Nominal ☒ ☐ ☐ ☐ -/- § 15.225 (a) Field strength of the RSS 210 Issue 9 fundamental Nominal Nominal ☒ ☐ ☐ ☐ -/- § 15.209 Field strength of the & harmonics and Nominal Nominal ☒ ☐ ☐ ☐ -/- § 15.225 (b-d) spurious Receiver spurious § 15.109 emissions and Nominal Nominal ☐ ☐ ☒ ☐ -/- cabinet radiations §15.107 §15.207 Conducted limits Nominal Nominal ☒ ☐ ☐ ☐ -/- Normal & Normal & § 15.225 (a) RSS 210 Issue 9 Frequency tolerance extreme extreme ☒ ☐ ☐ ☐ -/- conditions conditions Note: C Compliant NC Not compliant NA Not applicable NP Not performed 10 Additional comments Reference documents: None Special test descriptions: None Configuration descriptions: None © CTC advanced GmbH Page 15 of 28

Test report no.: 1-8662/19-01-02-A 11 Measurement results 11.1 Occupied bandwidth Measurement: The emission bandwidth (x dB) is defined as the frequency range between two points, one above and one below the carrier frequency, at which the spectral density of the emission is attenuated x dB below the maximum in-band spectral density of the modulated signal. Measurement parameters Detector: Peak Resolution bandwidth: 1 % – 5 % of the occupied bandwidth Video bandwidth: ≥ 3x RBW Trace mode: Max hold Analyser function: 99 % power function Used equipment: See chapter 6.4 B Measurement uncertainty: See chapter 8 Limit: IC for RSP-100 test report coversheet only Result: 99% emission bandwidth 646 kHz © CTC advanced GmbH Page 16 of 28

Test report no.: 1-8662/19-01-02-A Plot: Plot 1: 99 % emission bandwidth * RBW 10 kHz Marker 1 [T1 ] VBW 30 kHz -40.89 dBm Ref -30 dBm Att 10 dB SWT 10 ms 13.560000000 MHz -30 OBW646.000000000 kHz Temp 1 [T1 OBW] 1 -61.29 dBm A -40 13.346000000 MHz 1 PK Temp 2 [T1 OBW] MAXH -50 -64.61 dBm 13.992000000 MHz T1 -60 T2 -70 -80 3DB -90 -100 -110 -120 -130 Center 13.56 MHz 100 kHz/ Span 1 MHz Date: 12.JUL.2019 13:22:34 © CTC advanced GmbH Page 17 of 28

Test report no.: 1-8662/19-01-02-A 11.2 Field strength of the fundamental Measurement: The maximum detected field strength for the carrier signal. Measurement parameters Detector: Quasi peak / peak (worst case) Resolution bandwidth: 120 kHz Video bandwidth: ≥ 3x RBW Trace mode: Max hold Used equipment: See chapter 6.2 A Measurement uncertainty: See chapter 8 Limit: FCC & IC Frequency Field strength Measurement distance (MHz) (µV/m) (m) 13.553 to 13.567 15,848 (84 dBµV/m) 30 Recalculation: According to ANSI C63.10 Frequency Formula Correction value 𝑑nearfield 𝑑𝑙𝑖𝑚𝑖𝑡 FSlimit = FSmax −40 log ( ) − 20log⁡( ) 𝑑𝑚𝑒𝑎𝑠𝑢𝑟𝑒 𝑑𝑛𝑒𝑎𝑟𝑓𝑖𝑒𝑙𝑑 FSlimit is the calculation of field strength at the limit distance, 13.56 MHz expressed in dBµV/m -21.4 from 3m to 30m FSmax is the measured field strength, expressed in dBµV/m dnear field is the λ/2π distance dmeasure is the distance of the measurement point from EUT dlimit is the reference limit distance Result: Field strength of the fundamental Frequency 13.56 MHz Distance @3m @ 30 m Measured / calculated value (PP) 77.1 dBµV/m 55.7 dBµV/m Measured / calculated value (QP) 75.6 dBµV/m 54.2 dBµV/m © CTC advanced GmbH Page 18 of 28

Test report no.: 1-8662/19-01-02-A 11.3 Field strength of the harmonics and spurious Measurement: The maximum detected field strength for the harmonics and spurious. Measurement parameters Quasi peak / average or Detector: peak (worst case – pre-scan) F < 150 kHz: 200 Hz Resolution bandwidth: 150 kHz < F < 30 MHz: 9 kHz 30 MHz < F < 1 GHz: 120 kHz F < 150 kHz: 1 kHz Video bandwidth: 150 kHz < F < 30 MHz: 100 kHz 30 MHz < F < 1 GHz: 300 kHz Trace mode: Max hold Used equipment: See chapter 6.1 A & 6.2 A & 6.4 A+B Measurement uncertainty: See chapter 8 Limit: FCC & IC Frequency Field strength Measurement distance (MHz) (dBµV/m) (m) 0.009 – 0.490 2400/F(kHz) 300 0.490 – 1.705 24000/F(kHz) 30 1.705 – 30 30 (29.5 dBµV/m) 30 30 – 88 100 (40 dBµV/m) 3 88 – 216 150 (43.5 dBµV/m) 3 216 – 960 200 (46 dBµV/m) 3 Note: For a reduced measurement distance, please take a look at the limit line and the ANSI C63.10-2013 sub clause 6.4 radiated emissions from unlicensed wireless devices below 30 MHz. Result: Detected emissions Frequency Resolution bandwidth Detected value Detector (MHz) (kHz) (dBµV/m @ 3m) 13.77 Peak 10 40.26 13.77 QP 9 26.60 27.12 Peak 10 32.70 Between 30 MHz and 1 GHz: See the table below the plot. © CTC advanced GmbH Page 19 of 28

Test report no.: 1-8662/19-01-02-A Plots: Plot 1: 9 kHz – 30 MHz, magnetic emissions 130 dBµV/m 120 110 100 90 80 70 60 50 40 30 20 10 9kHz 100k 1M 10M 30MHz Frequency Plot 2: Spectrum mask (the limits are recalculated according to the ANSI C63.10-2013 sub clause 6.4) © CTC advanced GmbH Page 20 of 28

Test report no.: 1-8662/19-01-02-A Plot 3: 30 MHz – 1 GHz, vertical and horizontal polarization Level in dBµV/m Meas. Frequency QuasiPeak Limit Margin Bandwidth Height Azimuth Corr. Time Pol (MHz) (dBµV/m) (dBµV/m) (dB) (kHz) (cm) (deg) (dB/m) (ms) 41.136 11.54 30.0 18.46 1000 120 144.0 V 171.0 14 78.239 5.27 30.0 24.73 1000 120 144.0 V 49.0 11 94.919 31.58 33.5 1.92 1000 120 103.0 V 275.0 12 257.634 31.29 36.0 4.71 1000 120 98.0 V 293.0 14 366.112 35.44 36.0 0.56 1000 120 244.0 H 285.0 16 474.599 33.36 36.0 2.64 1000 120 200.0 H 261.0 18 960.012 35.66 44.0 8.34 1000 120 100.0 H -8.0 24 © CTC advanced GmbH Page 21 of 28

Test report no.: 1-8662/19-01-02-A 11.4 Conducted limits Measurement: Measurement of the conducted spurious emissions for an intentional radiator that is designed to be connected to the public utility (AC) power line. Measurement parameters Quasi peak / average or Detector: peak (worst case – pre-scan) F < 150 kHz: 200 Hz Resolution bandwidth: F > 150 kHz: 9 kHz F < 150 kHz: 1 kHz Video bandwidth: F > 150 kHz: 100 kHz Trace mode: Max hold Used equipment: See chapter 6.3 A Measurement uncertainty: See chapter 8 Limit: FCC & IC Frequency Quasi-peak Average (MHz) (dBµV/m) (dBµV/m) 0.15 – 0.5 66 to 56* 56 to 46* 0.5 – 5 56 46 5 – 30.0 60 50 Result: Detected emissions Frequency Resolution bandwidth Detector Detected value (MHz) (kHz) See result table below plots! © CTC advanced GmbH Page 22 of 28

Test report no.: 1-8662/19-01-02-A Plots: Plot 1: 150 kHz to 30 MHz, phase line Premeasurement Measurement Average limit class B Quasi peak limit class B Average level Neutral line Quasi peak level 80.0 70.0 60.0 50.0 Amplitude in dBµV 40.0 30.0 20.0 10.0 0 150.0K 1.0M 10.0M 30.0M Frequency in Hz Project ID: 1-8662/19-01-02 Quasi peak Margin Average Margin Frequency Limit QP Limit AV level quasi peak level average MHz dBµV dB dBµV dBµV dB dBµV 0.150111 46.89 19.11 65.994 32.16 23.84 55.997 0.323253 46.88 12.74 59.623 44.15 6.89 51.050 0.569479 31.43 24.57 56.000 27.74 18.26 46.000 0.940678 31.64 24.36 56.000 26.23 19.77 46.000 1.184808 32.12 23.88 56.000 26.31 19.69 46.000 3.593367 33.30 22.70 56.000 25.57 20.43 46.000 4.451399 32.65 23.35 56.000 25.85 20.15 46.000 4.702897 32.32 23.68 56.000 25.91 20.09 46.000 9.193098 33.84 26.16 60.000 28.19 21.81 50.000 13.453709 32.01 27.99 60.000 25.33 24.67 50.000 13.561595 51.44 8.56 60.000 44.46 5.54 50.000 27.118033 32.67 27.33 60.000 27.46 22.54 50.000 © CTC advanced GmbH Page 23 of 28

Test report no.: 1-8662/19-01-02-A Plot 2: 150 kHz to 30 MHz, neutral line Premeasurement Measurement Average limit class B Quasi peak limit class B Average level Phase line Quasi peak level 80.0 70.0 60.0 50.0 Amplitude in dBµV 40.0 30.0 20.0 10.0 0 150.0K 1.0M 10.0M 30.0M Frequency in Hz Project ID: 1-8662/19-01-02 Quasi peak Margin Average Margin Frequency Limit QP Limit AV level quasi peak level average MHz dBµV dB dBµV dBµV dB dBµV 0.174370 43.95 20.80 64.750 31.94 23.37 55.304 0.322277 48.31 11.33 59.648 45.56 5.52 51.078 0.566336 30.79 25.21 56.000 26.50 19.50 46.000 0.942667 32.57 23.43 56.000 27.15 18.85 46.000 1.093057 32.75 23.25 56.000 28.76 17.24 46.000 1.509526 31.28 24.72 56.000 23.81 22.19 46.000 1.601554 31.47 24.53 56.000 23.57 22.43 46.000 8.960744 32.91 27.09 60.000 26.87 23.13 50.000 10.453122 33.03 26.97 60.000 27.30 22.70 50.000 13.461925 31.28 28.72 60.000 24.81 25.19 50.000 13.558680 51.28 8.72 60.000 44.37 5.63 50.000 © CTC advanced GmbH Page 24 of 28

Test report no.: 1-8662/19-01-02-A 11.5 Frequency error Measurement: The maximum detected field strength for the spurious. Measurement parameters Detector: Peak detector Resolution bandwidth: 10 Hz / 100 Hz Video bandwidth: > RBW Trace mode: Max hold Used equipment: See chapter 6.4 A Measurement uncertainty: See chapter 8 Limit: FCC & IC The frequency tolerance of the carrier signal shall be maintained within +/- 0.01% of the operating frequency over a temperature variation of -20 degrees to +50 degrees C at normal supply voltage, and for a variation in the primary supply voltage from 85% to 115% of the rated supply voltage at a temperature of 20 degrees C. (±1.356 kHz) Carrier frequency stability shall be maintained to ±0.01% (±100 ppm) Result: Temperature variation Frequency tolerance Measured frequency Frequency error Conditions Result (MHz) (kHz) 13.55977850 0.22 -20 °C & 100% voltage compliant 13.55978125 0.21 -10 °C & 100% voltage compliant 13.55979837 0.20 0 °C & 100% voltage compliant 13.55982323 0.17 +10 °C & 100% voltage compliant 13.55984538 0.15 +20 °C & 100% voltage compliant 13.55985973 0.14 +30 °C & 100% voltage compliant 13.55986158 0.13 +40 °C & 100% voltage compliant 13.55982933 0.17 +50 °C & 100% voltage compliant Result: Voltage variation Frequency tolerance Measured frequency Frequency error Conditions Result (MHz) (kHz) 13.559866 0.13 +20 °C & 85% voltage* compliant 13.559866 0.13 +20 °C & 115% voltage compliant *85% of the nominal voltage = 6.8V. The DUT stops transmitting when the voltage drops below 7.1V. Tests are made with 7.1V DC. © CTC advanced GmbH Page 25 of 28

Test report no.: 1-8662/19-01-02-A 12 Observations No observations except those reported with the single test cases have been made. Annex A Glossary EUT Equipment under test DUT Device under test UUT Unit under test ETSI European Telecommunications Standards Institute EN European Standard FCC Federal Communications Commission FCC ID Company Identifier at FCC IC Industry Canada PMN Product marketing name HMN Host marketing name HVIN Hardware version identification number FVIN Firmware version identification number EMC Electromagnetic Compatibility HW Hardware SW Software Inv. No. Inventory number S/N or SN Serial number C Compliant NC Not compliant NA Not applicable NP Not performed PP Positive peak QP Quasi peak AVG Average OC Operating channel OCW Operating channel bandwidth OBW Occupied bandwidth OOB Out of band CAC Channel availability check OP Occupancy period NOP Non occupancy period DC Duty cycle PER Packet error rate CW Clean wave MC Modulated carrier WLAN Wireless local area network RLAN Radio local area network OFDM Orthogonal frequency division multiplexing © CTC advanced GmbH Page 26 of 28

Test report no.: 1-8662/19-01-02-A Annex B Document history Version Applied changes Date of release -/- Initial release 2019-07-15 A Editorial changes 2019-07-18 Annex C Accreditation Certificate – D-PL-12076-01-04 first page last page Note: The current certificate annex is published on the website (link see below) of the Accreditation Body DAkkS or may be received by CTC advanced GmbH on request https://www.dakks.de/as/ast/d/D-PL-12076-01-04.pdf © CTC advanced GmbH Page 27 of 28

Test report no.: 1-8662/19-01-02-A Annex D Accreditation Certificate – D-PL-12076-01-05 first page last page Note: The current certificate annex is published on the website (link see below) of the Accreditation Body DAkkS or may be received by CTC advanced GmbH on request https://www.dakks.de/as/ast/d/D-PL-12076-01-05.pdf ################################## END OF TEST REPORT ################################## © CTC advanced GmbH Page 28 of 28


Document Created: 2019-07-18 16:52:54
Document Modified: 2019-07-18 16:52:54
© 2024 FCC.report
This site is not affiliated with or endorsed by the FCC