RF TEST REPORT. Equipment Under Test (EUT): NOTE: The following sample(s) was/were submitted and identified by the client as

Transcription

1 588 West Jindu Road, Xinqiao, Songjiang, 62 Shanghai, China Telephone: +86 () Fax: +86 () ee.shanghai@sgs.com Page: of 77 Cover Page pplication No.: pplicant: RF TEST REPORT SHEM752849CR Bosch Security Systems Inc FCC ID: ESVEVOLVE5 Equipment Under Test (EUT): NOTE: The following sample(s) was/were submitted and identified by the client as Product Name: Self-powered column speaker system Model No.(EUT): EVOLVE 5 dd Model No.: EVOLVE 5-SB-US, EVOLVE 5-SB-EU, EVOLVE 5-SB-P, EVOLVE 5-SW, EVOLVE 5-TB, EVOLVE 5-TW Standards: FCC PRT 5 Subpart C: 6 Date of Receipt: Date of Test: to Date of Issue: Test Result: Pass* *In the configuration tested, the EUT detailed in this report complied with the standards specified above. Parlam Zhan E&E Section Manager SGS-CSTC The manufacturer should ensure that all products in series production are in conformity with the product sample detailed in this report. If the product in this report is used in any configuration other than that detailed in the report, the manufacturer must ensure the new system complies with all relevant standards. ny mention of SGS International Electrical pprovals or testing done by SGS International Electrical pprovals in connection with, distribution or use of the product described in this report must be approved by SGS International Electrical pprovals in writing. This document is issued by the Company subject to its General Conditions of Service printed overleaf, available on request or accessible at and, for electronic format documents, subject to Terms and Conditions for Electronic Documents at ttention is drawn to the limitation of liability, indemnification and jurisdiction issues defined therein. ny holder of this document is advised that information contained hereon reflects the Company s findings at the time of its intervention only and within the limits of Client s instructions, if any. The Company s sole responsibility is to its Client and this document does not exonerate parties to a transaction from exercising all their rights and obligations under the transaction. documents. This document cannot be reproduced except in full, without prior written approval of the Company. ny unauthorized alteration, forgery or falsification of the content or appearance of this document is unlawful and offenders may be prosecuted to the fullest extent of the law. Unless otherwise stated the results shown in this test report refer only to thesample(s) tested and such sample(s) are retained for 9 days only

2 Page: 2 of 77 Revision Record Version Chapter Date Modifier Remark / / Original uthorized for issue by: Tested By Leon_wu /Project Engineer Date Checked By Parlam Zhan /Reviewer Date

3 Page: 3 of 77 2 Test Summary Test Item FCC Requirement Test method Result ntenna Requirement FCC Part 5, Subpart C Section 5.3/5.247 (c) --- PSS C Power Line Conducted Emission FCC Part 5, Subpart C Section 5.7 NSI C63. (3) Section 6.2 PSS Minimum db Bandwidth FCC Part 5, Subpart C Section (a)() NSI C63. (3) Section PSS Conducted Peak Output Power FCC Part 5, Subpart C Section (b)(3) NSI C63. (3) Section.9..2 PSS Carrier Frequencies Separation FCC Part 5, Subpart C Section (a)() NSI C63. (3) Section PSS Hopping Channel Number FCC Part 5, Subpart C Section (b) NSI C63. (3) Section PSS Dwell Time FCC Part 5, Subpart C Section (a)() NSI C63. (9) Section PSS RF Conducted Spurious Emissions and Band-edge FCC Part 5, Subpart C Section 5.247(d) NSI C63. (3) Section.& PSS Radiated Spurious Emissions and Band-edge FCC Part 5, Subpart C Section 5.9&5.5 NSI C63. (3) Section 6.4&6.5&6.6&6. PSS Note: There are series models mentioned in this report, and they are the similar in electrical and electronic characters. Only the model EVOLVE 5 was tested since their differences were the software version, their naming and color silk.

4 Page: 4 of 77 3 Contents COVER PGE... 2 TEST SUMMRY CONTENTS GENERL INFORMTION CLIENT INFORMTION GENERL DESCRIPTION OF E.U.T TECHNICL SPECIFICTIONS DESCRIPTION OF SUPPORT UNITS DETILS OF TEST MODE TEST LOCTION TEST FCILITY MESUREMENT UNCERTINTY EQUIPMENTS LIST NTENN REQUIREMENT E.U.T. TEST CONDITIONS FREQUENCY HOPPING SYSTEM REQUIREMENT NTENN REQUIREMENT CONDUCTED EMISSIONS ON MINS TERMINLS DB OCCUPIED BNDWIDTH CONDUCTED PEK OUTPUT POWER CRRIER FREQUENCIES SEPRTED HOPPING CHNNEL NUMBER DWELL TIME CONDUCTED SPURIOUS EMISSIONS ND BND EDGE Conducted Spurious Emissions Conducted Band-edge RDITED SPURIOUS EMISSIONS ND BND-EDGE Radiated Spurious Emissions Radiated Band-edge TEST SETUP PHOTOGRPHS EUT CONSTRUCTIONL DETILS Page

5 Page: 5 of 77 4 General Information 4. Client Information pplicant: ddress of pplicant: Manufacturer: ddress of Manufacturer: Factory: ddress of Factory: Bosch Security Systems Inc 3 Perinton Parkway,Fairport,NY,US Bosch Security Systems Inc 3 Perinton Parkway,Fairport,NY,US Speaker Electronic (Jia Shan ) CO,.Ltd No,8,Development,ZoneRoad,Huimin,Subdistrict,Jiashan,Country,Zhejiang 342,P,R,China 4.2 General Description of E.U.T. Product Description: Rated Input: Test Voltage: Fixed product with BT function C -23V 5/6Hz C V 6Hz 4.3 Technical Specifications Operation Frequency: 242MHz-248MHz Bluetooth Version: BT 3. + HS Modulation Type: GFSK, π/4dqpsk,8dpsk Number of Channel: 79 ntenna Type PCB ntenna ntenna Gain.54 dbi 4.4 Description of Support Units The EUT has been tested with associated equipment below. Description Manufacturer Model No. Supplied by Laptop Lenovo ThinkPad Xe SGS BT test board / / SGS Software name Manufacturer Version Supplied By Blue Test3 (For CSR) / 2.5. SGS 4.5 Details of Test Mode Test Mode Hopping disabled mode Hopping enabled mode Description of Test Mode Using test software to control EUT working in continuous transmitting, and select channel and modulation type. Using test software to control EUT working in continuous transmitting, and hopping on status.

6 4.6 Test Location ll tests were performed at: SGS-CSTC Standards Technical Services SGS-CSTC Standards Technical Services E&E Lab 588 West Jindu Road, Xinqiao, Songjiang, 62 Shanghai, China Tel: Fax: No tests were sub-contracted. 4.7 Test Facility Page: 6 of 77 The test facility is recognized, certified, or accredited by the following organizations: CNS (No. CNS L599) CNS has accredited SGS-CSTC Standards Technical Services to ISO/IEC 725:5 General Requirements for the Competence of Testing and Calibration Laboratories (CNS- CL ccreditation Criteria for the Competence of Testing and Calibration Laboratories) for the competence in the field of testing. Industry Canada (IC) IC ssigned Code: 867 The 3m Semi-anechoic chamber of SGS-CSTC Standards Technical Services has been registered by Certification and Engineering Bureau of Industry Canada for radio equipment testing with Registration No.: VCCI (Member No.: 36) The 3m Semi-anechoic chamber and Shielded Room of SGS-CSTC Standards Technical Services has been registered in accordance with the Regulations for Voluntary Control Measures with Registration No.: R-3868, C-4336, T-222, G-83 respectively. 4.8 Measurement Uncertainty No. Parameter Measurement Uncertainty Radio Frequency < ± x -5 2 Total RF power, conducted < ±.5 db 3 RF power density, conducted < ±3 db 4 Spurious emissions, conducted < ±3 db 5 ll emissions, radiated < ±6 db (Below GHz) < ±6 db (bove GHz) 6 Temperature < ± C 7 Humidity < ±5 % 8 DC and low frequency voltages < ±3 %

7 Page: 7 of 77 5 Equipments List Item Test Equipment Manufacturer Model No. Serial No. Cal. Date Cal. Due date Spectrum nalyzer R&S FSP Spectrum nalyzer gilent N9 MY Power meter R&S NRP Power Sensor R&S NRP-Z Signal Generator R&S SMR Signal Generator gilent N582 MY Communication Tester R&S CMW5.2K Switcher Tonscend JS86 JS86-2 / / 9 Splitter nritsu M62 M2265 / / Coupler e-meca 83-S- 9-M / / High-low Temperature Cabinet Suzhou Zhihe TL C Power Stabilizer WOCEN DC Power Supply QJE QJ33SII 3573/4/ EMI Test Receiver R&S ESU ctive Loop ntenna (9kHz to 3MHz) Broadband ntenna (25MHz to 2GHz) Broadband ntenna (25MHz to 3GHz) Horn ntenna ( -8GHz) Horn ntenna ( - 8GHz) Horn ntenna (4-4GHz) Pre-amplifier (9KHz 2GHz) Pre-amplifier ( 26.5GHz) Pre-amplifier (4 4GHz) R&S FMZB Schwarzbeck VULB R&S HL R&S HF Schwarzbeck BBH9D 9D Schwarzbeck BBH 97 BBH LN69 TESEQ Schwarzbeck Schwarzbeck 24 Tunable Notch Filter Wainwright SCU-F8-G4- BZ4-CSS(F) SCU-F84-G35- BZ3-CSS(F) WRCT8./88.-.2/4-5SSK / / 25 High pass Filter FSCW HP 2/ / / 26 EMI test receiver Rohde & Schwarz ESR Line impedance stabilization network Line impedance stabilization network SCHWRZBECK NSLK EMCO 386/

8 Page: 8 of 77 6 ntenna Requirement 6. E.U.T. test conditions Requirements: Operating Environment: Test frequencies: 5.3(e) For intentional radiators, measurements of the variation of the input power or the radiated signal level of the fundamental frequency component of the emission, as appropriate, shall be performed with the supply voltage varied between 85% and 5% of the nominal rated supply voltage. For battery operated equipment, the equipment tests shall be performed using a new battery. Temperature: C Humidity: % RH tmospheric Pressure: kpa ccording to the 5.3(m) Measurements on intentional radiators or receivers, other than TV broadcast receivers, shall be performed and. if required. reported for each band in which the device can be operated with the device operating at the number of frequencies in each band specified in the following table: Frequency range over which device operates Number of frequencies Location in the range of operation MHz or less Middle to MHz 2 near top and near bottom More than MHz 3 near top. near middle and near bottom Pursuant to Part 5.3(c) For swept frequency equipment, measurements shall be made with the frequency sweep stopped at those frequencies chosen for the measurements to be reported. Test frequency is the lowest channel: channel (242MHz), middle channel: 39 channel (244MHz) and highest channel: 78 channel (248MHz) with fixed at channel.

9 Page: 9 of Frequency Hopping System Requirement Test Requirement: Section (a)(), (g), (h) requirement: The system shall hop to channel frequencies that are selected at the system hopping rate from a Pseudorandom ordered list of hopping frequencies. Each frequency must be used equally on the average by each transmitter. The system receivers shall have input bandwidths that match the hopping channel bandwidths of their corresponding transmitters and shall shift frequencies in synchronization with the transmitted signals. Frequency hopping spread spectrum systems are not required to employ all available hopping channels during each transmission. However, the system, consisting of both the transmitter and the receiver, must be designed to comply with all of the regulations in this section should the transmitter be presented with a continuous data (or information) stream. In addition, a system employing short transmission bursts must comply with the definition of a frequency hopping system and must distribute its transmissions over the minimum number of hopping channels specified in this section. The incorporation of intelligence within a frequency hopping spread spectrum system that permits the system to recognize other users within the spectrum band so that it individually and independently chooses and adapts its hop sets to avoid hopping on occupied channels is permitted. The coordination of frequency hopping systems in any other manner for the express purpose of avoiding the simultaneous occupancy of individual hopping frequencies by multiple transmitters is not permitted. Compliance for section 5.247(a)() ccording to Bluetooth Core Specification, the pseudorandom sequence may be generated in a ninestage shift register whose 5th and 9th stage outputs are added in a modulo-two addition stage. nd the result is fed back to the input of the first stage. The sequence begins with the first ONE of 9 consecutive ONEs; i.e. the shift register is initialized with nine ones. Number of shift register stages: 9 Length of pseudo-random sequence: = 5 bits Longest sequence of zeros: 8 (non-inverted signal) n example of Pseudorandom Frequency Hopping Sequence as follow: Each frequency used equally on the average by each transmitter. ccording to Bluetooth Core Specification, Bluetooth receivers are designed to have input and IF bandwidths that match the hopping channel bandwidths of any Bluetooth transmitters and shift frequencies in synchronization with the transmitted signals.

10 Page: of 77 Compliance for section 5.247(g) ccording to Bluetooth Core Specification, the Bluetooth system transmits the packet with the pseudorandom hopping frequency with a continuous data and the short burst transmission from the Bluetooth system is also transmitted under the frequency hopping system with the pseudorandom hopping frequency system. Compliance for section 5.247(h) ccording to Bluetooth Core specification, the Bluetooth system incorporates with an adaptive system to detect other user within the spectrum band so that it individually and independently to avoid hopping on the occupied channels. ccording to the Bluetooth Core specification, the Bluetooth system is designed not have the ability to coordinate with other FHSS System in an effort to avoid the simultaneous occupancy of individual hopping frequencies by multiple transmitter. 6.3 ntenna Requirement Standard requirement: 5.3 requirement: n intentional radiator shall be designed to ensure that no antenna other than that furnished by the responsible party shall be used with the device. The use of a permanently attached antenna or of an antenna that uses a unique coupling to the intentional radiator, the manufacturer may design the unit so that a broken antenna can be replaced by the user, but the use of a standard antenna jack or electrical connector is prohibited (b) (4) requirement: The conducted output power limit specified in paragraph (b) of this section is based on the use of antennas with directional gains that do not exceed 6 dbi. Except as shown in paragraph (c) of this section, if transmitting antennas of directional gain greater than 6 dbi are used, the conducted output power from the intentional radiator shall be reduced below the stated values in paragraphs (b)(), (b)(2), and (b)(3) of this section, as appropriate, by the amount in db that the directional gain of the antenna exceeds 6 dbi. EUT ntenna: The antenna is PCB antenna and no consideration of replacement. The gain of the antenna is.54 dbi.

11 Page: of Conducted Emissions on Mains Terminals Frequency Range: 5 KHz to 3 MHz Limit: Test Setup: Frequency range MHz Quasi-peak Class B Limits: db (µv) verage.5 to.5 66 to to 46.5 to to Note: The limit decreases linearly with the logarithm of the frequency in the range.5 MHz to.5mhz. Note2: The lower limit is applicable at the transition frequency. Test Procedure: ) The mains terminal disturbance voltage was measured with the EUT in a shielded room. 2) The EUT was connected to C power source through a LISN (Line Impedance Stabilization Network) which provides 5Ω/5µH + 5Ω linear impedance. The power cables of all other units of the EUT were connected to a second LISN, which was bonded to the ground reference plane in the same way as the LISN for the unit being measured. multiple socket outlet strip was used to connect multiple power cables to a single LISN provided the rating of the LISN was not exceeded 3) The tabletop EUT was placed upon a non-metallic table.8m above the ground reference plane. nd for floor-standing arrangement, the EUT was placed on the horizontal ground reference plane, but separated from metallic contact with the ground reference plane by.m of insulation. 4) The test was performed with a vertical ground reference plane. The rear of the EUT shall be.4 m from the vertical ground reference plane. The vertical ground reference plane was bonded to the horizontal ground reference plane. The LISN was placed.8 m from the boundary of the unit under test and bonded to a ground reference plane for LISN mounted on top of the ground reference plane. This distance was between the closest points of the LISN and the EUT. The mains lead of EUT excess.8m was folded back and forth parallel to the lead so as to form a horizontal bundle with a length between.3m and.4m. ll other units of the EUT and associated equipment were at least.8 m from the LISN. Remark: Pre-scan was performed with peak detected on all ports, Quasi-peak & average

12 Page: 2 of 77 measurements were performed at the frequencies at which maximum peak emission level were detected. Pretest under all modes; choose the worst case mode (in Middle channel) record on the report. Please see the attached Quasi-peak and verage test results. Test Result: PSS Test Data: Test Mode: Hopping Test Channel: N/ Test Port: C Live Line Item Freq. Read Level LISN Factor Cable Loss Level Limit Line Over Limit Detector (Mark) (MHz) (dbµv) (db) (db) (dbµv) (dbµv) (db) verage QP verage QP verage QP verage QP verage QP verage QP

13 Page: 3 of 77 Test Port: C Neutral Line Item Freq. Read Level LISN Factor Cable Loss Level Limit Line Over Limit Detector (Mark) (MHz) (dbµv) (db) (db) (dbµv) (dbµv) (db) verage QP verage QP verage QP verage QP verage QP verage QP Remark: Level = Read Level + LISN/ISN Factor + Cable Loss.

14 Page: 4 of db Occupied Bandwidth Test Configuration: Test Procedure:. Remove the antenna from the EUT and then connect a low RF cable from the antenna port to the spectrum; 2. Set the spectrum analyzer: Span = approximately 2 to 5 times the OBW, centred on the hopping channel; 3. Set the spectrum analyzer: RBW >= % to 5% of the OBW (set 3 khz). VBW >= RBW. Sweep = uto; Detector = Peak. Trace = Max Hold. 4. Mark the peak frequency and -db points. Test Date: Test Mode Test Frequency(MHz) Bandwidth(kHz) GFSK π/4dqpsk DPSK

15 Page: 5 of 77 Test plot as follows: Test mode: GFSK Test channel: 242 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ] 2.97 db.56 MHz MXH dbm GHz Marker 2 [T ] 2.37 dbm GHz - - D dbm Center 2.42 GHz 3 khz/ Span 3 MHz Test mode: GFSK Test channel: 244 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ] 2.53 db.5 MHz MXH -.23 dbm GHz 2 Marker 2 [T ] 3.3 dbm GHz - - D dbm Center 2.44 GHz 3 khz/ Span 3 MHz

16 Page: 6 of 77 Test mode: GFSK Test channel: 248 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ] -2. db.5 MHz MXH dbm GHz 2 Marker 2 [T ] 3.5 dbm GHz - D dbm Center 2.48 GHz 3 khz/ Span 3 MHz Test mode: π/4dqpsk Test channel: 242 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ].53 db.76 MHz MXH dbm GHz Marker 2 [T ] -.34 dbm GHz - - D -.34 dbm Center 2.42 GHz 3 khz/ Span 3 MHz

17 Page: 7 of 77 Test mode: π/4dqpsk Test channel: 244 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ] -. db.64 MHz MXH dbm GHz Marker 2 [T ].76 dbm GHz - - D dbm Center 2.44 GHz 3 khz/ Span 3 MHz Test mode: π/4dqpsk Test channel: 248 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ].6 db.7 MHz MXH -8. dbm GHz 2 Marker 2 [T ] 2.65 dbm GHz - - D dbm Center 2.48 GHz 3 khz/ Span 3 MHz

18 Page: 8 of 77 Test mode: 8DPSK Test channel: 242 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ] -.9 db.94 MHz MXH dbm GHz Marker 2 [T ] -.38 dbm 2.4 GHz - - D -.38 dbm Center 2.42 GHz 3 khz/ Span 3 MHz Test mode: 8DPSK Test channel: 244 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ].94 db.88 MHz MXH dbm GHz Marker 2 [T ].4 dbm 2.44 GHz - - D dbm Center 2.44 GHz 3 khz/ Span 3 MHz

19 Page: 9 of 77 Test mode: 8DPSK Test channel: 248 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 3 [T ].46 db.88 MHz MXH dbm GHz Marker 2 [T ] 2. dbm GHz - - D -7.8 dbm Center 2.48 GHz 3 khz/ Span 3 MHz

20 Page: of Conducted Peak Output Power Test Configuration:. Remove the antenna from the EUT and then connect a low RF cable from Test Procedure: the antenna port to the spectrum. 2. Set the spectrum analyzer: RBW = 3 MHz, VBW = MHz, Sweep = auto; Detector Function = Peak. 3. Keep the EUT in transmitting at lowest, middle and highest channel individually. Record the max value. Test Limit: Regulation (b)()for frequency hopping systems operating in the MHz band employing at least 75 non-overlapping hopping channels, and all frequency hopping systems in the MHz band: watt. For all other frequency hopping systems in the MHz band:.25 watts. Refer to the result Hopping channel number of this document. The.25 watt (2 dbm) limit applies. Test Data: Test Mode Test Frequency (MHz) Reading Power (dbm) Cable Loss (db) Output Power (dbm) Limit (dbm) Test Result GFSK π/4dqpsk 8DPSK Pass Pass Pass Pass Pass Pass Pass Pass Pass Remark: Output Power=Reading Power + Cable loss

21 Page: 2 of 77 Test plot as follows: Test mode: GFSK Test channel: 242 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms.65 dbm 2.4 GHz MXH Center 2.42 GHz 5 khz/ Span 5 MHz Test mode: GFSK Test channel: 244 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms. dbm GHz MXH Center 2.44 GHz 5 khz/ Span 5 MHz

22 Page: 22 of 77 Test mode: GFSK Test channel: 248 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms 2.88 dbm GHz MXH Center 2.48 GHz 5 khz/ Span 5 MHz Test mode: π/4dqpsk Test channel: 242 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms -.82 dbm GHz MXH Center 2.42 GHz 5 khz/ Span 5 MHz

23 Page: 23 of 77 Test mode: π/4dqpsk Test channel: 244 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms.74 dbm GHz MXH Center 2.44 GHz 5 khz/ Span 5 MHz Test mode: π/4dqpsk Test channel: 248 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms.75 dbm GHz MXH Center 2.48 GHz 5 khz/ Span 5 MHz

24 Page: 24 of 77 Test mode: 8DPSK Test channel: 242 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms -.7 dbm 2.4 GHz MXH Center 2.42 GHz 5 khz/ Span 5 MHz Test mode: 8DPSK Test channel: 244 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms. dbm GHz MXH Center 2.44 GHz 5 khz/ Span 5 MHz

25 Page: 25 of 77 Test mode: 8DPSK Test channel: 248 Ref dbm * tt 3 db * RBW 3 MHz * VBW MHz SWT 5 ms.99 dbm GHz MXH Center 2.48 GHz 5 khz/ Span 5 MHz

26 Page: 26 of Carrier Frequencies Separated Test Configuration: Test Procedure: Limit: ) Remove the antenna from the EUT and then connect a low RF cable from the antenna port to the spectrum. 2) Set the spectrum analyzer: RBW >= % of the span (set 3 khz). VBW >= RBW, Span = 3MHz. Sweep = auto; Detector Function = Peak. Trace = Maxhold. 3) llow the trace to stabilize. Use the marker-delta function to determine the separation between the peaks of the adjacent channels. The limit is specified in one of the subparagraphs of this Section. Submit this plot..25mhz or 2/3 of the db bandwidth (whichever is greater) Test data: Test Mode Test Channel Carrier Frequencies Separated (MHz) Limit Test Result GFSK Middle Channels (Channel 39 & 4). >25 khz or 2/3 of db BW Pass π/4dqpsk Middle Channels (Channel 39 & 4). >25 khz or 2/3 of db BW Pass 8DPSK Middle Channels (Channel 39 & 4).2 >25 khz or 2/3 of db BW Remark:. ccording to the section 7.6, the conducted power measured is less than 25mW and 2/3 of db bandwidth is used for limit. 2. db bandwidth reference Section 7.5 Pass

27 Page: 27 of 77 Test plot as follows: Test mode: GFSK Test channel: Channel 39 & 4 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 2 [T ] -.4 db. MHz -3.3 dbm GHz MXH Center GHz 3 khz/ Span 3 MHz Test mode: π/4dqpsk Test channel: Channel 39 & 4 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 2 [T ].44 db. MHz -.78 dbm GHz MXH Center GHz 3 khz/ Span 3 MHz

28 Page: 28 of 77 Test mode: 8DPSK Test channel: Channel 39 & 4 Ref dbm * tt 3 db * RBW 3 khz * VBW khz SWT 5 ms Delta 2 [T ] -.77 db. MHz dbm GHz MXH Center GHz 3 khz/ Span 3 MHz

29 Page: 29 of Hopping Channel Number Test Configuration: Test Procedure: Limit: ) Remove the antenna from the EUT and then connect a low RF cable from the antenna port to the spectrum. 2) Set the spectrum analyzer: RBW = khz. VBW = 3 khz. Sweep = auto; Detector Function = Peak. Trace = Max hold. 3) llow the trace to stabilize. It may prove necessary to break the span up to sections. in order to clearly show all of the hopping frequencies. The limit is specified in one of the subparagraphs of this Section. 4) Set the spectrum analyzer: start frequency = 24MHz. stop frequency = MHz. Submit the test result graph. t least 5 channels Test Data: Mode Hopping channel numbers Limit Test Result GFSK 79 Pass π/4dqpsk 79 5 Pass 8DPSK 79 Pass

30 Page: 3 of 77 Test plot as follows: Test mode: GFSK Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ] -.6 dbm 2.44 GHz -3.8 dbm GHz MXH Start 2.4 GHz 4.5 MHz/ Stop GHz Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ].58 dbm GHz -.35 dbm GHz MXH Start GHz 4.2 MHz/ Stop GHz

31 Page: 3 of 77 Test mode: π/4dqpsk Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ] -.6 dbm 2.44 GHz -3.8 dbm GHz MXH Start 2.4 GHz 4.5 MHz/ Stop GHz Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ].37 dbm GHz -.32 dbm GHz MXH Start GHz 4.2 MHz/ Stop GHz

32 Page: 32 of 77 Test mode: 8DPSK Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ] -.28 dbm GHz -3.5 dbm GHz MXH Start 2.4 GHz 4.5 MHz/ Stop GHz Ref dbm * tt 3 db * RBW 3 khz * VBW 3 khz SWT 5 ms Marker 2 [T ].62 dbm GHz -.36 dbm GHz MXH Start GHz 4.2 MHz/ Stop GHz

33 Page: 33 of Dwell Time Test Configuration: Test Procedure: ) Remove the antenna from the EUT and then connect a low RF cable from the antenna port to the spectrum. Keep EUT in Hopping transmitting with all kind of modulation. 2) Set spectrum analyzer span =. centered on a hopping channel; 3) Use Emission width * No. of Hopping Channels in 3.6s to determine the dwell time. Limit: Regulation 5.247(a)()(iii) Frequency hopping systems in the MHz band shall use at least 5 channels. The average time of occupancy on any channel shall not be greater than.4 seconds within a period of.4 seconds multiplied by the number of hopping channels employed. Frequency hopping systems may avoid or suppress transmissions on a particular hopping frequency provided that a minimum of 5 channels are used. Test Data: Test Mode Test Frequency Packet Emission Width (ms) Number of Hopping Channel in 3.6s verage Occupancy Time (s) Limit(s) Test Result DH Pass GFSK DH Pass π/4dqpsk 8DPSK 244 DH Pass 2DH Pass 2DH Pass 2DH Pass 3DH Pass 3DH Pass 3DH Pass

34 Page: 34 of 77 Test plot as follows: Test mode:gfsk-dh Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 5 ms Delta 2 [T ].8 db 4. µs.32 dbm.4445 as MXH 2 TRG Center 2.44 GHz 5 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

35 Page: 35 of 77 Test mode:gfsk-dh3 MXH Ref dbm Test channel:244 * tt 3 db 2 RBW MHz * VBW 3 MHz SWT 7 ms Delta 2 [T ] 4. db.659 ms -.85 dbm -. µs TRG Center 2.44 GHz 7 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

36 Page: 36 of 77 Test mode:gfsk-dh5 MXH Ref dbm Test channel:244 2 * tt 3 db RBW MHz * VBW 3 MHz SWT 2 ms Delta 2 [T ] -.94 db 2.94 ms 2.9 dbm 4. µs TRG Center 2.44 GHz.2 ms/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

37 Page: 37 of 77 Test mode: π/4dqpsk -2DH Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 5 ms Delta 2 [T ].6 db 45. µs dbm -5. µs MXH 2 TRG Center 2.44 GHz 5 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

38 Page: 38 of 77 Test mode: π/4dqpsk -2DH3 Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 7 ms Delta 2 [T ] -.27 db.65 ms -. dbm 4. µs MXH 2 TRG Center 2.44 GHz 7 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

39 Page: 39 of 77 Test mode: π/4dqpsk -2DH5 Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 2 ms Delta 2 [T ] -.9 db.74 ms -.24 dbm -8. µs MXH 2 TRG Center 2.44 GHz.2 ms/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

40 Page: 4 of 77 Test mode: 8DPSK -3DH Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 5 ms Delta 2 [T ].88 db 4. µs dbm -5. µs MXH 2 TRG Center 2.44 GHz 5 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

41 Page: 4 of 77 Test mode: 8DPSK -3DH3 Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 7 ms Delta 2 [T ] -.3 db.666 ms -.3 dbm -3. µs MXH 2 TRG Center 2.44 GHz 7 µs/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

42 Page: 42 of 77 Test mode: 8DPSK -3DH5 Test channel:244 Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 2 ms Delta 2 [T ] -.83 db 2.94 ms -.25 dbm -3. µs MXH 2 TRG Center 2.44 GHz.2 ms/ Ref dbm * tt 3 db RBW MHz * VBW 3 MHz SWT 3.6 s * CLRWR SGL Center 2.44 GHz 36 ms/

43 Page: 43 of Conducted Spurious Emissions and Band edge Test Configuration: Test Procedure: Limit: ) Remove the antenna from the EUT and then connect a low RF cable from the antenna port to the spectrum. 2) Set the spectrum analyzer: RBW = KHz. VBW = 3 KHz. Sweep = auto; Detector Function = Peak (Max. hold). (d) In any khz bandwidth outside the frequency band in which the spread spectrum or digitally modulated intentional radiator is operating, the radio frequency power that is produced by the intentional radiator shall be at least db below that in the khz bandwidth within the band that contains the Highest level of the desired power, based on either an RF conducted or a radiated measurement, provided the transmitter demonstrates compliance with the peak conducted power limits.

44 Page: 44 of Conducted Spurious Emissions Test plot as follows: Test mode: GFSK Test channel: 242 3MHz-3GHz: Ref dbm *tt 3 db * RBW khz * VBW 3 khz SWT 3 ms dbm 2.46 GHz MXH - - D dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

45 Page: 45 of 77 Test mode: GFSK Test channel: 244 3MHz-3GHz: Ref dbm *tt 3 db * RBW khz * VBW 3 khz SWT 3 ms 2.8 dbm GHz MXH - - D -7.2 dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -7.2 dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

46 Page: 46 of 77 Test mode: GFSK Test channel: 248 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms 2.87 dbm GHz MXH - - D -7.3 dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -7.3 dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

47 Page: 47 of 77 Test mode: π/4dqpsk Test channel: 242 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms dbm 2.46 GHz MXH - - D dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

48 Page: 48 of 77 Test mode: π/4dqpsk Test channel: 244 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms -.92 dbm GHz MXH - - D -.92 dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -.92 dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

49 Page: 49 of 77 Test mode: π/4dqpsk Test channel: 248 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms.3 dbm GHz MXH - - D -9.7 dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s -36. dbm GHz MXH - - D -9.7 dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

50 Page: 5 of 77 Test mode: 8DPSK Test channel: 242 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms -3. dbm 2.46 GHz MXH - - D -23. dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -23. dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

51 Page: 5 of 77 Test mode: 8DPSK Test channel: 244 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms -.27 dbm GHz MXH - - D -.27 dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -.27 dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

52 Page: 52 of 77 Test mode: 8DPSK Test channel: 248 3MHz-3GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 3 ms.89 dbm GHz MXH - - D -9. dbm Start 3 MHz 297 MHz/ Stop 3 GHz 3GHz-25GHz: Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT 2.2 s dbm GHz MXH - - D -9. dbm Start 3 GHz 2.2 GHz/ Stop 25 GHz

53 Page: 53 of Conducted Band-edge Test plot as follows: Test mode: GFSK Hopping enabled Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.45 dbm 2.45 GHz MXH Marker 2 [T ] dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.68 dbm GHz MXH Marker 2 [T ] dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

54 Page: 54 of 77 Test mode: π/4dqpsk Hopping enabled Ref dbm *tt 3 db * RBW khz * VBW 3 khz SWT ms -.5 dbm 2.45 GHz MXH Marker 2 [T ] dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D -2.5 dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms 2.8 dbm GHz MXH Marker 2 [T ] dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

55 Page: 55 of 77 Test mode: 8DPSK Hopping enabled Ref dbm *tt 3 db * RBW khz * VBW 3 khz SWT ms -.43 dbm GHz MXH Marker 2 [T ] dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Ref dbm *tt 3 db *RBW khz *VBW 3 khz SWT ms.3 dbm GHz MXH Marker 2 [T ] dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

56 Page: 56 of 77 Test mode: GFSK Test channel: Hopping disabled- 242 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms 2.78 dbm GHz MXH Marker 2 [T ] -42. dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Test mode: GFSK Test channel: Hopping disabled- 248 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.28 dbm GHz MXH Marker 2 [T ] -5.5 dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

57 Page: 57 of 77 Test mode: π/4dqpsk Test channel: Hopping disabled- 242 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.5 dbm 2.42 GHz MXH Marker 2 [T ] dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Test mode: π/4dqpsk Test channel: Hopping disabled- 248 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.34 dbm GHz MXH Marker 2 [T ] dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

58 Page: 58 of 77 Test mode: 8DPSK Test channel: Hopping disabled- 242 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.67 dbm GHz MXH Marker 2 [T ] dbm 2.4 GHz Marker 3 [T ] dbm 2.39 GHz - - D dbm Start 2.3 GHz MHz/ Stop 2.4 GHz Test mode: 8DPSK Test channel: Hopping disabled- 248 Ref dbm * tt 3 db * RBW khz * VBW 3 khz SWT ms.3 dbm GHz MXH Marker 2 [T ] -49. dbm GHz Marker 3 [T ] dbm 2.5 GHz - - D dbm Start GHz 7.5 MHz/ Stop 2.55 GHz

59 Page: 59 of Radiated Spurious Emissions and Band-edge Frequency Range: 9KHz to 25GHz Test site/setup: Measurement Distance: 3m Test instrumentation set-up: Frequency Range Detector RBW VBW.9MHz-.9MHz Peak khz 3kHz.9MHz-.9MHz verage khz 3kHz.9MHz-.MHz Quasi-peak khz 3kHz.MHz-.49MHz Peak khz 3kHz.MHz-.49MHz verage khz 3kHz.49MHz -3MHz Quasi-peak khz 3kHz 3MHz-GHz Quasi-peak khz 3kHz bove GHz Sweep=uto 5.9 Limit: Frequency Peak verage RBW=MHz Field strength (microvolt/meter) VBW RBW VBW=Hz Limit (dbuv/m).9mhz-.49mhz 24/F(KHz) 28.5 ~ MHz-.75MHz 24/F(KHz) 73.8 ~63..75MHz-3MHz MHz-88MHz 4. 88MHz-26MHz MHz-96MHz MHz-GHz bove GHz Note: 5.35(b), Unless otherwise specified, the limit on peak radio frequency emissions is db above the maximum permitted average emission limit applicable to the equipment under test. This peak limit applies to the total peak emission level radiated by the device.

60 Page: 6 of 77 Test Configuration: Receive antenna scan height m - 4 m. polarization Vertical / Horizontal Figure. Below 3MHz radiated emissions test configuration Figure 2. 3MHz to GHz radiated emissions test configuration Figure 3. bove GHz radiated emissions test configuration

61 Page: 6 of 77 Test Procedure: ) The procedure used was NSI Standard C63.. The receiver was scanned from 9 KHz to 25GHz.When an emission was found, the table was rotated to produce the maximum signal strength. n initial pre-scan was performed for in peak detection mode using the receiver. The EUT was measured for both the Horizontal and Vertical polarities and performed a pre-test three orthogonal planes. For intentional radiators, measurements of the variation of the input power or the radiated signal level of the fundamental frequency component of the emission, as appropriate, shall be performed with the supply voltage varied between 85% and 5% of the nominal rated supply voltage. The worst case emissions were reported. Test Result: 2) Low noise amplifier was used below GHz, High pass Filter was used above 3GHz. We did not use any amplifier or filter between G and 3GHz. 3) Test were performed for their spatial orthogonal(x, Y, Z), the worst test data (X orthogonal) was submitted. a) For this intentional radiator operates below 25 GHz. the spectrum shall be investigated to the tenth harmonic of the highest fundamental frequency. nd above the third harmonic of this intentional radiator, the disturbance is very low. So the test result only displays to 5rd harmonic. b) s shown in Section, for frequencies above MHz. the above field strength limits are based on average limits. However, the peak field strength of any emission shall not exceed the maximum permitted average limits specified above by more than db under any condition of modulation. 4) No spurious emissions were detected within db of limit below 3MHz. Pass

62 Page: 62 of Radiated Spurious Emissions 3MHz-GHz: Polarization: Horizontal Item Freq. Read ntenna Preamp Cable Result Limit Over Detector Level Factor Factor Loss Level Line Limit (dbµv/m (dbµv/m (Mark) (MHz) (dbµv) (db/m) (db) (db) (db) ) ) QP QP QP QP QP QP

63 Page: 63 of 77 Polarization: Vertical Item Freq. Read ntenna Preamp Cable Result Limit Over Detector Level Factor Factor Loss Level Line Limit (dbµv/m (dbµv/m (Mark) (MHz) (dbµv) (db/m) (db) (db) (db) ) ) QP QP QP QP QP QP Result Level = Read Level + ntenna Factor + Cable loss - Preamp Factor

64 Page: 64 of 77 bove GHz: Lowest Channel(242MHz) Modulation: GFSK Mark Frequency (MHz) Reading (dbuv) Factor (db) Emission (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Middle Channel(244MHz) Modulation: GFSK Frequency Reading Factor Emission Mark (MHz) (dbuv) (db) (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Highest Channel(248MHz) Modulation: GFSK Frequency Reading Factor Emission Mark (MHz) (dbuv) (db) (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Remark: ) Emission = Receiver Reading + Factor 2) Factor = ntenna Factor + Cable Loss + Pre-amplifier Factor. 3) If the Peak value below the V Limit, the V test doesn t perform for this submission.

65 Page: 65 of 77 bove GHz: Lowest Channel(242MHz) Modulation: π/4dqpsk Mark Frequency (MHz) Reading (dbuv) Factor (db) Emission (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Middle Channel(244MHz) Modulation: π/4dqpsk Frequency Reading Factor Emission Mark (MHz) (dbuv) (db) (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Highest Channel(248MHz) Modulation: π/4dqpsk Frequency Reading Factor Emission Mark (MHz) (dbuv) (db) (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Remark: ) Emission = Receiver Reading + Factor 2) Factor = ntenna Factor + Cable Loss + Pre-amplifier Factor. 3) If the Peak value below the V Limit, the V test doesn t perform for this submission.

66 Page: 66 of 77 bove GHz: Lowest Channel(242MHz) Mark Frequency (MHz) Reading (dbuv) Modulation: 8DPSK Factor (db) Emission (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Middle Channel(244MHz) Frequency Reading Mark (MHz) (dbuv) Modulation: 8DPSK Emission (dbuv/m) Factor (db) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Highest Channel(248MHz) Frequency Reading Mark (MHz) (dbuv) Factor (db) Modulation: 8DPSK Emission (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector polarization peak Horizontal peak Horizontal peak Horizontal peak Vertical peak Vertical peak Vertical Remark: ) Emission = Receiver Reading + Factor 2) Factor = ntenna Factor + Cable Loss + Pre-amplifier Factor. 3) If the Peak value below the V Limit, the V test doesn t perform for this submission.

67 Page: 67 of Radiated Band-edge Lowest Channel (242MHz) MK. Frequency (MHz) Reading (dbuv/m) Corrected factor(db) Result (dbuv/m) Modulation: GFSK Limit (dbuv/m) Over Limit (db) Detector Polarization Peak Horizontal Peak Horizontal Peak Horizontal Peak Vertical Peak Vertical Peak Vertical Horizontal Vertical:

68 Page: 68 of 77 Highest Channel (248MHz) Modulation: GFSK MK. Frequency Reading Corrected Result Limit Over Limit (MHz) (dbuv/m) factor(db) (dbuv/m) (dbuv/m) (db) Detector Polarization Peak Horizontal Peak Horizontal Peak Horizontal verage Horizontal verage Horizontal verage Horizontal PK verage

69 Page: 69 of 77 Highest Channel (248MHz) Modulation: GFSK MK. Frequency (MHz) Reading (dbuv/m) Corrected factor(db) Result (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector Polarization Peak Vertical Peak Vertical Peak Vertical verage Vertical verage Vertical verage Vertical PK verage

70 Page: 7 of 77 Highest Channel (242MHz) Modulation: π/4dqpsk MK. Frequency Reading Corrected Result Limit Over Limit (MHz) (dbuv/m) factor(db) (dbuv/m) (dbuv/m) (db) Detector Polarization Peak Horizontal Peak Horizontal Peak Horizontal Peak Vertical Peak Vertical Peak Vertical Horizontal Vertical

71 Highest Channel (248MHz) MK. Frequency (MHz) Reading (dbuv/m) SGS-CSTC Standards Technical Services Corrected factor(db) Result (dbuv/m) Modulation: π/4dqpsk Limit (dbuv/m) Page: 7 of 77 Over Limit (db) Detector Polarization Peak Horizontal Peak Horizontal Peak Horizontal verage Horizontal verage Horizontal verage Horizontal PK verage

72 Page: 72 of 77 Highest Channel (248MHz) Modulation: π/4dqpsk MK. Frequency (MHz) Reading (dbuv/m) Corrected factor(db) Result (dbuv/m) Limit (dbuv/m) Over Limit (db) Detector Polarization Peak Vertical Peak Vertical Peak Vertical verage Vertical verage Vertical verage Vertical PK verage