BlueRadios BR-LE4.0-D2A

TEST REPORT of R&TTE (1999/5/EC) Directive ETSI EN 300 328 V1.8.1: 2012 Product: Brand: Model: Model Difference: Applicant: Address: BT 4.0 Dual Mode Module BlueRadios BR-LE4.0-D2A N/A BlueRadios, Inc. 7173 S. Hanava Street, Suite 600, Englewood, CO/USA Test Performed by: <Lung-Tan LAB> *Address: No. 120, Lane 180, San Ho Tsuen, Hsin Ho Rd. Lung-Tan Hsiang, Tao Yuan County 325, Taiwan *Tel : 886-3-407-1718; Fax: 886-3-407-1738 Report No.: ISL-14LR208E328 Issue Date : 2014/09/10 Test results given in this report apply only to the specific sample(s) tested and are traceable to national or international standard through calibration of the equipment and evaluating measurement uncertainty herein. This report MUST not be used to claim product endorsement by TAF, NEMKO or any agency of the Government. This test report shall not be reproduced except in full, without the written approval of. Page: 1 of 62

-2 of 62- VERIFICATION OF COMPLIANCE Applicant: BlueRadios, Inc. Equipment Under Test: BT 4.0 Dual Mode Module Brand Name: BlueRadios Model Number: BR-LE4.0-D2A Model Different: N/A Date of Test: 2014/09/01 ~ 2014/09/09 Date of EUT Received: 2014/08/30 APPLICABLE STANDARDS STANDARD ETSI EN 300 328 V1.8.1 :2012 TEST RESULT Complied The above equipment was tested by for compliance with the requirements set forth in the European Standard ETSI EN 300 328 V1.8.1: 2012. class I device under R&TTE Directive 1999/5/EC. The results of testing in this report apply to the product/system that was tested only. Other similar equipment will not necessarily produce the same results due to production tolerance and measurement uncertainties. Test By: Date: 2014/09/10 Dino Chen / Engineer Prepared By: Date: 2014/09/10 Elisa Chen / Specialist Approved By: Date: 2014/09/10 Vincent Su / Technical Manager

-3 of 62- Version Version No. Date Description 00 2014/09/10 Initial creation of document

-4 of 62- TABLE OF CONTENTS 1. DESCRIPTION OF EQUIPMENT UNDER TEST (EUT)... 5 2. GENERAL DESCRIPTION OF APPLIED STANDARDS... 6 3. TEST FACILITY... 6 4. BLOCK DIAGRAM OF TEST SETUP... 7 5. FREQUENCY HOPPING EQUIPMENT MEASUREMENT (FHSS)... 12 6. OTHER TYPES OF WIDE BAND MODULATION EQUIPMENT... 39 APPENDIX A PHOTOGRAPHS OF SET UP... 56 APPENDIX B PHOTOGRAPHS OF EUT... 59

-5 of 62-1. DESCRIPTION OF EQUIPMENT UNDER TEST (EUT) General: Product Name: BT 4.0 Dual Mode Module Brand Name: BlueRadios Model Name: BR-LE4.0-D2A Model Difference: N/A Power Supply: 3.0Vdc from host Type of Equipment: Modular Temperature Range: -20 to 55 Simultaneous transmissions: Hardware Version: Software Version: Bluetooth 1Tx, 1Rx: Bluetooth Version No N/A N/A V2.1 + EDR (GFSK + π /4 DQPSK + 8DPSK) V4.0(GFSK) Frequency Range: 2402 2480MHz 2402 2480MHz Channel number: 79 channels 40 channels Modulation type: Transmit Power: (EIRP) Frequency Hopping Spread Spectrum (FHSS) 9.50dBm Dwell Time: <= 0.4s N/A Wide band Modulation 7.40dBm Operating Mode: Point-to-Point Adaptive/ Non-Adaptive Adaptive Adaptive LBT (Listen Before Talk) Occupied Channel Bandwidth Duty Cycle Antenna Beam forming Antenna Designation: Yes Adaptive Frequency Hopping using LBT based DAA Adaptive Frequency Hopping using other forms of DAA (non-lbt based) Short Control Signaling Transmissions Within 2400-2483.5MHz N/A No Type: Chip Antenna, 2dBi max. P/N:ANT8030-2R4-01A The EUT is compliance with Bluetooth V2.1 + EDR and V4.0. Remark: The above DUT's information was declared by manufacturer. Please refer to the specifications or user's manual for more detailed description.

-6 of 62-1.1. DESCRIPTION OF TEST MODES The EUT has been tested under Operating condition. To control the EUT for staying in continuous transmitting and receiving mode is programmed. Bluetooth BDR, EDR1, EDR2: Lowest (2402MHz), Mid (2441MHz) and Highest (2480MHz) mode. Bluetooth LE4.0: Lowest (2402MHz), Mid (2442MHz) and Highest (2480MHz) mode. The worst case of Radiated Spurious Emission was report: Bluetooth BDR mode: Lowest (2402MHz) and Highest (2480MHz) mode. Normal test conditions : Temperature : -20 to 55 Relative humidity: 20 % to 75 % Normal Voltage: this modular is powered from 5.0Vdc from USB host. Extreme temperatures and Power source voltage Refer to section 5.1.1.2 of EN 300328 For tests at extreme temperatures, measurements shall be made over the extremes of the operating temperature ranges as declared by the manufacturer. For tests at extreme voltage, measurements shall be made over the extremes of the power source voltage range as declared by the manufacturer. 2. GENERAL DESCRIPTION OF APPLIED STANDARDS The EUT According to the Specifications, it must comply with the requirements of the following standards: ETSI EN 300 328 V1.8.1 : 2012 Electromagnetic compatibility and Radio spectrum Matters (ERM) ; Wideband transmission systems; Data transmission equipment operating in the 2.4GHz ISM band and using wide band modulation techniques: 3. TEST FACILITY <Lung-Tan LAB> No. 120, Lane 180, San Ho Tsuen, Hsin Ho Rd., Lung-Tan Hsiang, Tao Yuan County 325, Taiwan A fully anechoic chamber was used for the radiated spurious emissions test. TAF Accreditation Lab. Lab number: 0997 NEMKO Laboratory Authorities No.: ELA 113B

-7 of 62-4. BLOCK DIAGRAM OF TEST SETUP 4.1. EUT Configuration Fig. 4-1 Configuration of Tested System EUT+JIG NB Table 4-1 Equipment Used in Tested System Item Equipment Mfr./Brand Model name Series No Data Cable Power Cable 1 NB Lenovo X220 N/A Shield No- Shielding 2 JIG N/A N/A N/A N/A N/A

-8 of 62-4.2. Test Setup for ERP/EIRP Measurement 4.2.1. Step 1. Field Strength Measurement Turntable Absorber EUT 3m Coaxial Cable 1.5m 1.5m 4.2.2. Step 2. SUBSTITUTION METHOD: A Spectrum Analyzer Turntable Absorber 3m Coaxial Cable 1.5m 1.5m SG A Spectrum Analyzer

-9 of 62-4.3. Test Setup for Conducted Measurement Power Meter or SP EUT 4.4. Test Setup for Extreme test Spectrum analyzer / Power meter Temperature Chamber EUT Variable AC or DC power supply 4.5. Test Setup for verifying the adaptivity/receiver blocking of an equipment

-10 of 62-4.6. Measurement Equipment Used: Chamber (1166) EQUIPMENT MFR MODEL SERIAL LAST CAL DUE. TYPE NUMBER NUMBER CAL. Spectrum Analyzer 21(26.5GHz) Agilent N9010A MY52100117 05/08/2014 05/07/2015 Dipole antenna SCHWARZBECK VHAP,30-300 919 12/03/2013 12/02/2015 Dipole antenna SCHWARZBECK UHAP,300-100 0 1195 12/03/2013 12/02/2015 Loop Antenna A.H.SYSTEM SAS-564 294 03/07/2013 03/06/2015 Bilog Antenna Schaffner 9168 9168-495 06/19/2014 06/18/2015 Horn antenna1-18g EM EM-AH-10180 2011071401 09/05/2014 09/04/2015 Horn antenna18-26g Com-power AH-826 081001 05/15/2013 05/14/2015 Horn antenna26-40g Com-power AH-640 100A 01/09/2013 01/08/2015 Preamplifier9-1.3G HP 8447F NA 08/28/2014 08/27/2015 Preamplifier1-26G EM EM01M26G NA 02/20/2014 02/19/2015 Preamplifier26-40G MITEQ JS-26004000-2 7-5A 818471 05/08/2013 05/07/2015 Cable HUBER SUHNER SUCOFLEX10 4A 1166 cable 001 02/19/2014 02/18/2015 Cable HUBER SUHNER SUCOFLEX10 1166 cable 002 02/21/2014 02/20/2015 4A SUCOFLEX HUBER SUHNER Sucoflex 102 27963/2&3742 10/03/2013 10/02/2015 1GHz~40GHz cable 1/2 Signal Generator R&S SMU200A 102330 02/19/2014 02/18/2015 Signal Generator Anritsu MG3692A 20311 10/30/2013 10/29/2014 2.4G Filter Micro-Tronics Brm50702 76 12/27/2013 12/26/2014 Conducted Emission Test Site EQUIPMENT MFR MODEL SERIAL LAST CAL DUE. TYPE NUMBER NUMBER CAL. Power Meter 05 Anritsu ML2495A 1116010 05/08/2014 05/07/2015 Power Sensor 05 Anritsu MA2411B 34NKF50 05/08/2014 05/07/2015 Temperature Chamber KSON THS-B4H100 2287 03/17/2014 03/16/2015 DC Power supply ABM 51850 N/A 08/16/2014 08/15/2015 AC Power supply EXTECH CFC105W NA 12/19/2013 12/18/2014 Attenuator Woken Watt-65m3502 11051601 NA NA Splitter MCLI PS4-199 12465 12/27/2013 12/26/2014 Spectrum analyzer Agilent N9030A MY51360021 05/02/2014 05/01/2015

-11 of 62- Adaptive/ Receiver Blocking Test Site EQUIPMENT MFR MODEL SERIAL LAST CAL DUE. TYPE NUMBER NUMBER CAL. Signal Generator Agilent E4438C MY49071550 04/29/2014 04/28/2015 Spectrum analyzer Agilent N9030A MY51360021 05/02/2014 05/01/2015 AP Router Cisco AIR-RM1252A FTX1220905D G-A-K9 NA NA Direction Couliper Krytar 1821S 1461 NA NA Splitter Mini-Circuits ZN2PD-63-S UU97201111 NA NA Attenuator Woken Watt-65m3502 11051601 NA NA Software Agilent DFS TEST NA NA NA Software Agilent Adaptive TEST NA NA NA Cable Draka NA NA NA NA

-12 of 62-5. Frequency Hopping Equipment Measurement (FHSS) 5.1. ETSI EN 300 328 SUB-CLAUSE 4.3.1.1 RF Output Power This requirement applies to all types of Frequency Hopping equipment 5.1.1. Limit: The maximum RF output power for adaptive Frequency Hopping equipment shall be equal to or less than 20 dbm. The maximum RF output power for non-adaptive Frequency Hopping equipment, shall be declared by the supplier. The maximum RF output power for this equipment shall be equal to or less than the value declared by the supplier. This declared value shall be equal to or less than 20 dbm. This limit shall apply for any combination of power level and intended antenna assembly. 5.1.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.1 of ETSI EN 300 328 for conducted method.

-13 of 62-5.1.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test Mode: BDR Pburst values (value "A" in dbm) antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db TEST CONDITIONS Vmin 4.25 V Temp (-20) C Vmax 5.75 V Temp (25) C Vnom 5 V Vmin 4.25 V Temp (55) C Vmax 5.75 V Limit(EIRP) Measurement uncertainty TRANSMITTER POWER (dbm) Hopping mode P = 8.70 dbm A = 6.70 dbm Reading -20.3 dbm P = 8.70 dbm A = 6.70 dbm Reading -20.3 dbm P = 9.50 dbm A = 7.50 dbm Reading -19.5 dbm P = 8.70 dbm A = 6.70 dbm Reading -20.3 dbm P = 8.70 dbm A = 6.70 dbm Reading -20.3 dbm 20dBm + 0.28dB / - 0.30dB

-14 of 62- Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test Mode: EDR 1M Pburst values (value "A" in dbm) antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db TEST CONDITIONS Vmin 4.25 V Temp (-20) C Vmax 5.75 V Temp (25) C Vnom 5 V Vmin 4.25 V Temp (55) C Vmax 5.75 V Limit(EIRP) Measurement uncertainty TRANSMITTER POWER (dbm) Hopping mode P = 7.40 dbm A = 5.40 dbm Reading -21.6 dbm P = 7.40 dbm A = 5.40 dbm Reading -21.6 dbm P = 7.00 dbm A = 5.00 dbm Reading -22 dbm P = 5.90 dbm A = 3.90 dbm Reading -23.1 dbm P = 5.90 dbm A = 3.90 dbm Reading -23.1 dbm 20dBm + 0.28dB / - 0.30dB

-15 of 62- Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test Mode: EDR 2M Pburst values (value "A" in dbm) antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db TEST CONDITIONS Vmin 4.25 V Temp (-20) C Vmax 5.75 V Temp (25) C Vnom 5 V Vmin 4.25 V Temp (55) C Vmax 5.75 V Limit(EIRP) Measurement uncertainty TRANSMITTER POWER (dbm) Hopping mode P = 7.40 dbm A = 5.40 dbm Reading -21.6 dbm P = 7.40 dbm A = 5.40 dbm Reading -21.6 dbm P = 7.00 dbm A = 5.00 dbm Reading -22 dbm P = 5.90 dbm A = 3.90 dbm Reading -23.1 dbm P = 5.90 dbm A = 3.90 dbm Reading -23.1 dbm 20dBm + 0.28dB / - 0.30dB

-16 of 62-5.2. ETSI EN 300 328 SUB-CLAUSE 4.3.1.2 Duty Cycle, Tx-sequence, Tx-gap These requirements apply to non-adaptive frequency hopping equipment or to adaptive frequency hopping equipment operating in a non-adaptive mode. These requirements do not apply for equipment with a maximum declared RF Output power of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Medical devices requiring reverse compatibility with other medical devices placed on the market when earlier versions of the present document were harmonised, are allowed to have an operating mode in which they do not have to comply with the requirements for Duty Cycle, Tx-sequence and Tx-gap. 5.2.1. Limit: For non-adaptive FHSS equipment, the Duty Cycle shall be equal to or less than the maximum value declared by the supplier. In addition, the maximum Tx-sequence time shall be 5 ms while the minimum Tx-gap time shall be 5 ms. 5.2.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.2 of ETSI EN 300 328 for conducted method. 5.2.3. Test Result: N/A, This is adaptive device.

-17 of 62-5.3. ETSI EN 300 328 SUB-CLAUSE 4.3.1.3 Dwell Time, Minimum Frequency Occupation and Hopping Sequence These requirements apply to all types of frequency hopping equipment 5.3.1. Limit: Non-adaptive frequency hopping systems The accumulated Dwell Time on any hopping frequency shall not be greater than 15 ms within any period of 15 ms multiplied by the minimum number of hopping frequencies (N) that have to be used. Non-adaptive medical devices requiring reverse compatibility with other medical devices placed on the market when earlier versions of the present document were harmonised, are allowed to have an operating mode in which the maximum dwell time is 400 ms. The hopping sequence(s) shall contain at least N hopping frequencies where N is 15 or 15 divided by the minimum Hopping Frequency Separation in MHz, whichever is the greater. The Minimum Frequency Occupation Time shall be equal to one dwell time within a period not exceeding four times the product of the dwell time per hop and the number of hopping frequencies in use. Adaptive frequency hopping systems Adaptive Frequency Hopping systems shall be capable of operating over a minimum of 70 % of the band specified in clause 1. The maximum accumulated dwell time on any hopping frequency shall be 400 ms within any period of 400 ms multiplied by the minimum number of hopping frequencies (N) that have to be used. The hopping sequence(s) shall contain at least N hopping frequencies at all times, where N is 15 or 15 divided by the minimum Hopping Frequency Separation in MHz, whichever is the greater. The Minimum Frequency Occupation Time shall be equal to one dwell time within a period not exceeding four times the product of the dwell time per hop and the number of hopping frequencies in use. Other Requirements Frequency Hopping equipment shall transmit on a minimum of two hopping frequencies. For non-adaptive Frequency Hopping equipment, when not transmitting on a hopping frequency, the equipment has to occupy that frequency for the duration of the typical dwell time. For Adaptive Frequency Hopping systems using LBT based DAA, if a signal is detected during the CCA, these systems may jump immediately to the next frequency in the hopping sequence (see clause 4.3.1.6.1.2 point 2) provided the limit for maximum dwell is respected. 5.3.2. Test Procedure: See Sub-Clause 5.3.4.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.4.2.1 of ETSI EN 300 328 for conducted method.

-18 of 62-5.3.3. Test Result: Dwell Time: Test Mode: Bluetooth BDR Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/04 Packet DH1 Type of packet Maximum dwell time recorded during a single hop (ms) DH1 0.384 DH3 1.635 DH5 2.860

-19 of 62- Packet DH3 Packet DH5

-20 of 62- Minimum Frequency Occupation Type of system: Adaptive Frequency Hopping. 1. The number of hopping channels used is 79 (see next two plots). The nominal frequency of the hopping channels are: 2402+n (MHz), where 0 S n S 78, So the hopping frequencies are from 2402MHz to 2480 MHz which is a 93.4 % of the band2.4 GHz- 2.4835 GHz Test Mode: Bluetooth BDR Ambient temperature: 25 Relative humidity: 65% Test Date: 2014/09/03 2.4 GHz 2.441GHz, Number of hopping frequencies: 39

-21 of 62-2.441 GHz 2.480GHz Number of hopping frequencies: 40

-22 of 62- Hopping sequence 2. Each hopping channel of the hopping sequence is occupied at least once during a period of four times the product of the dwell time per hop and the number of channels (see next plots for channel 39 for reference): The equipment is set in hopping on mode with each type of packet selected. With a spectrum analyzer tuned in one hopping channel, with zero span and sweep time : four times the product of the dwell time measured in 9.5.1 and 79 (number of channels) a single sweep is performed and the number of transmissions in this time period captured. The number of transmissions shall be at least one during this period, for each type of packet. The plots show the results in central channel: 244lMHz. Ambient temperature: 25 Relative humidity: 65% Test Date: 2014/09/03 Packet DH1: Period= 4x0.384x79=121.344ms

-23 of 62- Packet DH3: Period= 4x1.635x79=516.66 ms Packet DH5: Period= 4x2.86x79=903.76ms

-24 of 62-5.4. ETSI EN 300 328 SUB-CLAUSE 4.3.1.4 Hopping Frequency Separation This requirement applies to all types of frequency hopping equipment. 5.4.1. Limit: Non-adaptive frequency hopping systems The minimum Hopping Frequency Separation shall be equal to Occupied Channel Bandwidth (see clause 4.3.1.7) of a single hop, with a minimum separation of 100 khz. Adaptive frequency hopping systems The minimum Hopping Frequency Separation shall be 100 khz. 5.4.2. Test Procedure: See Sub-Clause 5.3.5.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.5.2.1 of ETSI EN 300 328 for conducted method. 5.4.3. Test Result: Ambient temperature: 25 Relative humidity: 65% Test Date: 2014/09/04 Test Mode Frequency Separation (MHz) Result BDR mode 1.000 PASS EDR 2M Mode 1.000 PASS EDR 3Mode 1.000 PASS Channel separation between carries =1.0 MHz Measurement uncertainty: 120 khz

-25 of 62-5.5. ETSI EN 300 328 SUB-CLAUSE 4.3.1.5 Medium Utilisation (MU) factor This requirement does not apply to adaptive equipment unless operating in a non-adaptive mode. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Medical devices requiring reverse compatibility with other medical devices placed on the market when earlier versions of the present document were harmonised, are allowed to have an operating mode in which they have a Medium Utilisation above the limit defined in clause 4.3.1.5.2. 5.5.1. Limit: The maximum Medium Utilisation factor for non-adaptive Frequency Hopping equipment shall be 10 %. The Medium Utilisation (MU) factor is a measure to quantify the amount of resources (Power and Time) used by non-adaptive equipment. The Medium Utilisation factor is defined by the formula: MU = (P/100 mw) DC, where: MU is Medium Utilisation factor in %. P is the RF output power as defined in clause 4.3.1.1.1 expressed in mw. DC is the Duty Cycle as defined in clause 4.3.1.2.1 expressed in %. 5.5.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.3 of ETSI EN 300 328 for conducted method. 5.5.3. Test Result: N/A, this is adaptive device and RF Output power level is less than 10 dbm e.i.r.p.

-26 of 62-5.6. ETSI EN 300 328 SUB-CLAUSE 4.3.1.6 Adaptivity (Adaptive Frequency Hopping) This requirement does not apply to non-adaptive equipment or adaptive equipment operating in a non-adaptive mode providing the equipment complies with the requirements and/or restrictions applicable to non-adaptive equipment. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Adaptive Frequency Hopping equipment is allowed to operate in a non-adaptive mode providing it complies with the requirements applicable to non-adaptive frequency hopping equipment. Adaptive Frequency Hopping equipment is allowed to have Short Control Signalling Transmissions (e.g. ACK/NACK signals, etc.) without sensing the frequency for the presence of other signals. See clause 4.3.1.6.3. Adaptive Frequency Hopping (AFH) equipment uses a Detect And Avoid (DAA) mechanism which allows an equipment to adapt to its environment by identifying frequencies that are being used by other equipment. Adaptive Frequency Hopping systems shall implement either of the DAA mechanisms provided in clauses 4.3.1.6.1 or 4.3.1.6.2. NOTE: Adaptive systems are allowed to switch dynamically between different adaptive modes. 5.6.1. Limit: ETSI EN 300 328 SUB-CLAUSE 4.3.1.6.1 Adaptive Frequency Hopping using LBT based DAA The CCA observation time shall be not less than 0,2 % of the Channel Occupancy Time with a minimum of 20 μs. The Channel Occupancy Time for a given hopping frequency, which starts immediately after a successful CCA, shall be less than 60 ms followed by an Idle Period of minimum 5 % of the Channel Occupancy Time with a minimum of 100 μs. ETSI EN 300 328 SUB-CLAUSE 4.3.1.6.2 Adaptive Frequency Hopping using other forms of DAA (non-lbt based) The Channel Occupancy Time for a given hopping frequency shall be less than 40 ms. For equipment using a dwell time > 40 ms that want to have other transmissions during the same hop (dwell time) an Idle Period (no transmissions) of minimum 5 % of the Channel Occupancy Period with a minimum of 100 μs shall be implemented. After this, the procedure as in step 1 need to be repeated before having new transmissions on this hopping frequency during the same dwell time. ETSI EN 300 328 SUB-CLAUSE 4.3.1.6.3 Short Control Signalling Transmissions Adaptive equipment may or may not have Short Control Signalling Transmissions If implemented, Short Control Signalling Transmissions shall have a maximum duty cycle of 10 % within an observation period of 50 ms or within an observation period equal to the dwell time, whichever is the shorter.

-27 of 62-5.6.2. Test Procedure: See Sub-Clause 5.3.7.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.7.2.1 of ETSI EN 300 328 for conducted method. 5.6.3. Test Result: N/A, the RF Output power level is less than 10 dbm e.i.r.p

-28 of 62-5.7. ETSI EN 300 328 SUB-CLAUSE 4.3.1.7 Occupied Channel Bandwidth This requirement applies to all types of frequency hopping equipment 5.7.1. Limit: The Occupied Channel Bandwidth for each hopping frequency shall fall completely within the band given in clause 1. For non-adaptive Frequency Hopping equipment with e.i.r.p greater than 10 dbm, the Occupied Channel Bandwidth for every occupied hopping frequency shall be equal to or less than the value declared by the supplier. This declared value shall not be greater than 5 MHz. 5.7.2. Test Procedure: See Sub-Clause 5.3.8.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.8.2.1 of ETSI EN 300 328 for conducted method.

-29 of 62-5.7.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 BDR antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db Occupied Channel Bandwidth Channel Low Channel High Occupied Bandwidth (MHz) 0.835 0.845 Frequency Range(MHz) 2401.6000 2480.4400 Limit 2400.0000 MHz 2483.5000 MHz Measurement Uncertainty +/- 120kHz EDR 2M antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db Occupied Channel Bandwidth Channel Low Channel High Occupied Bandwidth (MHz) 1.192 1.196 Frequency Range(MHz) 2401.4200 2480.6400 Limit 2400.0000 MHz 2483.5000 MHz Measurement Uncertainty +/- 120kHz EDR 3M antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 27.00 db Occupied Channel Bandwidth Channel Low Channel High Occupied Bandwidth (MHz) 1.21 1.20 Frequency Range(MHz) 2401.4000 2480.6200 Limit 2400.0000 MHz 2483.5000 MHz Measurement Uncertainty +/- 120kHz

-30 of 62-5.8. ETSI EN 300 328 SUB-CLAUSE 4.3.1.8 Transmitter Unwanted Emissions in the out-of-band Domain This requirement applies to all types of frequency hopping equipment 5.8.1. Limit: The transmitter unwanted emissions in the out-of-band domain but outside the allocated band, shall not exceed the values provided by the mask in figure 1. NOTE: Within the 2 400 MHz to 2 483,5 MHz band, the Out-of-band emissions are fulfilled by compliance with the Occupied Channel Bandwidth requirement in clause 4.3.1.7. Transmit mask 5.8.2. Test Procedure: Conducted test method See Sub-Clause 5.3.9.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.9.2.1 of ETSI EN 300 328 for conducted method. 5.8.3. Test Result: Refer to next page for details.

-31 of 62- Test Mode: Bluetooth BDR Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test condition out of band domin emission 2400 ~ 2400-BW 2400 ~ 2400-2BW 2483.5 ~ 2483.5+BW 2483.5 ~ 2483.5+2BW Temp (-20) C Vmin 4.25 V -16.01-30.11-30.27-40.14 Vmax 5.75 V -16.03-30.14-30.28-40.16 Temp (25) C Vnom 5 V -16.11-30.32-30.57-40.48 Temp (55) C Vmin 4.25 V -16.14-30.58-30.61-40.68 Vmax 5.75 V -16.13-30.56-30.63-40.65 Limit(dBm/MHz) -10-20 -10-20 Test Mode: Bluetooth EDR 1 Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 out of band domin emission Test condition 2400 ~ 2400-BW 2400 ~ 2400-2BW 2483.5 ~ 2483.5+BW 2483.5 ~ 2483.5+2BW Temp (-20) C Vmin 4.25 V -15.98-30.14-30.21-40.12 Vmax 5.75 V -15.97-30.18-30.22-40.15 Temp (25) C Vnom 5 V -16.09-30.34-30.65-40.46 Temp (55) C Vmin 4.25 V -16.04-30.7-30.88-40.57 Vmax 5.75 V -16.07-30.65-30.85-40.55 Limit(dBm/MHz) -10-20 -10-20 Test Mode: Bluetooth EDR 2 Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test condition out of band domin emission 2400 ~ 2400-BW 2400 ~ 2400-2BW 2483.5 ~ 2483.5+BW 2483.5 ~ 2483.5+2BW Temp (-20) C Vmin 4.25 V -16.08-30.25-30.27-40.21 Vmax 5.75 V -16.07-30.24-30.26-40.19 Temp (25) C Vnom 5 V -16.11-30.28-30.66-40.51 Temp (70) C Vmin 4.25 V -16.32-30.37-30.68-40.77 Vmax 5.75 V -16.33-30.39-30.65-40.75 Limit(dBm/MHz) -10-20 -10-20

-32 of 62-5.9. ETSI EN 300 328 SUB-CLAUSE 4.3.1.9 Transmitter Unwanted Emissions in the Spurious Domain This requirement applies to all types of frequency hopping equipment. 5.9.1. Limit: The transmitter unwanted emissions in the spurious domain shall not exceed the values given in table Transmitter limits for Narrowband Spurious emissions Frequency Range Maximum power, e.r.p. ( 1 GHz) e.i.r.p. (> 1 GHz) Bandwidth 30 MHz to 47 MHz -36 dbm 100 khz 47 MHz to 74 MHz -54 dbm 100 khz 74 MHz to 87,5 MHz -36 dbm 100 khz 87,5 MHz to 118 MHz -54 dbm 100 khz 118 MHz to 174 MHz -36 dbm 100 khz 174 MHz to 230 MHz -54 dbm 100 khz 230 MHz to 470 MHz -36 dbm 100 khz 470 MHz to 862 MHz -54 dbm 100 khz 862 MHz to 1 GHz -36 dbm 100 khz 1 GHz to 12,75 GHz -30 dbm 1 MHz 5.9.2. Test Procedure: See Sub-Clause 5.3.10.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.10.2.1 and 5.3.10.2.2 of ETSI EN 300 328 for Conducted Pre-Scan test method. See Sub-Clause 5.3.10.2.2 of ETSI EN 300 328 for final Radiated test method.

-33 of 62-5.9.3. Test Result: Radiated (The Worst Case situation with respect to output power ) Test Mode: Bluetooth BDR, TX CH Low Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 106.63-60.18 0.33-59.85-54.00-5.85 VERTICAL 2 296.75-66.97-1.27-68.24-36.00-32.24 VERTICAL 3 491.72-69.19 3.05-66.14-54.00-12.14 VERTICAL 4 577.08-73.05 4.92-68.13-54.00-14.13 VERTICAL 5 665.35-73.60 6.29-67.31-54.00-13.31 VERTICAL 6 812.79-73.98 8.84-65.14-54.00-11.14 VERTICAL 7 4804.00-49.80 11.44-38.36-30.00-8.36 VERTICAL 1 47.46-64.10 6.14-57.96-54.00-3.96 HORIZONTAL 2 109.54-62.83-2.16-64.99-54.00-10.99 HORIZONTAL 3 222.06-61.05-3.76-64.81-54.00-10.81 HORIZONTAL 4 296.75-67.44-0.55-67.99-36.00-31.99 HORIZONTAL 5 591.63-74.98 5.15-69.83-54.00-15.83 HORIZONTAL 6 816.67-71.74 9.05-62.69-54.00-8.69 HORIZONTAL 7 4804.00-49.45 11.85-37.60-30.00-7.60 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-34 of 62- Test Mode: Bluetooth BDR, TX CH High Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 47.46-66.49 6.15-60.34-54.00-6.34 VERTICAL 2 106.63-61.15 0.33-60.82-54.00-6.82 VERTICAL 3 295.78-64.55-1.28-65.83-36.00-29.83 VERTICAL 4 504.33-68.40 3.30-65.10-54.00-11.10 VERTICAL 5 576.11-72.61 4.90-67.71-54.00-13.71 VERTICAL 6 813.76-75.97 8.87-67.10-54.00-13.10 VERTICAL 7 4960.00-50.75 12.11-38.64-30.00-8.64 VERTICAL 1 47.46-64.55 6.14-58.41-54.00-4.41 HORIZONTAL 2 109.54-62.30-2.16-64.46-54.00-10.46 HORIZONTAL 3 222.06-63.12-3.76-66.88-54.00-12.88 HORIZONTAL 4 296.75-66.05-0.55-66.60-36.00-30.60 HORIZONTAL 5 594.54-75.14 5.18-69.96-54.00-15.96 HORIZONTAL 6 816.67-71.02 9.05-61.97-54.00-7.97 HORIZONTAL 7 4960.00-49.40 12.47-36.93-30.00-6.93 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-35 of 62-5.10. ETSI EN 300 328 SUB-CLAUSE 4.3.1.10 Receiver Spurious Emissions This requirement applies to all types of frequency hopping equipment. 5.10.1. Limit: The spurious emissions of the receiver shall not exceed the values given in table. Frequency Range Spurious emission limits for receivers Maximum power, e.r.p. ( 1 GHz) e.i.r.p. (> 1 GHz) Measurement Bandwidth 30 MHz to 1 GHz -57 dbm 100 khz 1 GHz to 12,75 GHz -47 dbm 1 MHz 5.10.2. Test Procedure: See Sub-Clause 5.3.11.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.11.2.1 and 5.3.11.2.2 of ETSI EN 300 328 for Conducted Pre-Scan test method. See Sub-Clause 5.3.11.2.2 of ETSI EN 300 328 for final Radiated test method.

-36 of 62-5.10.3. Test Result Test Mode: Bluetooth BDR, RX CH Low Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 106.63-65.59 0.33-65.26-57.00-8.26 VERTICAL 2 143.49-67.61-1.30-68.91-57.00-11.91 VERTICAL 3 296.75-68.12-1.27-69.39-57.00-12.39 VERTICAL 4 504.33-68.24 3.30-64.94-57.00-7.94 VERTICAL 5 785.63-73.06 8.06-65.00-57.00-8.00 VERTICAL 6 850.62-78.67 10.19-68.48-57.00-11.48 VERTICAL 7 2036.00-65.68 0.19-65.49-47.00-18.49 VERTICAL 1 47.46-69.40 6.14-63.26-57.00-6.26 HORIZONTAL 2 185.20-62.64-3.49-66.13-57.00-9.13 HORIZONTAL 3 296.75-65.17-0.55-65.72-57.00-8.72 HORIZONTAL 4 455.83-71.40 2.36-69.04-57.00-12.04 HORIZONTAL 5 665.35-78.00 6.27-71.73-57.00-14.73 HORIZONTAL 6 813.76-72.70 8.94-63.76-57.00-6.76 HORIZONTAL 7 3037.00-67.19 3.57-63.62-47.00-16.62 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-37 of 62- Test Mode: Bluetooth BDR, RX CH High Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 106.63-65.09 0.33-64.76-57.00-7.76 VERTICAL 2 296.75-68.63-1.27-69.90-57.00-12.90 VERTICAL 3 491.72-67.57 3.05-64.52-57.00-7.52 VERTICAL 4 577.08-72.22 4.92-67.30-57.00-10.30 VERTICAL 5 794.36-72.91 8.24-64.67-57.00-7.67 VERTICAL 6 866.14-76.59 10.31-66.28-57.00-9.28 VERTICAL 7 1994.00-61.79 0.04-61.75-47.00-14.75 VERTICAL 1 111.48-60.43-2.06-62.49-57.00-5.49 HORIZONTAL 2 223.03-61.68-3.72-65.40-57.00-8.40 HORIZONTAL 3 295.78-65.15-0.59-65.74-57.00-8.74 HORIZONTAL 4 455.83-72.24 2.36-69.88-57.00-12.88 HORIZONTAL 5 593.57-74.97 5.17-69.80-57.00-12.80 HORIZONTAL 6 813.76-73.33 8.94-64.39-57.00-7.39 HORIZONTAL 7 2379.00-66.61 1.55-65.06-47.00-18.06 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-38 of 62-5.11. ETSI EN 300 328 SUB-CLAUSE 4.3.1.11 Receiver Blocking This requirement does not apply to non-adaptive equipment or adaptive equipment operating in a non-adaptive mode. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. 5.11.1. Limit: Adaptive Frequency Hopping equipment shall comply with the requirements defined in clauses 4.3.1.6.1 (LBT based DAA) or 4.3.1.6.2 (non-lbt based DAA) in the presence of a blocking signal with characteristics as provided in table 3. 5.11.2. Test Procedure: See Sub-Clause 5.3.7.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.7.2.1 of ETSI EN 300 328 for conducted method. 5.11.3. Test Result: N/A, the RF Output power level is less than 10 dbm e.i.r.p

-39 of 62-6. Other Types of Wide Band Modulation Equipment 6.1. ETSI EN 300 328 SUB-CLAUSE 4.3.2.1 RF Output Power This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.1.1. Limit: For adaptive equipment using wide band modulations other than FHSS, the maximum RF output power shall be 20 dbm. The maximum RF output power for non-adaptive equipment shall be declared by the supplier and shall not exceed 20 dbm. See clause 5.3.1 m). For non-adaptive equipment using wide band modulations other than FHSS, the maximum RF output power shall be equal to or less than the value declared by the supplier. This limit shall apply for any combination of power level and intended antenna assembly. 6.1.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.1 of ETSI EN 300 328 for conducted method.

-40 of 62-6.1.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/02 Test Mode: BT LE Pburst values (value "A" in dbm) antenna assembly gain "G" in dbi beamforming gain "Y" in db Cable Loss= 2.00 dbi 0.00 db 27.00 db TEST CONDITIONS Temp (-20) C Temp (25) C Temp (55) C Vmin 4.25 V Vmax 5.75 V Vnom 5 V Vmin 4.25 V Vmax 5.75 V Limit(P) Measurement uncertainty Lowest Frequency (2402MHz) TRANSMITTER POWER (dbm) Middle Frequency (2442MHz) Highest Frequency (2480MHz) P 7.40 dbm P 6.90 dbm P 7.10 dbm A 5.40 dbm A 4.90 dbm A 5.10 dbm Reading -21.6 dbm Reading -22.1 dbm Reading -21.9 dbm P 7.40 dbm P 6.90 dbm P 7.10 dbm A 5.40 dbm A 4.90 dbm A 5.10 dbm Reading -21.6 dbm Reading -22.1 dbm Reading -21.9 dbm P 7.00 dbm P 6.90 dbm P 7.00 dbm A 5.00 dbm A 4.90 dbm A 5.00 dbm Reading -22 dbm Reading -22.1 dbm Reading -22 dbm P 5.90 dbm P 5.90 dbm P 5.80 dbm A 3.90 dbm A 3.90 dbm A 3.80 dbm Reading -23.1 dbm Reading -23.1 dbm Reading -23.2 dbm P 5.90 dbm P 5.90 dbm P 5.80 dbm A 3.90 dbm A 3.90 dbm A 3.80 dbm Reading -23.1 dbm Reading -23.1 dbm Reading -23.2 dbm 20dBm + 0.28dB / - 0.30dB

-41 of 62-6.2. ETSI EN 300 328 SUB-CLAUSE 4.3.2.2 Power Spectral Density This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.2.1. Limit: For equipment using wide band modulations other than FHSS, the maximum Power Spectral Density is limited to 10 dbm per MHz. 6.2.2. Test Procedure: See Sub-Clause 5.3.3.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.3.2.1 of ETSI EN 300 328 for conducted method. 6.2.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/02 Test Mode: BT LE measured power density Reading (value "A" in dbm) antenna assembly gain "G" in dbi 2.00 dbi beamforming gain "Y" in db 0.00 db Cable Loss= 0.50 db Maximum Power Spectrum Density =A+G+Y Power Density Measurement TEST CONDITIONS Ch Low dbm/1mhz Ch Mid dbm/1mhz Ch High dbm/1mhz Measured power density Reading Maximum Power Spectrum Density Limit Measurement Uncertainty 0.45-1.01-0.89 2.95 1.49 1.61 10 dbm/1mhz + 1.5dB/ - 1.4dB

-42 of 62-6.3. ETSI EN 300 328 SUB-CLAUSE 4.3.2.3 Duty Cycle, Tx-sequence, Tx-gap These requirements apply to non-adaptive equipment or to adaptive equipment when operating in a non-adaptive mode. The equipment is using wide band modulations other than FHSS. These requirements do not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Medical devices requiring reverse compatibility with other medical devices placed on the market when earlier versions of the present document were harmonised, are allowed to have an operating mode in which they do not have to comply with the requirements for Duty Cycle, Tx-sequence and Tx-gap. 6.3.1. Limit: The Duty Cycle shall be equal to or less than the maximum value declared by the supplier. The maximum Tx-sequence Time and the minimum Tx-gap Time shall be according to the formula below: Maximum Tx-Sequence Time = Minimum Tx-gap Time = M where M is in the range of 3,5 ms to 10 ms. 6.3.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.2 of ETSI EN 300 328 for conducted method. 6.3.3. Test Result: N/A, Output power is less than 10 dbm e.i.r.p.

-43 of 62-6.4. ETSI EN 300 328 SUB-CLAUSE 4.3.2.4 Medium Utilisation (MU) factor This requirement does not apply to adaptive equipment unless operating in a non-adaptive mode. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Medical devices requiring reverse compatibility with other medical devices placed on the market when earlier versions of the present document were harmonised, are allowed to have an operating mode in which they have a Medium Utilisation above the limit defined in clause 4.3.2.4.2. 6.4.1. Limit: For non-adaptive equipment using wide band modulations other than FHSS, the maximum Medium Utilisation factor shall be 10 %. The Medium Utilisation (MU) factor is a measure to quantify the amount of resources (Power and Time) used by non-adaptive equipment. The Medium Utilisation factor is defined by the formula: MU = (P/100 mw) DC, where: MU is Medium Utilisation factor in %. P is the RF output power as defined in clause 4.3.1.1.1 expressed in mw. DC is the Duty Cycle as defined in clause 4.3.1.2.1 expressed in %. 6.4.2. Test Procedure: See Sub-Clause 5.3.2.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.2.2.1.3 of ETSI EN 300 328 for conducted method. 6.4.3. Test Result: N/A, Output power is less than 10 dbm e.i.r.p.

-44 of 62-6.5. ETSI EN 300 328 SUB-CLAUSE 4.3.2.5 Adaptivity (Adaptive Equipment Using Modulations Other Than FHSS) This requirement does not apply to non-adaptive equipment or adaptive equipment operating in a non-adaptive mode providing the equipment complies with the requirements and/or restrictions applicable to non-adaptive equipment. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. Adaptive equipment using modulations other than FHSS is allowed to operate in a non-adaptive mode providing it complies with the requirements applicable to non-adaptive equipment. An adaptive equipment using modulations other than FHSS is equipment that uses a mechanism by which it can adapt to its environment by identifying other transmissions present within its Occupied Channel Bandwidth. Adaptive equipment using modulations other than FHSS shall implement either of the Detect and Avoid mechanisms provided in clauses 4.3.2.5.1 or 4.3.2.5.2. Adaptive systems are allowed to switch dynamically between different adaptive modes. 6.5.1. Limit: ETSI EN 300 328 SUB-CLAUSE 4.3.2.5.1 Non-LBT based Detect and Avoid Channel Occupancy Time shall be less than 40ms. Idle Period (no transmissions) of minimum 5 % of the Channel Occupancy Time with a minimum of 100 μs. ETSI EN 300 328 SUB-CLAUSE 4.3.2.5.2 LBT based Detect and Avoid The present document defines 2 types of adaptive equipment using wide band modulations other than FHSS and that uses an LBT based Detect and Avoid mechanism: Frame Based Equipment and Load Based Equipment Adaptive equipment which is capable of operating as either Load Based Equipment or as Frame Based Equipment is allowed to switch dynamically between these types of operation. ETSI EN 300 328 SUB-CLAUSE 4.3.2.5.2.2.1 Frame Based Equipment Clear Channel Assessment (CCA) observation time which shall be not less than 20 μs. The Channel Occupancy Time shall be in the range 1 ms to 10 ms followed by an Idle Period of at least 5 % of the Channel Occupancy Time used in the equipment for the current Fixed Frame Period.

-45 of 62- ETSI EN 300 328 SUB-CLAUSE 4.3.2.5.2.2.2 Load Based Equipment Clear Channel Assessment (CCA) observation time which shall be not less than 20 μs. If the equipment finds the channel occupied, it shall not transmit on this channel (see note 1). The equipment shall perform an Extended CCA check in which the channel is observed for the duration of a random factor R multiplied by the CCA observation time. R defines the number of clear idle slots resulting in a total Idle Period that needs to be observed before initiation of the transmission. The value of R shall be randomly selected in the range 1 q every time an Extended CCA is required and the value stored in a counter. The value of q is selected by the manufacturer in the range 4 32. This selected value shall be declared by the manufacturer (see clause 5.3.1 d). The counter is decremented every time a CCA slot is considered to be 'unoccupied'. When the counter reaches zero, the equipment may transmit. ; Channel Occupancy Time shall be less than (13/32) q ms, with q is selected by the manufacturer in the range 4 32, after which the device shall perform the Extended CCA. ETSI EN 300 328 SUB-CLAUSE 4.3.2.5.3 Short Control Signaling Transmissions Adaptive equipment may or may not have Short Control Signaling Transmissions If implemented, Short Control Signaling Transmissions of adaptive equipment using wide band modulations other than FHSS shall have a maximum duty cycle of 10 % within an observation period of 50 ms. 6.5.2. Test Procedure: See Sub-Clause 5.3.7.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.7.2.1.3 of ETSI EN 300 328 for conducted method. TL= -70dBm/MHz + 20 Pout e.i.r.p 6.5.3. Test Result: N/A, Output power is less than 10 dbm e.i.r.p.

-46 of 62-6.6. ETSI EN 300 328 SUB-CLAUSE 4.3.2.6 Occupied Channel Bandwidth This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.6.1. Limit: The Occupied Channel Bandwidth shall fall completely within the band given in clause 1. In addition, for non-adaptive systems using wide band modulations other than FHSS and with e.i.r.p greater than 10 dbm, the occupied channel bandwidth shall be less than 20 MHz. 6.6.2. Test Procedure: See Sub-Clause 5.3.8.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.8.2.1 of ETSI EN 300 328 for conducted method. 6.6.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/02 Test Mode: BT LE Occupied Channel Bandwidth Channel Low Channel High Occupied Bandwidth (MHz) 1.23 1.21 Lowest/Highest Frequency (MHz) 2401.344 2480.653 Limit (Operating in the band) 2400~2483.5 MHz 2400~2483.5 MHz Measurement Uncertainty +/- 120kHz

-47 of 62-6.7. ETSI EN 300 328 SUB-CLAUSE 4.3.2.7 Transmitter Unwanted Emissions in the out-of-band Domain This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.7.1. Limit: The transmitter unwanted emissions in the out-of-band domain but outside the allocated band, shall not exceed the values provided by the mask in figure 3. NOTE: Within the 2 400 MHz to 2 483.5 MHz band, the Out-of-band emissions are fulfilled by compliance with the Occupied Channel Bandwidth requirement in clause 4.3.2.6. Transmit mask 6.7.2. Test Procedure: Conducted test method. See Sub-Clause 5.3.9.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.9.2.1 of ETSI EN 300 328 for conducted method.

-48 of 62-6.7.3. Test Result: Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/03 Test Mode: BT LE antenna assembly gain "G" in dbi beamforming gain "Y" in db Cable Loss= 2.0 dbi 0 db 27.0 db Test condition Out of Band Domain Emission 2400 ~ 2400-BW 2400-BW ~ 2400-2BW 2483.5 ~ 2483.5+BW 2483.5+BW ~ 2483.5+2BW Vmin: 4.25 V -16.07-30.37-30.87-40.24 Temp (-20) C Vmax: 5.75 V -16.09-30.35-30.88-40.24 Temp (25) C Vnom: 5.00 V -16.11-30.41-30.98-40.38 Vmin: 4.25 V -16.22-30.48-30.99-40.51 Temp (55) C Vmax: 5.75 V -16.24-30.42-30.98-40.52 Limit(dBm/MHz) -10-20 -10-20

-49 of 62-6.1. ETSI EN 300 328 SUB-CLAUSE 4.3.2.8 Transmitter Unwanted Emissions in the Spurious Domain This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.1.1. Limit: The transmitter unwanted emissions in the spurious domain shall not exceed the values given in table Transmitter limits for Narrowband Spurious emissions Frequency Range Maximum power, e.r.p. ( 1 GHz) e.i.r.p. (> 1 GHz) Measurement Bandwidth 30 MHz to 47 MHz -36 dbm 100 khz 47 MHz to 74 MHz -54 dbm 100 khz 74 MHz to 87,5 MHz -36 dbm 100 khz 87,5 MHz to 118 MHz -54 dbm 100 khz 118 MHz to 174 MHz -36 dbm 100 khz 174 MHz to 230 MHz -54 dbm 100 khz 230 MHz to 470 MHz -36 dbm 100 khz 470 MHz to 862 MHz -54 dbm 100 khz 862 MHz to 1 GHz -36 dbm 100 khz 1 GHz to 12,75 GHz -30 dbm 1 MHz 6.1.2. Test Procedure: See Sub-Clause 5.3.10.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.10.2.1.1 and 5.3.10.2.1.2 of ETSI EN 300 328 for Conducted Pre-Scan test method. See Sub-Clause 5.3.10.2.2 of ETSI EN 300 328 for final Radiated test method.

-50 of 62-6.1.3. Test Result: Radiated Test Mode: LE mode, TX CH Low Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/04 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 47.46-67.49 6.15-61.34-54.00-7.34 VERTICAL 2 106.63-60.80 0.33-60.47-54.00-6.47 VERTICAL 3 296.75-63.58-1.27-64.85-36.00-28.85 VERTICAL 4 504.33-69.16 3.30-65.86-54.00-11.86 VERTICAL 5 576.11-72.93 4.90-68.03-54.00-14.03 VERTICAL 6 813.76-75.77 8.87-66.90-54.00-12.90 VERTICAL 7 4804.00-52.47 11.44-41.03-30.00-11.03 VERTICAL 1 47.46-63.94 6.14-57.80-54.00-3.80 HORIZONTAL 2 109.54-63.56-2.16-65.72-54.00-11.72 HORIZONTAL 3 185.20-61.68-3.49-65.17-54.00-11.17 HORIZONTAL 4 223.03-60.28-3.72-64.00-54.00-10.00 HORIZONTAL 5 296.75-65.81-0.55-66.36-36.00-30.36 HORIZONTAL 6 813.76-71.79 8.94-62.85-54.00-8.85 HORIZONTAL 7 4804.00-47.21 11.85-35.36-30.00-5.36 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-51 of 62- Test Mode: LE mode, TX CH High Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/04 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 48.43-66.59 5.99-60.60-54.00-6.60 VERTICAL 2 106.63-60.28 0.33-59.95-54.00-5.95 VERTICAL 3 296.75-66.21-1.27-67.48-36.00-31.48 VERTICAL 4 504.33-68.37 3.30-65.07-54.00-11.07 VERTICAL 5 665.35-70.96 6.29-64.67-54.00-10.67 VERTICAL 6 866.14-77.34 10.31-67.03-36.00-31.03 VERTICAL 7 4960.00-49.46 12.11-37.35-30.00-7.35 VERTICAL 1 47.46-63.71 6.14-57.57-54.00-3.57 HORIZONTAL 2 110.51-62.98-2.11-65.09-54.00-11.09 HORIZONTAL 3 222.06-58.89-3.76-62.65-54.00-8.65 HORIZONTAL 4 296.75-65.27-0.55-65.82-36.00-29.82 HORIZONTAL 5 663.41-71.87 6.23-65.64-54.00-11.64 HORIZONTAL 6 816.67-74.13 9.05-65.08-54.00-11.08 HORIZONTAL 7 4960.00-46.10 12.47-33.63-30.00-3.63 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-52 of 62-6.2. ETSI EN 300 328 SUB-CLAUSE 4.3.2.9 Receiver Spurious Emissions This requirement applies to all types of equipment using wide band modulations other than FHSS. 6.2.1. Limit: The spurious emissions of the receiver shall not exceed the values given in table Frequency Range Spurious emission limits for receivers Maximum power, e.r.p. ( 1 GHz) e.i.r.p. (> 1 GHz) Measurement Bandwidth 30 MHz to 1 GHz -57 dbm 100 khz 1 GHz to 12,75 GHz -47 dbm 1 MHz 6.2.2. Test Procedure: See Sub-Clause 5.3.11.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.11.2.1 and 5.3.11.2.2 of ETSI EN 300 328 for Conducted Pre-Scan test method. See Sub-Clause 5.3.11.2.2 of ETSI EN 300 328 for final Radiated test method.

-53 of 62-6.2.3. Test Result: Radiated Test Mode: LE mode, RX CH Low Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/04 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 106.63-60.31 0.33-59.98-57.00-2.98 VERTICAL 2 296.75-64.53-1.27-65.80-57.00-8.80 VERTICAL 3 504.33-68.83 3.30-65.53-57.00-8.53 VERTICAL 4 577.08-72.34 4.92-67.42-57.00-10.42 VERTICAL 5 793.39-71.69 8.22-63.47-57.00-6.47 VERTICAL 6 865.17-75.49 10.30-65.19-57.00-8.19 VERTICAL 7 1994.00-61.83 0.04-61.79-47.00-14.79 VERTICAL 1 47.46-68.12 6.14-61.98-57.00-4.98 HORIZONTAL 2 109.54-61.45-2.16-63.61-57.00-6.61 HORIZONTAL 3 223.03-59.90-3.72-63.62-57.00-6.62 HORIZONTAL 4 296.75-65.51-0.55-66.06-57.00-9.06 HORIZONTAL 5 664.38-72.09 6.25-65.84-57.00-8.84 HORIZONTAL 6 813.76-72.58 8.94-63.64-57.00-6.64 HORIZONTAL 7 3261.00-68.67 4.60-64.07-47.00-17.07 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-54 of 62- Test Mode: LE mode, RX CH High Ambient temperature: 25 Relative humidity: 60% Test Date: 2014/09/04 No Freq Reading Aux Level Limit Over Limit Pol MHz dbm db dbm dbm db V/H 1 48.43-67.30 5.99-61.31-57.00-4.31 VERTICAL 2 106.63-60.60 0.33-60.27-57.00-3.27 VERTICAL 3 295.78-64.96-1.28-66.24-57.00-9.24 VERTICAL 4 504.33-69.19 3.30-65.89-57.00-8.89 VERTICAL 5 792.42-70.88 8.20-62.68-57.00-5.68 VERTICAL 6 855.47-77.15 10.23-66.92-57.00-9.92 VERTICAL 7 2806.00-67.87 2.53-65.34-47.00-18.34 VERTICAL 1 47.46-67.00 6.14-60.86-57.00-3.86 HORIZONTAL 2 109.54-61.53-2.16-63.69-57.00-6.69 HORIZONTAL 3 223.03-63.13-3.72-66.85-57.00-9.85 HORIZONTAL 4 295.78-64.78-0.59-65.37-57.00-8.37 HORIZONTAL 5 665.35-71.39 6.27-65.12-57.00-8.12 HORIZONTAL 6 813.76-74.24 8.94-65.30-57.00-8.30 HORIZONTAL 7 2323.00-66.45 1.40-65.05-47.00-18.05 HORIZONTAL Measurement uncertainty 30MHz - 80MHz: 5.04dB 80MHz -1000MHz: 3.76dB 1GHz - 26GHz: 4.45dB Remark: 1. The emission behaviors belong to narrowband spurious emission. 2. Remark '' --- '' means that the emission level is too low to be measured 3. The result basic equation calculation is as follows: 4. ERP/EIRP (dbm) = SG Setting(dBm) + Antenna Gain (db/dbi) Cable loss (db) 5. Measurement Range upto 12.75GHz.

-55 of 62-6.3. ETSI EN 300 328 SUB-CLAUSE 4.3.2.10 Receiver Blocking This requirement does not apply to non-adaptive equipment or adaptive equipment operating in a non-adaptive mode. See also clause 4.3.2.5. In addition, this requirement does not apply for equipment with a maximum declared RF Output power level of less than 10 dbm e.i.r.p. or for equipment when operating in a mode where the RF Output power is less than 10 dbm e.i.r.p. 6.3.1. Limit: Adaptive equipment using wide band modulations other than FHSS, shall comply with the requirements defined in clauses 4.3.2.5.1 (non-lbt based DAA) or 4.3.2.5.2 (LBT based DAA) in the presence of a blocking signal with characteristics as provided in table 6. 6.3.2. Test Procedure: See Sub-Clause 5.3.7.1 of ETSI EN 300 328 for the test conditions See Sub-Clause 5.3.7.2.1 of ETSI EN 300 328 for conducted method. 6.3.3. Test Result: N/A. Output power is less than 10 dbm e.i.r.p.

-56 of 62- APPENDIX 1 PHOTOGRAPHS OF SET UP

-57 of 62- Front of Set up Back of Set up

-58 of 62-

-59 of 62- APPENDIX 2 PHOTOGRAPHS OF EUT

-60 of 62- EUT 1 EUT 2

-61 of 62- EUT 3 EUT 4 BT Antenna

-62 of 62- EUT 5 EUT 6 ~ End of Report ~