FCC ID: PQMPL161SC PL161SC

 

Parts kit Instruction The Perkins SmartCap works in conjunction with the Perkins My Engine App, which can be downloaded from Google Play, and the Apple App Store. 21820135 Simply:-

1) Install the App 2) Register a user ID and log in 3) Add your engine to the My engines section via its serial number 4) Enter your engines current application hours 5) Replace your oil filler cap with the Perkins SmartCap 6) Register the Perkins SmartCap, using your devices camera and the data matrix on the top of the SmartCap. Perkins SmartCap communicates with your phone via BlueTooth, enabling you to quickly access useful parts, service and engine based data. The Perkins MyEngine App must be active within the background of your mobile device to enable data transmition to and from the Cloud. Further help is available within the App to assist with installation and Perkins SmartCap use. We recommend that you confirm to receive notifications from both Perkins and third parties. This will enable your local Perkins Distributor to assist you in all your service needs. Additional installation support can be obtained from your local Perkins Distributor, or by contacting myappsupport@perkins.com. FCC Notice This device complies with part 15 of the FCC rules. Operation is subject to the following two conditions:

1. This device may not cause harmful interference, and 2. This device must accept any interference received, including interference that may cause undesired operation. Industry Canada Notice to Users This device complies with Industry Canada license - exempt RSS standard(s). Operation is subject to the following two conditions:

1. This device may not cause interference, and 2. This device must accept any interference received, including interference that may cause undesired operation of the device. Le prsent appareil est conforme aux CNR d'Industrie Canada applicables auxappareils radio exempts de licence. L'exploitation est autorise aux deux conditions suivantes :

(1) l'appareil ne doit pas produire de brouillage, et

(2) l'utilisateur de l'appareil doit accepter tout brouillage radiolectrique subi, mme si le brouillage est susceptible d'en compromettre le fonctionnement. End Issued by Perkins Engines Company Limited 2017, Peterborough PE1 5FQ, England. Proprietary information of Perkins Engines Company Limited 2017, all rights reserved. The information is correct at the time of going to press. This Instruction is for technical information only and cannot be used as a basis for a warranty claim.

 

 

 

 

 

 

 

 

 

 

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Caterpillar Inc. 100 North East Adams Street Peoria, IL 61629 FCC ID: PQMPL161SC Date: July 15, 2019 To Whom It May Concern, We, Caterpillar Inc., are requesting a Class II Permissive Change for the PL161SC

(PQMPL161SC). A summary of the hardware changes that have been implemented on this device are as follows:

Four (4) capacitors in the power supply circuit changed from 100uF to 220uF Power level reduced through a software change Sincerely, _________________________ Michael Caruthers Engineering Senior Manager

(309) 578-8131 Caruthers_Michael_A@cat.com

(Signature) Caterpillar: Confidential Yellow

 

 

Engineering Test Report No. 1901073-02 Measurement of RF Emissions from a Bluetooth Low Energy Transmitter Model No. PL161 SC For P.O. Number Date Tested Test Personnel Test Specification FCC "Code of Federal Regulations" Title 47, Part 15, CATERPILLAR Mossville AC 100 NE Adams Peoria, IL 61629 JBJ 62846 May 16-23, 2019 Richard King Subpart C, Section 15.247 for Digital Modulation Intentional Radiators Operating within The bands 2400-2483.5MHz Innovation, Science, and Economic Development Canada RSS-247 Innovation, Science, and Economic Development Canada RSS-GEN Test Report By:

Requested By:

Approved By:

Richard King EMC Engineer Wes Breedlove CATERPILLAR Mossville AC Raymond J. Klouda Registered Professional Engineer of Illinois - 44894 Engineering Test Report No. 1901073-02 TABLE OF CONTENTS 4. 3.1. 3.2. 3.3. 4.1. 4.2. 4.3. 4.4. 1.1. 1.2. 1.3. 1.4. 1.5. 3.1.1. 3.1.2. 3.1.3. 3.1.4. 3.1.5. PARAGRAPH DESCRIPTION OF CONTENTS PAGE NO. Introduction ................................................................................................................................................... 5 1. Scope of Tests ..................................................................................................................................... 5 Purpose ............................................................................................................................................... 5 Deviations, Additions and Exclusions .................................................................................................. 5 EMC Laboratory Identification ............................................................................................................. 5 Laboratory Conditions.......................................................................................................................... 5 2. Applicable Documents .................................................................................................................................. 5 3. EUT Setup and Operation ............................................................................................................................ 6 General Description ............................................................................................................................. 6 Power Input ................................................................................................................................. 6 Peripheral Equipment ................................................................................................................. 6 Signal Input/Output Leads .......................................................................................................... 6 Grounding ................................................................................................................................... 6 Software ...................................................................................................................................... 6 Operational Mode ................................................................................................................................ 6 EUT Modifications ................................................................................................................................ 7 Test Facility and Test Instrumentation ......................................................................................................... 7 Shielded Enclosure .............................................................................................................................. 7 Test Instrumentation ............................................................................................................................ 7 Calibration Traceability ........................................................................................................................ 7 Measurement Uncertainty ................................................................................................................... 7 Test Procedures ........................................................................................................................................... 8 Powerline Conducted Emissions ......................................................................................................... 8 Requirements .............................................................................................................................. 8 6dB Bandwidth ..................................................................................................................................... 8 Requirements .............................................................................................................................. 8 Procedures .................................................................................................................................. 8 Results ........................................................................................................................................ 8 Peak Conducted Output Power ........................................................................................................... 8 Requirements .............................................................................................................................. 8 Procedures .................................................................................................................................. 8 Results ........................................................................................................................................ 8 PEAK EIRP .......................................................................................................................................... 8 Requirements .............................................................................................................................. 8 Procedures .................................................................................................................................. 8 Results ........................................................................................................................................ 9 Radiated Spurious Emissions Measurements ..................................................................................... 9 Requirements .............................................................................................................................. 9 Procedures .................................................................................................................................. 9 Results ...................................................................................................................................... 11 Band Edge Compliance ..................................................................................................................... 11 Requirement.............................................................................................................................. 11 THIS REPORT SHALL NOT BE REPRODUCED, EXCEPT IN FULL, WITHOUT THE WRITTEN APPROVAL OF ELITE ELECTRONIC ENGINEERING INCORPORATED. 5.5.1. 5.5.2. 5.5.3. 5.2.1. 5.2.2. 5.2.3. 5.4.1. 5.4.2. 5.4.3. 5.3.1. 5.3.2. 5.3.3. 5.1.1. 5.6.1. 5.1. 5.2. 5.4. 5.5. 5.6. 5.3. 5. Page 2 of 76 Engineering Test Report No. 1901073-02 TABLE OF CONTENTS 5.7. 5.6.3. 5.6.2. 5.6.2.1 5.6.2.2 5.7.1. 5.7.2. 5.7.3. PARAGRAPH DESCRIPTION OF CONTENTS PAGE NO. Procedures ................................................................................................................................ 11 Low Band Edge .................................................................................................................... 11 High Band Edge.................................................................................................................... 11 Results ...................................................................................................................................... 12 Power Spectral Density ..................................................................................................................... 12 Requirements ............................................................................................................................ 12 Procedures ................................................................................................................................ 12 Results ...................................................................................................................................... 12 6. Other Test Conditions ................................................................................................................................ 13 Test Personnel and Witnesses .......................................................................................................... 13 Disposition of the EUT ....................................................................................................................... 13 7. Conclusions ................................................................................................................................................ 13 8. Certification................................................................................................................................................. 13 9. Equipment List ............................................................................................................................................ 14 6.1. 6.2. THIS REPORT SHALL NOT BE REPRODUCED, EXCEPT IN FULL, WITHOUT THE WRITTEN APPROVAL OF ELITE ELECTRONIC ENGINEERING INCORPORATED. Page 3 of 76 Engineering Test Report No. 1901073-02 Revision Date 14 June 2019 REVISION HISTORY Description Initial release Page 4 of 76 Engineering Test Report No. 1901073-02 Measurement of RF Emissions from a Bluetooth Low Energy Transmitter, Model No. PL161 SC 1. INTRODUCTION 1.1. Scope of Tests This document represents the results of the series of radio interference measurements performed on a CATERPILLAR Mossville AC Bluetooth Low Energy Transmitter, Model No. PL161 SC (hereinafter referred to as the EUT). The EUT is a digital modulation transmitter. The transmitter was designed to transmit in the 2400-2483.5 MHz band using a Taoglas Antenna Solutions SWLP.2450.12.4.B.02 Patch Antenna with 2.0dBi gain. The EUT was manufactured and submitted for testing by CATERPILLAR Mossville AC located in Peoria, IL. 1.2. Purpose The test series was performed to determine if the EUT meets the conducted RF emission requirements, radiated RF emissions requirements, and additional provisions of the FCC "Code of Federal Regulations" Title 47, Part 15, Subpart C, Sections 15.247 for Intentional Radiators Operating within the 2400-2483.5 MHz band. The test series was also performed to determine if the EUT meets the conducted RF emission requirements, radiated RF emissions requirements, and additional provisions of the Innovation, Science, and Economic Development Canada Radio Standards Specification RSS-Gen Section 8.8 and Innovation, Science, and Economic Development Canada Radio Standards Specification RSS-Gen Section 8.8 and Innovation, Science, and Economic Development Canada Radio Standards Specification RSS-247 for Transmitters. Testing was performed in accordance with ANSI C63.4-2014 and ANSI C63.10-2013. 1.3. Deviations, Additions and Exclusions There were no deviations, additions to, or exclusions from the test specification during this test series. 1.4. EMC Laboratory Identification This series of tests was performed by Elite Electronic Engineering Incorporated of Downers Grove, Illinois. The laboratory is accredited by The American Association for Laboratory Accreditation (A2LA). A2LA Certificate Number: 1786.01. 1.5. Laboratory Conditions The temperature at the time of the test was 23.3oC and the relative humidity was 43%. 2. APPLICABLE DOCUMENTS The following documents of the exact issue designated form part of this document to the extent specified herein:

- Federal Communications Commission "Code of Federal Regulations", Title 47, Part 15, Subpart C, dated 1 October 2019

- ANSI C63.4-2004, "American National Standard for Methods of Measurement of Radio-Noise Emissions from Low-Voltage Electrical and Electronic Equipment in the Range of 9 kHz to 40 GHz"

- FCC Public Notice, DA 00-705, "Filing and Measurement Guidelines for Frequency Hopping Spread Spectrum Systems", Released March 30, 2000 Page 5 of 76 Engineering Test Report No. 1901073-02

- Federal Communications Commission Office of Engineering and Technology Laboratory Division Guidance for Performing Compliance Measurements on Digital Transmission Systems (DTS) Operating Under Section 15.247, April 2, 2019

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Industry Canada Radio Standards Specification, RSS-Gen, General Requirements and Information for the Certification of Radiocommunication Equipment, Issue 1, March 2019 Industry Canada Radio Standards Specification, RSS-247, Digital Transmission Systems

(DTSs), Frequency Hopping Systems (FHSs) and License-Exempt Local Area Network (LE-LAN) Devices, Issue 2, February 2019 3. EUT SETUP AND OPERATION 3.1. General Description The EUT is a CATERPILLAR Mossville AC, Bluetooth Low Energy Transmitter, Model No. PL161 SC. A block diagram of the EUT setup is shown as Figure 1. 3.1.1. Power Input The EUT normally obtains 3.6VDC from an internal TL-2450 tadiran battery. For testing purposes, the battery was removed and short wires were soldered onto the battery leads and a power supply was used to provide 3.6VDC to the EUT. 3.1.2. Peripheral Equipment The following peripheral equipment was submitted with the EUT:

Item Laptop computer Debugger Description HP ProBook Laptop Computer: Running HP SmartRF Studio 7. TI CC Debugger 3.1.3. Signal Input/Output Leads The following interconnect cables were submitted with the EUT:

Item USB Cable Ribbon Cable Description Used to connect the HP laptop computer to the TI CC Debugger Used to connect the TI CC Debugger to the EUT 3.1.4. Grounding The EUT was not grounded during testing. 3.1.5. Software For all tests, the EUT had software loaded from the HP SmartRF Studio 7 program prior to each test. 3.2. Operational Mode The EUT and all peripheral equipment were energized. The EUT was connected to the TI CC Debugger and laptop computer. The TI SmartRF Studio 7 software was used to program the EUT as follows. For the PL161 SC the following transmit frequencies and power levels were used:

- Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm Page 6 of 76 Engineering Test Report No. 1901073-02

- Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

- Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm The TI CC Debugger was disconnected from the EUT during testing. 3.3. EUT Modifications No modifications were required for compliance to the specifications listed in paragraph 1.2. 4. TEST FACILITY AND TEST INSTRUMENTATION 4.1. Shielded Enclosure All tests were performed in a 32ft. x 20ft. x 18ft. hybrid ferrite-tile/anechoic absorber lined test chamber. With the exception of the floor, the reflective surfaces of the shielded chamber are lined with ferrite tiles on the walls and ceiling. Anechoic absorber material is installed over the ferrite tile. The floor of the chamber is used as the ground plane. The chamber complies with ANSI C63.4-2004 for site attenuation. 4.2. Test Instrumentation The test instrumentation and auxiliary equipment used during the tests are listed in Table 9-1. All equipment was calibrated per the instruction manuals supplied by the manufacturer. Conducted and radiated emission measurements were performed with a spectrum analyzer. This receiver allows measurements with the bandwidths and detector functions specified by the FCC. The receiver bandwidth was 120kHz for the 30MHz to 1000MHz radiated emissions data and 1MHz for the 1000MHz to 5000MHz radiated emissions data. 4.3. Calibration Traceability Test equipment is maintained and calibrated on a regular basis. All calibrations are traceable to the National Institute of Standards and Technology (NIST). 4.4. Measurement Uncertainty All measurements are an estimate of their true value. The measurement uncertainty characterizes, with a specified confidence level, the spread of values which may be possible for a given measurement system. Values of Expanded Measurement Uncertainty (95% Confidence)are presented below:

Measurement Type Expanded Measurement Uncertainty Conducted disturbance (mains port) (150 kHz 30 MHz) Radiated disturbance (electric field strength on an open area test site or alternative test site) (30 MHz 1000 MHz) Radiated disturbance (electric field strength on an open area test site or alternative test site) (1 GHz 6 GHz) Radiated disturbance (electric field strength on an open area test site or alternative test site) (6 GHz 18 GHz) 2.7 4.3 3.1 3.2 Page 7 of 76 Engineering Test Report No. 1901073-02 5. TEST PROCEDURES 5.1. Powerline Conducted Emissions 5.1.1. Requirements Since the EUT was powered by internal batteries, no conducted emissions tests were performed. 5.2. 6dB Bandwidth 5.2.1. Requirements Per 15.247(a)(2),the minimum 6dB bandwidth shall be at least 500kHz for all systems using digital modulation techniques. 5.2.2. Procedures The antenna port of the EUT was connected to the Rohde & Schwarz Wireless Test Set. The EUT was allowed to transmit continuously. The transmit channel was set separately to low, middle, and high channels. The resolution bandwidth (RBW) was set to 100kHz, the video bandwidth (VBW) was set to the same as or 3 times greater than the RBW, and the span was set to 3 times the RBW. 5.2.3. Results The plots on pages 20 through 22 show that the minimum 6 dB bandwidth was 871.288kHz which is greater than minimum allowable 6dB bandwidth requirement of 500kHz for systems using digital modulation techniques. The 99% bandwidth was measured to be 1.080MHz. 5.3. Peak Conducted Output Power 5.3.1. Requirements Per section 15.247(b)(3), for systems using digital modulation the maximum peak output conducted power shall not be greater than 1.0W (30dBm). 5.3.2. Procedures The antenna port of the EUT was connected to the Rohde & Schwarz Wireless Test Set. The EUT was set to transmit separately at the low, middle, and high channels. The resolution bandwidth (RBW) was set to greater than the 6dB bandwidth. The testing was in accordance to FCC title 47 part 15 15.247(b), KDB 558074 D01 DTS Meas Guidance and ANSI C63.10. 5.3.3. Results The results are presented on pages 23 through 25. The maximum peak conducted output power from the transmitter was .0005W (-2.7 dBm) which is below the 1 Watt limit. 5.4. PEAK EIRP 5.4.1. Requirements Per section 15.247(b)(3), for systems using digital modulation the maximum peak output conducted power shall not be greater than 1.0W (30dBm). Per section 15.247(b)(4), this limit is based on the use of antennas with directional gains that do not exceed 6dBi. Since the limit allows for a 6dBi antenna gain, the maximum EIRP can be increased by 6dB to 4 Watt (36dBm). 5.4.2. Procedures The EUT was placed on the non-conductive stand and set to transmit. A double ridged waveguide antenna was placed at a test distance of 3 meters from the EUT. The resolution bandwidth (RBW) of the spectrum Page 8 of 76 Engineering Test Report No. 1901073-02 analyzer was set to greater than the 6dB bandwidth. The EUT was maximized for worst case emissions (or maximum output power) at the measuring antenna. The maximum meter reading was recorded. The peak power output was measured for the low, middle and high channels. The equivalent power was determined from the field intensity levels measured at 3 meters using the substitution method. To determine the emission power, a double ridged waveguide antenna was then set in place of the EUT and connected to a calibrated signal generator. The output of the signal generator was adjusted to match the received level at the spectrum analyzer. The signal level was recorded. The reading was then corrected to compensate for cable loss (and antenna gain for all measurements above 1GHz), as required. The peak power output was calculated for low, middle, and high hopping frequencies. The testing was in accordance to FCC title 47 part 15 15.247(b), KDB 558074 D01 DTS Meas Guidance and ANSI C63.10. 5.4.3. Results The results are presented on pages 26 through 28. The maximum EIRP measured from the transmitter was

-18dBm or 0.0000158 W which is below the 4 Watt limit. 5.5. Radiated Spurious Emissions Measurements 5.5.1. Requirements Per section 15.247(d), in any 100kHz 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 20 dB below that in the 100kHz bandwidth within the band that contains the highest level of the desired power, based on either an RF conducted or a radiated emissions measurement. Attenuation below the general limits specified in 15.209(a) is not required. In addition, radiated emissions which fall in the restricted bands, as defined in 15.205(a), must comply with the radiated emission limits specified in 15.209(a). Radiated emissions which fall in the restricted bands, as defined in 15.205(a), must comply with the radiated emission limits specified in 15.209(a). Paragraph 15.209(a) has the following radiated emission limits:

Frequency MHz 0.009-0.490 0.490-1.705 1.705-30.0 30.0-88.0 88.0-216.0 216.0-960.0 Above 960 Field Strength

(microvolts/meter) 2400/F(kHz) 24000/F(kHz) 30 100 150 200 500 Measurement distance

(meters) 300 30 3 3 3 3 3 5.5.2. Procedures Radiated measurements were performed in a 32ft. x 20ft. x 14ft. high shielded enclosure. The shielded enclosure prevents emissions from other sources, such as radio and TV stations from interfering with the measurements. All powerlines and signal lines entering the enclosure pass through filters on the enclosure wall. The powerline filters prevent extraneous signals from entering the enclosure on these leads. Preliminary radiated emissions tests were performed to determine the emission characteristics of the EUT. For the preliminary test, a broadband measuring antenna was positioned at a 3 meter distance from the EUT. The entire frequency range from 30MHz to 25GHz was investigated using a peak detector function. The final emission tests were then manually performed over the frequency range of 30MHz to 25GHz. Page 9 of 76 Engineering Test Report No. 1901073-02 1) For all harmonics not in the restricted bands, the following procedure was used:

a) The field strength of the fundamental was measured using a double ridged waveguide antenna. The waveguide antenna was positioned at a 3 meter distance from the EUT. The EUT was placed on a 1.5 meter high non-conductive stand. A peak detector with a resolution bandwidth of 100 kHz was used on the spectrum analyzer. b) The field strengths of all of the harmonics not in the restricted band were then measured using a double-ridged waveguide antenna. The waveguide antenna was positioned at a 3 meter distance from the EUT. The EUT was placed on a 1.5 meter high non-conductive stand. A peak detector with a resolution bandwidth of 100 kHz was used on the spectrum analyzer. c) To ensure that maximum or worst case emission levels at the fundamental and harmonics were measured, the following steps were taken when measuring the fundamental emissions and the spurious emissions:

i) The EUT was rotated so that all of its sides were exposed to the receiving antenna. ii) Since the measuring antenna is linearly polarized, both horizontal and vertical field components were measured. iii) The measuring antenna was raised and lowered for each antenna polarization to maximize the readings. iv) In instances where it was necessary to use a shortened cable between the measuring antenna and the spectrum analyzer. The measuring antenna was not raised or lowered to ensure maximized readings, instead the EUT was rotated through all axis to ensure the maximum readings were recorded for the EUT. d) All harmonics not in the restricted bands must be at least 20 dB below levels measured at the fundamental. However, attenuation below the general limits specified in 15.209(a) is not required. 2) For all emissions in the restricted bands, the following procedure was used:

a) The field strengths of all emissions below 1 GHz were measured using a bi-log antenna. The bi-log antenna was positioned at a 3 meter distance from the EUT. The EUT was placed on an 80cm high non-conductive stand. A peak detector with a resolution bandwidth of 100 kHz was used on the spectrum analyzer. b) The field strengths of all emissions above 1 GHz were measured using a double-ridged waveguide antenna. The waveguide antenna was positioned at a 3 meter distance from the EUT. The EUT was placed on a 1.5 meter high non-conductive stand. A peak detector with a resolution bandwidth of 1 MHz was used on the spectrum analyzer. c) To ensure that maximum or worst case emission levels were measured, the following steps were taken when taking all measurements:

i) The EUT was rotated so that all of its sides were exposed to the receiving antenna. ii) Since the measuring antenna is linearly polarized, both horizontal and vertical field components were measured. iii) The measuring antenna was raised and lowered for each antenna polarization to maximize the readings. iv) In instances where it was necessary to use a shortened cable between the measuring antenna and the spectrum analyzer. The measuring antenna was not raised or lowered to ensure maximized readings, instead the EUT was rotated through all axis to ensure the maximum readings were recorded for the EUT. d) For all radiated emissions measurements below 1 GHz, if the peak reading is below the limits listed in 15.209(a), no further measurements are required. If however, the peak readings exceed the limits listed in 15.209(a), then the emissions are remeasured using a quasi-peak detector. e) For all radiated emissions measurements above 1 GHz, the peak readings must comply with the Page 10 of 76 Engineering Test Report No. 1901073-02 15.35(b) limits. 15.35(b) states that when average radiated emissions measurements are specified, there also is a limit on the peak level of the radiated emissions. The limit on the peak radio frequency emissions is 20 dB above the maximum permitted average emission limit applicable to the equipment under test. Therefore, all peak readings above 1 GHz must be no greater than 20 dB above the limits specified in 15.209(a). f) Next, for all radiated emissions measurements above 1GHz, the resolution bandwidth was set to 1MHz. The analyzer was set to linear mode with a 10Hz video bandwidth in order to simulate an average detector. An average reading was taken 5.5.3. Results Preliminary radiated emissions plots with the EUT transmitting at Low Frequency, Middle Frequency, and High Frequency are shown on pages 29 through 52. Final radiated emissions data are presented on data pages 53 through 61. As can be seen from the data, all emissions measured from the EUT were within the specification limits. Photographs of the test configuration which yielded the highest, or worst case, radiated emission levels are shown in Figures 3 through 6. 5.6. Band Edge Compliance 5.6.1. Requirement Per section 15.247(d), the emissions at the band edges must be at least 20dB below the highest level measured within the band but attenuation below the general limits listed in 15.209(a) is not required. In addition, the radiated emissions which fall in the restricted band beginning at 2483.5 MHz must meet the general limits of 15.209(a). 5.6.2. Procedures 5.6.2.1 Low Band Edge 1) The output of the EUT was connected to the Rohde & Schwarz Wireless Test Set. 2) The EUT was set to transmit continuously at the channel closest to the low band-edge 3) To determine the band edge compliance, the following spectrum analyzer settings were used:

a. Center frequency = low band-edge frequency. b. Span = Wide enough to capture the peak level of the emission operating on the channel closest to the band-edge, as well as any modulation products which fall outside of the authorized band of operation. c. Resolution bandwidth (RBW) 1% of the span. d. The 'Max-Hold' function was engaged. The analyzer was allowed to scan until the envelope of the transmitter bandwidth was defined. 4) The marker was set on the peak of the in-band emissions. A display line was placed 20dB down from the peak of the in-band emissions. All emissions which fall outside of the authorized band of operation must be below the 20dB down display line. (All emissions to the left of the center frequency (band edge) must be below the display line.) 5.6.2.2 High Band Edge 1) The EUT was set to transmit continuously at the channel closest to the high band-edge 2) A double ridged waveguide was placed 3 meters away from the EUT. The antenna was connected to the input of a spectrum analyzer. 3) The center frequency of the analyzer was set to the high band edge (2483.5MHz) Page 11 of 76 Engineering Test Report No. 1901073-02 4) The resolution bandwidth was set to 1MHz. 5) To ensure that the maximum or worst case emission level was measured, the following steps were taken:

a. The EUT was rotated so that all of its sides were exposed to the receiving antenna. b. Since the measuring antenna is linearly polarized, both horizontal and vertical field c. The measuring antenna was raised and lowered from 1 to 4 meters for each antenna components were measured. polarization to maximize the readings. 6) The highest measured peak reading was recorded. 7) The highest measured average reading was recorded. 5.6.3. Results Pages 62 through 64 show the band edge compliance results. As can be seen from these plots, the conducted emissions at the low end band edge are within the 20 dB down limits. The radiated emissions at the high end band edge are within the general limits. 5.7. Power Spectral Density 5.7.1. Requirements Per section 15.247(d), the peak power spectral density from the intentional radiator shall not be greater than 8 dBm in any 3 kHz band during any time interval of continuous transmission. 5.7.2. Procedures 1) The output of the EUT was connected to the Rohde & Schwarz Wireless Test Set. 2) The EUT was set to transmit separately at the low, middle, and high channels. 3) To determine the power spectral density, the following spectrum analyzer settings were used:

a. b. c. d. e. Center frequency = transmit frequency Resolution bandwidth (RBW) greater than the 20dB bandwidth. Sweep time = auto The peak detector and 'Max-Hold' function was engaged. The analyzer was allowed to scan until the envelope of the transmitter bandwidth was defined. The analyzer's display was plotted using a 'screen dump' utility. 4) The testing was in accordance to FCC title 47 part 15 15.247(b), KDB 558074 D01 DTS Measurement Guidance and ANSI C63.10. 5) To determine the power spectral density, the following spectrum analyzer settings were used:

a. Center frequency = transmit frequency b. Span =1.5times the channel bandwidth c. Resolution bandwidth (RBW) 3kHz d. Video bandwidth (VBW) 3 x RBW e. Sweep time = auto couple f. The analyzer was allowed to scan until the envelope of the transmitter bandwidth was defined. The peak detector and 'Max-Hold' function was engaged. g. The analyzer's display was plotted using a 'screen dump' utility. h. If the measured value exceeds the +8dBm limit, reduce the RBW (no less than 3kHz) and repeat step 7. 5.7.3. Results Pages 65 and 67 show the power spectral density results. As can be seen from the plots, the peak power density is less than 8dBm in a 3kHz band during any time interval of continuous transmission. Page 12 of 76 Engineering Test Report No. 1901073-02 6. OTHER TEST CONDITIONS 6.1. Test Personnel and Witnesses All tests were performed by qualified personnel from Elite Electronic Engineering Incorporated. The test series was witnessed by CATERPILLAR Mossville AC personnel. 6.2. Disposition of the EUT The EUT and all associated equipment were returned to CATERPILLAR Mossville AC upon completion of the tests. 7. CONCLUSIONS It was determined that the CATERPILLAR Mossville AC Bluetooth Low Energy Transmitter, Part No. PL161 SC and PL161 SC did fully meet the conducted and radiated emission requirements of the FCC "Code of Federal Regulations" Title 47, Part 15, Subpart B, Sections 15.107 and Subpart C, Sections 15.207 and 15.247 for Intentional Radiators Operating within the 2400-2483.5 MHz band, when tested per ANSI C63.4-

2004 and ANSI C63.10-2013. It was also determined that the CATERPILLAR Mossville AC Bluetooth Low Energy Transmitter, Part No. PL161 SC and PL161 SC, did fully meet the conducted and radiated RF emission requirements of the Innovation, Science, and Economic Development Canada Radio Standards Specification, RSS-Gen, Section 8.8 and the Innovation, Science, and Economic Development Canada Radio Standards Specification RSS-

Gen Section 8.8 and Radio Standards Specification RSS-247 for transmitters, when tested per ANSI C63.4-

2004 and ANSI C63.10-2013. 8. CERTIFICATION Elite Electronic Engineering Incorporated certifies that the information contained in this report was obtained under conditions which meet or exceed those specified in the test specifications. The data presented in this test report pertains to the EUT at the test date CATERPILLAR Mossville AC personnel. Any electrical or mechanical modification made to the EUT subsequent to the specified test date will serve to invalidate the data and void this certification. This report must not be used to claim product certification, approval, or endorsement by NVLAP, NIST or any agency of the Federal Government. Page 13 of 76 Engineering Test Report No. 1901073-02 9. EQUIPMENT LIST Table 9-1 Equipment List Eq ID Equipment Description Manufacturer Model No. Serial No. Frequency Range Cal Date Due Date APW0 PREAMPLIFIER PLANAR ELECTRONICS PE2-30-20G20R6G PL2926/0646 20GHZ-26.5GHZ 4/8/2019 4/8/2020 APW11 PREAMPLIFIER COMPUTER SIGNAL GENERATOR PMI ELITE AGILENT PE2-35-120-5R0-10-

12-SFF WORKSTATION PL11685/1241 1GHZ-20GHZ 4/8/2019 4/8/2020 N/A E4438C MY42081749 250KHZ-6GHZ 2/28/2019 2/28/2020 OSP-B157 OSP MODULE ROHDE & SCHWARZ OSP-B157 OSP120 BASE UNIT PSG ANALOG SIGNAL GENERATOR STANDARD GAIN HORN ANTENNA BILOG ANTENNA DOUBLE RIDGED WAVEGUIDE ANTENNA DOUBLE RIDGED WAVEGUIDE ANTENNA EMI ANALYZER EMI ANALYZER 24VDC POWER SUPPLY ADAPTER HIGH PASS FILTER ROHDE & SCHWARZ AGILENT NARDA TESEQ ETS LINDGREN ETS LINDGREN ROHDE & SCHWARZ ROHDE & SCHWARZ P-TRANS HEWLETT PACKARD K&L MICROWAVE OSP120 E8257D 638 6112D 3117 3117 ESW44 ESW44 FS-32024-1M K281C,012 11SH10-

4800/X20000 100867 101246

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10/23/2018 10/23/2019 10/23/2018 10/23/2019 US46461202 250KHZ-50GHZ 8/31/2018 8/31/2019

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46660 66657 66659 101533 101591 001 09407 001 18-26.5GHZ NOTE 1 20-2000GHZ 9/5/2018 9/5/2019 1GHZ-18GHZ 5/31/2018 5/31/2020 1GHZ-18GHZ 3/22/2018 3/22/2020 10HZ-44GHZ 2HZ-44GHZ 18-27VDC 18-26.5GHZ 12/5/2018 12/5/2019 2/21/2019 2/21/2020 NOTE 1 NOTE 1 4.8-20GHZ 9/12/2017 9/12/2019 I/O: Initial Only N/A: Not Applicable Note 1: For the purpose of this test, the equipment was calibrated over the specified frequency range, pulse rate, or modulation prior to the test or monitored by a calibrated instrument. CDX8 GRE2 GSFA GSFB GSG0 NHG1 NTA4 NWQ0 NWQ2 RBG0 RBG2 SES0 XOB2 XPR0 Page 14 of 76 Engineering Test Report No. 1901073-02 Anechoic Ferrite Chamber DUT e t e r s 3 m Receive Antenna Hpib cbl Computer Printer Turn Table & Mast Controller Spectrum Analyzer FIGURE 1 BLOCKDIAGRAM OF TEST SETUP Page 15 of 76 Anechoic Ferrite Chamber Engineering Test Report No. 1901073-02 DUT 3 m eters or 1 m eter QP Adaptor Spectrum Analyzer Attenuator Switch Pre-Amp Pre-Selector Receive Antenna Page 16 of 76 Engineering Test Report No. 1901073-02 Figure 2 EUT Page 17 of 76 Engineering Test Report No. 1901073-02 Figure 3 Test Setup for Radiated Emissions, 30MHz to 1GHz Horizontal Polarization Test Setup for Radiated Emissions, 30MHz to 1GHz Vertical Polarization Page 18 of 76 Engineering Test Report No. 1901073-02 Figure 4 Test Setup for Radiated Emissions, 30MHz to 1GHz Horizontal Polarization Test Setup for Radiated Emissions, 30MHz to 1GHz Vertical Polarization Page 19 of 76 Engineering Test Report No. 1901073-02 0

-10

-20

-30

-40

-50 m B d n i l e v e L 792.080 kHz 2400 2400.5 2401 2401.5 2402 2402.5 2403 2403.5 2404 Frequency in MHz FCC15.2476dBBandwidth MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: 6dB bandwidth = 792.080kHz

: Wireless Test Set Page 20 of 76 Engineering Test Report No. 1901073-02 0

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-20

-30

-40

-50 m B d n i l e v e L 871.288 kHz 2440 2440.5 2441 2441.5 2442 2442.5 2443 2443.5 2444 Frequency in MHz FCC15.2476dBBandwidth MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: 6dB bandwidth = 871.288kHz

: Wireless Test Set Page 21 of 76 Engineering Test Report No. 1901073-02 0

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-50 m B d n i l e v e L 831.684 kHz 2478 2478.5 2479 2479.5 2480 2480.5 2481 2481.5 2482 Frequency in MHz FCC15.2476dBBandwidth MANUFACTURER MODEL NUMBER SERIAL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

:

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: 6dB bandwidth = 831.684kHz

: Wireless Test Set Page 22 of 76 Engineering Test Report No. 1901073-02 25 20 10 0

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-20 m B d n i l e v e L 2400.5 2401 2401.5 2402 Frequency in MHz 2402.5 2403 2403.5 Connector 1 Peak Connector 1 Result DUT Frequency

(MHz) 2402.000000 Peak Power

(dBm) Limit Max

(dBm) Result

-3.3 30.0 PASS FCC15.247PeakConductedPower MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: Power = -3.3 dBm

: Wireless Test Set Page 23 of 76 Engineering Test Report No. 1901073-02 25 20 10 0

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-20 m B d n i l e v e L 2440.5 2441 2441.5 2442 Frequency in MHz 2442.5 2443 2443.5 Connector 1 Peak Connector 1 Result DUT Frequency

(MHz) 2442.000000 Peak Power

(dBm) Limit Max

(dBm) Result

-2.8 30.0 PASS FCC15.247PeakConductedPower MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: Power = -2.8 dBm

: Wireless Test Set Page 24 of 76 Engineering Test Report No. 1901073-02 25 20 10 0

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-20 m B d n i l e v e L 2478.5 2479 2479.5 2480 Frequency in MHz 2480.5 2481 2481.5 Connector 1 Peak Connector 1 Result DUT Frequency

(MHz) 2480.000000 Peak Power

(dBm) Limit Max

(dBm) Result

-2.7 30.0 PASS FCC15.247PeakConductedPower MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: Power = -2.7 dBm

: Wireless Test Set Page 25 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 18), Power Setting = 0dBm

: FCC-15.247, RSS-247 EIRP Output Power

: May 16-24, 2019

:3 meters

:

EIRP

(dBm)

-25.1

-23.3 Limit

(dBm) 36.0 36.0 Margin

(dB)

-61.1

-59.3

:

________________________________ Richard E. King Equivalent Antenna Cable Loss

(dB) 2.7 2.7 Wide BW Meter Reading

(dBuV) 39.0 38.0 Matched Sig. Gen. Reading

(dBm)

-26.6

-24.8 Ant Pol H V Gain

(dB) 4.2 4.2 Freq.

(MHz) 2402.00 2402.00 EIRP = Sig. Gen. Reading (dBm) + Antenna Gain (dB) Cable Loss (dB) Checked BY Page 26 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: FCC-15.247, RSS-247 EIRP Output Power

: May 16-24, 2019

: 3 meters

:

EIRP

(dBm)

-23.2

-18.0 Limit

(dBm) 36.0 36.0 Margin

(dB)

-59.2

-54.0

:

________________________________ Richard E. King Equivalent Antenna Cable Loss

(dB) 2.8 2.8 Wide BW Meter Reading

(dBuV) 41.6 44.3 Matched Sig. Gen. Reading

(dBm)

-24.8

-19.6 Ant Pol H V Gain

(dB) 4.4 4.4 Freq.

(MHz) 2442.00 2442.00 EIRP = Sig. Gen. Reading (dBm) + Antenna Gain (dB) Cable Loss (dB) Checked BY Page 27 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: FCC-15.247, RSS-247 EIRP Output Power

: May 16-24, 2019

: 3 meters

:

EIRP

(dBm)

-28.9

-23.9 Limit

(dBm) 36.0 36.0 Margin

(dB)

-64.9

-59.9

:

________________________________ Richard E. King Equivalent Antenna Cable Loss

(dB) 2.8 2.8 Wide BW Meter Reading

(dBuV) 35.6 37.6 Matched Sig. Gen. Reading

(dBm)

-30.6

-25.6 Ant Pol H V Gain

(dB) 4.5 4.5 Freq.

(MHz) 2480.00 2480.00 EIRP = Sig. Gen. Reading (dBm) + Antenna Gain (dB) Cable Loss (dB) Checked BY Page 28 of 76 Engineering Test Report No. 1901073-02 Page 29 of 76 Engineering Test Report No. 1901073-02 Page 30 of 76 Engineering Test Report No. 1901073-02 Page 31 of 76 Engineering Test Report No. 1901073-02 Page 32 of 76 Engineering Test Report No. 1901073-02 Page 33 of 76 Engineering Test Report No. 1901073-02 Page 34 of 76 Engineering Test Report No. 1901073-02 Page 35 of 76 Engineering Test Report No. 1901073-02 Page 36 of 76 Engineering Test Report No. 1901073-02 Page 37 of 76 Engineering Test Report No. 1901073-02 Page 38 of 76 Engineering Test Report No. 1901073-02 Page 39 of 76 Engineering Test Report No. 1901073-02 Page 40 of 76 Engineering Test Report No. 1901073-02 Page 41 of 76 Engineering Test Report No. 1901073-02 Page 42 of 76 Engineering Test Report No. 1901073-02 Page 43 of 76 Engineering Test Report No. 1901073-02 Page 44 of 76 Engineering Test Report No. 1901073-02 Page 45 of 76 Engineering Test Report No. 1901073-02 Page 46 of 76 Engineering Test Report No. 1901073-02 Page 47 of 76 Engineering Test Report No. 1901073-02 Page 48 of 76 Engineering Test Report No. 1901073-02 Page 49 of 76 Engineering Test Report No. 1901073-02 Page 50 of 76 Engineering Test Report No. 1901073-02 Page 51 of 76 Engineering Test Report No. 1901073-02 Page 52 of 76 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 1MHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V

(dBuV) Ambient 51.0 50.3 49.6 50.2 36.6 36.6

*

*

*

*

Pre Peak Total CBL Ant Fac

(dB) 3.7 3.7 6.1 6.1 2.2 2.2 Peak Total Fac Amp dBuV/m uV/m

(dB) 34.2 34.2 38.7 38.7 40.4 40.4 at 3m 48.6 47.9 54.5 55.1 51.0 51.0

(dB)

-40.2

-40.2

-39.9

-39.9

-28.2

-28.2 Peak Limit uV/m Margin

(dB)

-25.3

-26.1

-19.5

-18.9

-23.0

-23.0 at 3 m at 3 m 270.1 5000.0 248.6 5000.0 529.6 5000.0 566.8 5000.0 352.9 5000.0 353.3 5000.0 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 4804.00 4804.00 12010.00 12010.00 19216.00 19216.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 53 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Average Detector with 1MHz Resolution Bandwidth Average Average Average Limit uV/m Margin

(dB) at 3 m

-14.1 500.0 500.0

-18.0

-15.2 500.0

-15.1 500.0 500.0

-19.0

-19.0 500.0 Total dBuV/m at 3m 39.9 36.0 38.8 38.9 35.0 35.0 Total uV/m at 3 m 98.5 62.8 87.3 87.7 56.3 56.3

*

*

*

*

Freq. MHz CBL Fac

(dB) 3.7 3.7 6.1 6.1 2.2 2.2

(dBuV) Ambient 42.3 38.3 34.0 34.0 20.7 20.7 Ant Pre Duty Fac Amp Cycle

(dB)

(dB)

(dB) 0.0 34.2 -40.2 34.2 -40.2 0.0 0.0 38.7 -39.9 0.0 38.7 -39.9 40.4 -28.2 0.0 0.0 40.4 -28.2 Meter Ant Reading Pol H 4804.00 V 4804.00 12010.00 H 12010.00 V 19216.00 H 19216.00 V Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 54 of 76 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 4dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions not in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 100kHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V H V H V H V H V

(dBuV) Ambient 31.6 35.3 39.1 38.8 39.2 39.1 37.7 37.2 37.6 37.7 25.6 25.6 26.3 26.3

*

*

*

*

*

*

*

*

*

*

*

*

Ant Pre Peak CBL Total Fac Fac Amp dBuV/m at 3m

(dB) 66.4 2.6 2.6 70.1 39.3 4.6 39.1 4.6 5.2 41.0 40.9 5.2 44.3 6.6 43.9 6.6 7.2 47.5 47.6 7.2 39.8 2.2 2.2 39.8 40.3 2.2 2.2 40.3

(dB)

(dB) 0.0 32.2 0.0 32.2 35.9 -40.3 35.9 -40.3 36.8 -40.3 36.8 -40.3 39.6 -39.6 39.6 -39.6 42.0 -39.2 42.0 -39.2 40.6 -28.6 40.6 -28.6 40.6 -28.8 40.6 -28.8 Peak Total uV/m at 3 m 2092.7 3193.1 92.3 89.9 111.7 110.4 163.5 156.0 237.9 240.1 97.7 97.7 104.0 104.0 Peak Limit uV/m Margin

(dB) at 3 m 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0

-14.7

-14.9

-13.0

-13.1

-9.7

-10.1

-6.5

-6.4

-14.2

-14.2

-13.6

-13.6 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 2402.00 2402.00 7206.00 7206.00 9608.00 9608.00 14412.00 14412.00 16814.00 16814.00 21618.00 21618.00 24020.00 24020.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 55 of 76 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 1MHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V H V

(dBuV) Ambient 50.5 50.9 48.7 48.9 48.2 48.7 36.1 36.1

*

*

*

*

*

*

Pre Peak Total CBL Ant Fac

(dB) 3.7 3.7 4.7 4.7 6.1 6.1 2.2 2.2 Peak Total Fac Amp dBuV/m uV/m

(dB) 34.1 34.1 35.9 35.9 38.7 38.7 40.4 40.4 at 3m 48.2 48.6 48.9 49.1 53.0 53.6 50.5 50.5

(dB)

-40.1

-40.1

-40.3

-40.3

-39.9

-39.9

-28.1

-28.1 Peak Limit uV/m Margin

(dB)

-25.7

-25.4

-25.1

-24.8

-20.9

-20.4

-23.4

-23.4 at 3 m at 3 m 258.3 5000.0 268.9 5000.0 279.4 5000.0 286.2 5000.0 448.2 5000.0 476.4 5000.0 336.7 5000.0 336.7 5000.0 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 4884.00 4884.00 7326.00 7326.00 12210.00 12210.00 19536.00 19536.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 56 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Average Detector with 1MHz Resolution Bandwidth Average Average Average Limit uV/m Margin

(dB) at 3 m

-16.2 500.0 500.0

-14.1

-19.3 500.0

-19.2 500.0 500.0

-15.6

-15.5 500.0

-19.2 500.0 500.0

-19.2 Total dBuV/m at 3m 37.8 39.9 34.7 34.8 38.4 38.5 34.7 34.7 Total uV/m at 3 m 77.4 98.9 54.5 54.7 83.4 83.8 54.5 54.5 Freq. MHz

*

*

*

*

*

*

CBL Fac

(dB) 3.7 3.7 4.7 4.7 6.1 6.1 2.2 2.2

(dBuV) Ambient 40.1 42.2 34.47 34.5 33.6 33.6 20.3 20.3 Ant Pre Duty Fac Amp Cycle

(dB)

(dB)

(dB) 0.0 34.1 -40.1 34.1 -40.1 0.0 0.0 35.9 -40.3 0.0 35.9 -40.3 38.7 -39.9 0.0 0.0 38.7 -39.9 0.0 40.4 -28.1 40.4 -28.1 0.0 Meter Ant Reading Pol H 4884.00 V 4884.00 H 7326.00 7326.00 V 12210.00 H 12210.00 V 19536.00 H 19536.00 V Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 57 of 76 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions not in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 100kHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V H V H V H V

(dBuV) Ambient 39.1 40.1 38.3 38.4 36.8 37.7 37.8 37.5 25.9 25.9 26.5 26.5

*

*

*

*

*

*

*

*

*

*

Ant Pre Peak CBL Total Fac Fac Amp dBuV/m at 3m

(dB) 74.0 2.6 2.6 74.9 40.2 5.2 40.4 5.2 6.7 43.7 44.5 6.7 47.6 7.3 7.3 47.2 39.7 2.2 39.7 2.2 40.2 2.2 2.2 40.2

(dB)

(dB) 0.0 32.3 0.0 32.3 37.0 -40.3 37.0 -40.3 39.7 -39.6 39.7 -39.6 41.8 -39.3 41.8 -39.3 40.6 -29.0 40.6 -29.0 40.6 -29.1 40.6 -29.1 Peak Total uV/m at 3 m 4987.7 5589.9 102.7 104.8 152.8 168.5 238.6 230.2 96.2 96.2 102.7 102.7 Peak Limit uV/m Margin

(dB) at 3 m 559.0 559.0 559.0 559.0 559.0 559.0 559.0 559.0 559.0 559.0

-14.7

-14.5

-11.3

-10.4

-7.4

-7.7

-15.3

-15.3

-14.7

-14.7 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 2442.00 2442.00 9768.00 9768.00 14652.00 14652.00 17094.00 17094.00 21978.00 21978.00 24420.00 24420.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp Checked BY Page 58 of 76

:

________________________________ Richard E. King Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 1MHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V H V H V

(dBuV) Ambient 51.6 51.1 48.9 48.6 38.7 37.9 37.1 37.1 38.0 38.0

*

*

*

*

*

*

Pre Peak Total CBL Ant Fac

(dB) 3.7 3.7 4.7 4.7 6.1 6.1 2.2 2.2 2.2 2.2 Peak Total Fac Amp dBuV/m uV/m

(dB) 34.1 34.1 35.8 35.8 38.6 38.6 40.4 40.4 40.6 40.6 at 3m 49.5 48.9 49.1 48.8 43.4 42.6 51.4 51.4 51.9 51.9

(dB)

-40.0

-40.0

-40.3

-40.3

-40.0

-40.0

-28.4

-28.4

-29.0

-29.0 Peak Limit uV/m Margin

(dB)

-24.5

-25.1

-24.9

-25.1

-30.6

-31.4

-22.6

-22.6

-22.1

-22.1 at 3 m at 3 m 297.2 5000.0 278.3 5000.0 285.6 5000.0 276.6 5000.0 148.2 5000.0 135.3 5000.0 370.7 5000.0 370.7 5000.0 391.4 5000.0 391.4 5000.0 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 4960.00 4960.00 7440.00 7440.00 12400.00 12400.00 19840.00 19840.00 22320.00 22320.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 59 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions in Restricted Bands

: May 17-24, 2019

: 3 meters

: Average Detector with 1MHz Resolution Bandwidth Average Average Average Limit uV/m Margin

(dB) at 3 m

-16.6 500.0 500.0

-16.6

-19.9 500.0

-19.8 500.0 500.0

-15.6

-15.6 500.0

-17.8 500.0

-17.8 500.0 500.0

-18.2

-18.2 500.0 Total dBuV/m at 3m 37.4 37.3 34.1 34.2 38.4 38.4 36.2 36.1 35.7 35.7 Total uV/m at 3 m 74.2 73.6 50.7 51.4 83.4 82.9 64.5 64.2 61.2 61.2 Freq. MHz

*

*

*

*

CBL Fac

(dB) 3.7 3.7 4.7 4.7 6.1 6.1 2.2 2.2 2.2 2.2

(dBuV) Ambient 39.6 39.5 33.90 34.0 33.7 33.6 21.9 21.9 21.9 21.9 Ant Pre Duty Fac Amp Cycle

(dB)

(dB)

(dB) 0.0 34.1 -40.0 34.1 -40.0 0.0 0.0 35.8 -40.3 0.0 35.8 -40.3 38.6 -40.0 0.0 0.0 38.6 -40.0 0.0 40.4 -28.4 0.0 40.4 -28.4 40.6 -29.0 0.0 0.0 40.6 -29.0 Meter Ant Reading Pol H 4960.00 V 4960.00 H 7440.00 7440.00 V 12400.00 H 12400.00 V 19840.00 H 19840.00 V 22320.00 H 22320.00 V Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp

:

________________________________ Richard E. King Checked BY Page 60 of 76 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions not in Restricted Bands

: May 17-24, 2019

: 3 meters

: Peak Detector with 100kHz Resolution Bandwidth Meter Ant Reading Pol H V H V H V H V H V

(dBuV) Ambient 31.7 30.6 38.3 39.4 37.8 37.9 37.9 37.7 26.4 26.4

*

*

*

*

*

*

*

*

Ant Pre Peak Total CBL Fac Fac Amp dBuV/m at 3m

(dB) 2.7 66.7 65.6 2.7 40.5 5.3 41.5 5.3 6.8 44.7 44.9 6.8 47.5 7.4 7.4 47.3 40.1 2.2 2.2 40.1

(dB)

(dB) 0.0 32.3 32.3 0.0 37.1 -40.3 37.1 -40.3 39.8 -39.6 39.8 -39.6 41.7 -39.4 41.7 -39.4 40.6 -29.2 40.6 -29.2 Peak Total uV/m at 3 m 2159.2 1904.5 106.0 119.2 172.5 174.9 238.0 232.5 100.6 100.6 Peak Limit uV/m Margin at 3 m

(dB) 500.0 500.0 500.0 500.0 500.0 500.0 500.0 500.0

-13.5

-12.5

-9.2

-9.1

-6.4

-6.6

-13.9

-13.9 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 2480.00 2480.00 9920.00 9920.00 14880.00 14880.00 17360.00 17360.00 24800.00 24800.00 Total (dBuV/m) = Meter Reading + CBL FAC + Ant Fac + Pre Amp Checked BY Page 61 of 76

:

________________________________ Richard E. King Engineering Test Report No. 1901073-02 0

-20

-40

-60 m B d n i l e v e L 2310 2320 2340 2360 2380 2400 2420 2440 2460 2483.5 Limit Sum Level Fail Frequency in MHz FCC 15.247 Low Frequency Band Edge Compliance MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2402MHz (Ch. 37), Power Setting = 0dBm

: The trace represents the highest power measured inside the band with a 100kHz

: bandwidth. The red lines represents the 20dB down level from the peak in a

: 100kHz bandwidth and the low frequency band edge.

: Rohde & Schwarz Wireless Test Set Page 62 of 76 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes Freq. MHz 2483.50 2483.50 Engineering Test Report No. 1901073-02

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: FCC-15.247, RSS-247 Peak Radiated Emissions at High Band Edge

: May 16-24, 2019

: 3 meters

: Peak Detector with 1MHz Resolution Bandwidth Meter Ant Reading Pol H V

(dBuV) Ambient 22.9 23.9 Pre Peak Total CBL Ant Fac

(dB) 2.7 2.7 Peak Total Fac Amp dBuV/m uV/m

(dB) 32.3 32.3 at 3m 57.9 58.9

(dB) 0.0 0.0 Peak Limit uV/m Margin

(dB)

-16.1

-15.1 at 3 m at 3 m 783.7 5000.0 876.3 5000.0

:

________________________________ Richard E. King Checked BY Page 63 of 76 Engineering Test Report No. 1901073-02 Manufacturer Test Item Model No. Mode Test Specification Date Test Distance Notes

: CATERPILLAR Mossville AC

: Bluetooth Low Energy Transmitter

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 4dBm

: FCC-15.247, RSS-247 Average Radiated Emissions at High Band Edge

: May 16-24, 2019

: 3 meters

: Average Detector with 1MHz Resolution Bandwidth Freq. MHz 2483.50 2483.50 Meter Ant Reading Pol H V 6.9 6.8

(dBuV) Ambient CBL Fac

(dB) 2.7 2.7 Pre Duty Ant Fac Amp Cycle

(dB)

(dB) 32.3 0.0 0.0 32.3

(dB) 0.0 0.0 Average Average Average Limit uV/m Margin

(dB) at 3 m 500.0

-12.1

-12.2 500.0 Total dBuV/m at 3m 41.9 41.8 Total uV/m at 3 m 124.8 122.4

:

________________________________ Richard E. King Checked BY Page 64 of 76 Engineering Test Report No. 1901073-02 10 0

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-60 m B d n i l e v e L 2400.5 2401 2401.5 2402 Frequency in MHz 2402.5 2403 2403.5 Limit Sum Level PSD Result DUT Frequency

(MHz) Frequency

(MHz) 2402.000000 2401.917500 8.0 PASS Result PSD

(dBm)

-9.693 Limit Max

(dBm) FCC15.247PowerSpectralDensity MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: Power Spectral Density = -9.693dBm

: Rohde & Schwarz Wireless Test Set Page 65 of 76 Engineering Test Report No. 1901073-02 10 0

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-60 m B d n i l e v e L 2440.5 2441 2441.5 2442 Frequency in MHz 2442.5 2443 2443.5 Limit Sum Level PSD Result DUT Frequency

(MHz) Frequency

(MHz) 2442.000000 2442.022500 8.0 PASS Result PSD

(dBm)

-9.552 Limit Max

(dBm) FCC15.247PowerSpectralDensity MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2442MHz (Ch. 18), Power Setting = 0dBm

: Power Spectral Density = -9.552dBm

: Rohde & Schwarz Wireless Test Set Page 66 of 76 Engineering Test Report No. 1901073-02 10 0

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-60 m B d n i l e v e L 2478.5 2479 2479.5 2480 Frequency in MHz 2480.5 2481 2481.5 Limit Sum Level PSD Result DUT Frequency

(MHz) Frequency

(MHz) 2480.000000 2480.102500 8.0 PASS Result PSD

(dBm)

-9.414 Limit Max

(dBm) FCC15.247PowerSpectralDensity MANUFACTURER MODEL NUMBER TEST MODE NOTES EQUIPMENT USED

: CATERPILLAR Mossville AC

: PL161 SC

: Transmit at 2480MHz (Ch. 39), Power Setting = 0dBm

: Power Spectral Density = -9.414dBm

: Rohde & Schwarz Wireless Test Set Page 67 of 76 Engineering Test Report No. 1901073-02 Page 68 of 76 Engineering Test Report No. 1901073-02 Page 69 of 76 Engineering Test Report No. 1901073-02 Page 70 of 76 Engineering Test Report No. 1901073-02 Page 71 of 76 Engineering Test Report No. 1901073-02 Page 72 of 76 Engineering Test Report No. 1901073-02 Page 73 of 76 Engineering Test Report No. 1901073-02 Page 74 of 76 Engineering Test Report No. 1901073-02 Page 75 of 76 Engineering Test Report No. 1901073-02 Page 76 of 76

 

 

Date: _8/16/17 Subject: Confidenti PQM PL161SC 4071A PL161SC Pursuant to FCC 47 CRF 0.457(d) and 0.459 and IC RSP-100, Section 10, the applicant requests that a part of the subject FCC application be held confidenti Type of Confidentiality Requested Exhibit Cl Short Term KK] Permanent Block Diagrams Short Term External Photos

(1 Short Term Permanent*t Internal Photos Short Term XX] Permanent Operation Description/Theory of Operation Short Term &] Permanent Parts List & Placement/BOM Short Term [_] Permanent Tune-Up Procedure

[J Short Term XX] Permanent Schematics

[J Short Term Test Setup Photos LC Short Term Permanent* User's Manual

*Note: Insert Explanation as Necessa lar Inc. has spent substantial effort in developing this product and it is one of the first of its kind in industry. Having the subject information easily available to "competition" would negate the advantage they have achieved by developing this product. Not protecting the details of the design result in financial hardship. Permanent Confidentiality:

The applicant requests the exhibits listed above as permanently confidential be permanently withheld from public review due to materials that contain trade secrets and proprietary information not customarily released to the public. Short-Term Confidentiality:

The applicant requests the exhibits selected above as short term confidential be withheld from public view for a period of ify number of days not to exceed 180) _ days from the date of the Grant of Equipment Authorization and prior to marketing. This is to avoid premature release of sensitive information prior to marketing or release of the product to the public. Applicant is also aware that they are responsible to notify ELITE ELECTRONIC ENGINEERING, INC. in the event information regarding the product or the product is made available to the public. ELITE ELECTRONIC ENGINEERING, INC. will then release the documents listed above for public disclosure pursuant to FCC Public Notice DA 04-1705. NOTE for Industry Canada Applications:

The applicant understands that until such inguishes between Short Term and Permanent Confidentiality, either type of marked exhibit above will simply be marked Confidential when submitted to Ic. OY SS lng PE By: Michael Caruthers Division Manager (Print name) The asterisked items (*) require further justification before permanent confident be allowed. These also currently require review by the FCC under their Permit-But-Ask policy before the grant is issued and can delay completion of an application. Further justification should be added to the note above. One such example for a potted device would be: The EUT is FULLY potted using a non-removable epoxy based material. Removal of potting material causes irreparable damage to internal circuitry. See photographs exhibits that outline the device before and after potting.