FCC ID: 2AKNO-CT200LTE50 CENTAURI 200 Enterprise/Industrial IoT Gateway

Datasheet CENTAURI 200 Product ID CT200 LTE 50 Version: 2.3 Date: 01-02-2021 Volansys Technologies Private Limited Block A 7th Floor, Safal Profitaire, Corporate Road, Prahladnagar, Ahmedabad 380015, India www.volansys.com Phone: 91-79-4004-1994 Email: info@volansys.com Confidentiality Notice Copyright 2017 Volansys All rights reserved. This document is authored by Volansys and is Volansys intellectual property, including the copyrights in all countries in the world. This document is provided under a license to use only with all other rights, including ownership rights, being retained by Volansys. This file may not be distributed, copied, or reproduced in any manner, electronic or otherwise, without the express written consent of Volansys. CENTAURI 200 TABLE OF CONTENTS 1 INTRODUCTION........................................................................................................................................................... 5 1.1 PURPOSE..................................................................................................................................................................5 1.2 SCOPE..................................................................................................................................................................... 5 1.3 ACRONYMS & ABBREVIATIONS.................................................................................................................................... 5 1.4 REFERENCES............................................................................................................................................................. 5 2 PRODUCT OVERVIEW.................................................................................................................................................. 6 2.1 SYSTEM BLOCK DIAGRAM........................................................................................................................................... 7 2.2 FEATURES AND FUNCTIONALITY....................................................................................................................................8 3 MAJOR COMPONENTS ON CENTAURI 200................................................................................................................. 9 3.1 SECURE ELEMENT.................................................................................................................................................... 10 3.2 WIRELESS CONNECTIVITY.......................................................................................................................................... 10 3.3 WI-FI + BLUETOOTH COMBO MODULE.......................................................................................................................10 3.4 BLUETOOTH LOW ENERGY (BLE) MODULE.................................................................................................................. 11 3.5 ZWAVE 700 MODULE............................................................................................................................................. 12 3.6 LONG TERM EVOLUTION (LTE) MODULE.................................................................................................................... 12 3.7 POWER SUPPLY....................................................................................................................................................... 13 4 PERIPHERAL INTERFACES.......................................................................................................................................... 14 4.1 ETHERNET.............................................................................................................................................................. 14 4.2 IEEE FEATURES:...................................................................................................................................................... 17 4.3 USB......................................................................................................................................................................17 4.4 DEBUG PORT.......................................................................................................................................................... 18 4.5 EMMC..................................................................................................................................................................19 4.6 DDR (DOUBLE DATA RATE) RAM............................................................................................................................. 19 4.7 SWITCHES...............................................................................................................................................................19 4.8 LED'S....................................................................................................................................................................19 4.9 IO TABLE............................................................................................................................................................... 20 5 ELECTRICAL THERMAL & ANTENNA RANGE CHARACTERISTICS.............................................................................. 23 5.1 RECOMMENDED OPERATING CONDITIONS................................................................................................................... 23 5.2 THERMAL ANALYSIS DATA......................................................................................................................................... 23 5.3 RANGE FOR CT200................................................................................................................................................. 23 6 MECHANICAL DIMENSIONS.......................................................................................................................................24 7 CERTIFICATION...........................................................................................................................................................26 7.1 FCC (FEDERAL COMMUNICATIONS COMMISSION) & IC (INDUSTRY CANADA)................................................................... 26 CONFORME LA NORME NMB-003 DU CANADA...............................................................................................................26 APPLICATION NOTES.................................................................................................................................................... 26 SAFETY PRECAUTIONS.....................................................................................................................................................26 DESIGN ENGINEERING NOTES.......................................................................................................................................... 26 Rev 2.2 |25-Jun-20 Volansys - Confidential Page 2 of 27 CENTAURI 200 STORAGE CONDITIONS....................................................................................................................................................27 LIST OF FIGURES FIGURE 1 : CENTAURI 200 UNIT............................................................................................................................................ 6 FIGURE 2 : CENTAURI 200 PCBA...........................................................................................................................................7 FIGURE 3 : CENTAURI 200 - SYSTEM BLOCK DIAGRAM.............................................................................................................. 8 FIGURE 6 : NRF52840 BLE MODULE.................................................................................................................................. 11 FIGURE 8 : ZWAVE 700 MIKROBUS MODULE...................................................................................................................... 12 FIGURE 9 : LTE MODULE................................................................................................................................................... 13 FIGURE 10 : INTERFACES ON CENTAURI 200..........................................................................................................................14 FIGURE 11 : ETHERNET PORTS............................................................................................................................................ 14 FIGURE 12 : USB PORT SELECTION JUMPER.......................................................................................................................... 18 FIGURE 14 : DEBUG PORT.................................................................................................................................................. 18 FIGURE 15 : USER CONFIGURABLE SWITCHES........................................................................................................................ 19 FIGURE 16 : LED'S ON CENTAURI 200................................................................................................................................. 20 LIST OF TABLES TABLE 1 : REVISION HISTORY................................................................................................................................................ 4 TABLE 2 : ACRONYMS & ABBREVIATIONS................................................................................................................................ 5 TABLE 3 : REFERENCES......................................................................................................................................................... 5 TABLE 4 : FEATURES AND FUNCTION....................................................................................................................................... 8 TABLE 6 : WI-FI RF CHARACTRICS....................................................................................................................................... 11 TABLE 7 : LED'S................................................................................................................................................................ 20 TABLE 8 : IO ON CENTAURI 200.......................................................................................................................................... 22 TABLE 9 : RECOMMENDED OPERATING CONDITIONS............................................................................................................... 23 TABLE 10 : THERMAL ANALYSIS...........................................................................................................................................23 TABLE 11 : RANGE TEST.....................................................................................................................................................23 Rev 2.2 |25-Jun-20 Volansys - Confidential Page 3 of 27 COPYRIGHT INFORMATION CENTAURI 200 The information contained in this document is the proprietary information of VOLANSYS Technologies Pvt., Ltd. The contents are confidential and any disclosure to persons other than the officers, employees, agents or subcontractors of the owner or licensee of this document, without the prior written consent of VOLANSYS, is strictly prohibited. Further, no portion of this document may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, without the prior written consent of VOLANSYS, the copyright holder. VOLANSYS publishes this document without making any warranty as to the content contained herein. Further VOLANSYS reserves the right to make modifications, additions and deletions to this document due to typographical errors, inaccurate information, or improvements to products mentioned in the document at any time and without notice. Such changes will, nevertheless, be incorporated into new editions of this document. Revision History Date 5-Aug-19 8-Feb-20 Version 1 2 Details of change Author Reviewers Initial draft

- Updated the document as per the latest rev2.0 of the schematics and layout.

- Removed Regulatory Statements section.

- Updated the document with standard document template. 19-Mar-20 25-06-20 2.1 2.2

- Updated all the tables, Images, added thermal & Range test data.

- Updated PoE source specification in section 3.10 03/02/2021 2.3

- Updated as per Ochsner certification Table 1 : Revision History JB SD YP SD YP KB KB KB KB KB Rev 2.2 |25-Jun-20 Volansys - Confidential Page 4 of 27 CENTAURI 200 1 INTRODUCTION Purpose 1.1 This document describes the VOLANSYS Centauri 200 enterprise/industrial IoT Gateway. Targeted for multiple use cases in various segments of IoT such as Smart Home, Buildings and Industries. Core features are its Hardware Design with Multi-Radio Connectivity such as Wi-Fi, BLE/BT, LTE, Thread, Zigbee and Z-Wave. Apart from multiple radio connectivity options. This document mainly describes Centauri 200 from a Hardware point of view, there are separate software development manuals that can be also consulted. For any further support contact Volansys support services at: centauri.support@volansys.com Scope 1.2 The scope of this document is to detail out aspect of CT200 Gateway product design, specifications, Features etc. This document, henceforth, is to be used as a direct reference by end customers that uses this product. CT200 Gateway team will also use this document to review, approve and accept the product design for showcase purpose. 1.3 Acronyms & Abbreviations Terms SoC CPU BLE IoT RST UART LED GPIO TBD Etc Definition System on Chip Central Processing Unit Bluetooth Low Energy Internet of things Reset Universal asynchronous receiver-transmitter Light Emitting Diode General Purpose Input/output To Be Determined Et Criteria Table 2 : Acronyms & Abbreviations 1.4 References Sr No 1 2 Reference Document Title Schematics design Layout design Provided by Volansys Volansys Remarks Primary reference N/A Table 3 : References Rev 2.2 |25-Jun-20 Volansys - Confidential Page 5 of 27 CENTAURI 200 2 PRODUCT OVERVIEW Volansys Centauri 200 is all-in-one gateway development kit, which is based on NXPs power efficient i.MX6ULL/ i.MX6UltraLite/ i.MX6ULZ applications processor featuring ARM Cortex-A7 core CPUs. Centauri 200 has a wide range of interfaces available like USB, Ethernet, RS232/485, CAN. It supports various wireless connectivity protocol as Thread, BLE, Zigbee, Z-Wave, Wi-Fi b/g/n, LTE. Centauri 200 has standard MikroBus compatible socket header which enables a user to use any standard MikroBus add on modules. The figure below shows the complete Centauri 200 unit and internal view depicting all its interfaces. the needs of the CENTAURI 200 IoT Gateway platform is specifically crafted to satisfy all Enterprise/Industrial IoT Gateway Solution. Gateway is built on secure, power-efficient, and cost-

optimized ARM Cortex-A7 based i.MX6ULL SoC. This enables a greater amount of flexibility in providing various RF connectivity and peripherals to make a tailor-made solution according to end-user needs. VOLANSYS also offers a CENTAURI Software Framework for all OEMs to quickly build applications. CENTAURI Gateway platform is pre-integrated with well-known cloud & app platform providers to help OEMs with faster application development. OEMs can build Zigbee gateway, Z-Wave gateway, BLE gateway and Thread gateway-based solution on the platform with any two radios supported at a time. CENTAURI Gateway platform is available under OEM offerings to reduce time to market so that you can focus more on creating values in end-user applications. Figure 1: Centauri 200 Unit Rev 2.2 |25-Jun-20 Volansys - Confidential Page 6 of 27 CENTAURI 200 2.1 System Block Diagram Figure 2: Centauri 200 PCBA Rev 2.2 |25-Jun-20 Volansys - Confidential Page 7 of 27 Figure 3: Centauri 200 - System Block Diagram Features and Functionality 2.2 The table below lists major features and function of the Centauri 200. CENTAURI 200 Sr No 1 Block CPU Memory 2 3 4 Interfaces User Interface/

IO Feature Parameter Core & Frequency RAM Memory Type RAM Size EMMC Ethernet USB Mikrobus header Wi-Fi + BLE LTE Switch LED's Specification i.MX 6ULL (792 MHz) ARM Cortex A7 DDR3L 256 MB 4 GB 1 x 10/100Mbps 1 x USB2.0 (Host/Device) 1 x Z wave Module BLE 4.2, Wi-Fi 802.11 b/g/n CAT1(4G) 2x user configurable switches 1x power LED 2x user configurable LED's 1x UART port for debug Debug Port Table 4: Features and Function Rev 2.2 |25-Jun-20 Volansys - Confidential Page 8 of 27 CENTAURI 200 3 MAJOR COMPONENTS ON CENTAURI 200 Below are some of major features and interfaces of Centauri 200 base board:

2x MikroBus Compatible Header. (Supports ZGM130S Z-Wave module) 1x Wi-Fi b/g/n + BT/BLE Combo module with U.FL connector to support external antenna. On board nRF52840 BLE module with optional external antenna. 1x 4FF (Nano) SIM card connector for LTE. 1x JTAG header. 1x USB 2.0 port (host/device configurable). 1x 10/100 Ethernet port. 3x LED's (1x power + 2x user configurable). 2x user configurable switches. DC power jack (5V, 3A) or terminal block (9-27V). Note: Other MikroBUS compatible modules can be added to the Centauri 200 via its MikroBUS compatible headers. Figure 4 : Centauri 200 - Base Board Rev 2.2 |25-Jun-20 Volansys - Confidential Page 9 of 27 Secure Element 3.1 Centauri 200 has a built-in secure element IC providing device to device authentication, key storage and data protection, etc features based on NXPs A71CH chip. The A71CH is a ready-to-use solution providing a root of trust at the IC level and proven, chip-to-cloud security right out of the box. It is a platform capable of securely storing and provisioning credentials, securely connecting IoT devices to cloud services and performing cryptographic node authentication. CENTAURI 200 More information regarding this chip can be found at the link below:

https://www.nxp.com/docs/en/data-sheet/A71CH-SDS.pdf 3.2 Wireless Connectivity Centauri 200 has on board AP6212, ZGM130S, nRF52840 and EG91 wireless modules. Below are major features of each wireless peripheral. More information regarding the wireless modules can be obtained from their respective websites and data-sheets. 3.3 Wi-Fi + Bluetooth Combo Module The Centauri 200 uses an Ampak AP6212 Wi-Fi + Bluetooth combo module. AP6212 is a single chip 2.4 GHz WLAN IEEE 802.11 b/g/n single band radio and Bluetooth V4.0(HS) with integrated class 1.5 PA and Low Energy (LE) support. The Cenaturi 200 comes with two antenna options for the Wi-Fi/BLE viz. Internal PCB trace antenna and external high gain whip antenna. Below image shows the RF specification of the Wi-Fi/BT module. Sr Feature 1 WLAN Standard 2 Frequency Range 3 Number of Channels 4 Modulation 5 Output Power (Burst Average Power) 6 Receive Sensitivity (11n,20MHz) @10%

PER 7 Receive Sensitivity (11g) @10% PER Description IEEE 802.11b/g/n, WiFi compliant 2.400 GHz ~ 2.4835 GHz (2.4 GHz ISM Band) 2.4GHzCh1 ~ Ch14 802.11b : DQPSK, DBPSK, CCK 802.11 g/n : OFDM /64-QAM,16-QAM, QPSK, BPSK 802.11b /11Mbps : 16 dBm 1.5 dB @ EVM -9dB 802.11g /54Mbps : 15 dBm 1.5 dB @ EVM -25dB 802.11n /65Mbps : 14 dBm 1.5 dB @ EVM -28dB

- MCS=0 PER @ -85 dBm, typical

- MCS=1 PER @ -84 dBm, typical

- MCS=2 PER @ -82 dBm, typical

- MCS=3 PER @ -80 dBm, typical

- MCS=4 PER @ -77 dBm, typical

- MCS=5 PER @ -73 dBm, typical

- MCS=6 PER @ -71 dBm, typical

- MCS=7 PER @ -68 dBm, typical

- 6Mbps PER @ -86 dBm, typical

- 9Mbps PER @ -85 dBm, typical

- 12Mbps PER @ -85 dBm, typical Rev 2.2 |25-Jun-20 Volansys - Confidential Page 10 of 27 CENTAURI 200

- 18Mbps PER @ -83 dBm, typical

- 24Mbps PER @ -81 dBm, typical

- 36Mbps PER @ -78 dBm, typical

- 48Mbps PER @ -73 dBm, typical

- 54Mbps PER @ -71 dBm, typical

- 2Mbps PER @ -88 dBm, typical

- 5.5Mbps PER @ -87 dBm, typical

- 11Mbps PER @ -84 dBm, typical

- 2Mbps PER @ -88 dBm, typical 802.11b : 1, 2, 5.5, 11Mbps 802.11g : 6, 9, 12, 18, 24, 36, 48, 54Mbps 802.11n: 6.5, 13, 19.5, 26, 39, 52, 58.5, 65Mbps 802.11n : 7.2, 14.4, 21.7, 28.9, 43.3, 57.8, 65,72.2Mbps 802.11b : -10 dBm 802.11g/n : -20 dBm Small antennas with 0~2 dBi peak gain 8 Receive Sensitivity (11b) @8% PER 9 Data Rate 10 Data Rate (20MHz ,Long GI,800ns) 11 Data Rate (20MHz ,short GI,400ns) 12 Maximum Input Level 13 Antenna Reference Table 6 : Wi-Fi RF Charactrics 3.4 Bluetooth Low Energy (BLE) Module The Centauri 200 implements a Nordic semiconductor nRF52840 multiprotocol transceiver chip on board. The nRF52840 is fully multiprotocol capable of full protocol concurrency. It has protocol support for Bluetooth 5.0, Bluetooth mesh, Thread, Zigbee, 802.15.4, ANT and 2.4 GHz proprietary stacks. This chip also comes with inbuilt sophisticated power management system for low energy consumption. The Centauri 200 provides a PCB trace antenna on board for operation of this section and has U.FL connector for providing support to external 2.4 GHz antenna depending upon the use case. Figure 4-5 depicts implementation of the nRF52840 on the Centauri 200 board. Figure 5 : nRF52840 BLE Module Rev 2.2 |25-Jun-20 Volansys - Confidential Page 11 of 27 CENTAURI 200 ZWave 700 Module 3.5 ZWave 700 connectivity is possible on Centauri 200 using Volansys ZWave 700 module. It is developed using the Silicon Labs Z-Wave 700 Zen Gecko SiP Module, ZGM130S. The ZGM130S is a fully integrated Z-

Wave module, enabling rapid development of Z-Wave solutions. A base band controller, Sub-GHz radio transceiver, crystal, decoupling, and matching is included to provide a complete Z-Wave System-in-

Package module requiring only an external antenna. An ideal solution for smart home control and sensing applications such as sensors, door locks, light switches, security networks as well as gateways. Following are the features of the Zwave 700 module:

ITU G.9959 compliant. Supports all ZWave bands (865.2 MHz - 926.3 MHz). ARM Cortex-M4 Floating Point Unit. 39 MHz clock speed. 64 Kb application flash. 8 Kb application RAM. MikroBUS compliant. Figure 6 : ZWave 700 MikroBUS Module Long Term Evolution (LTE) Module 3.6 Centauri 200 supports on-board LTE cellular connectivity LTE CAT1(4G), CAT M1, NB-IOT and WCDMA

(3G) to provide compatibility with multiple geographic regions like North America, Europe, etc. Centauri 200 uses external antenna for LTE wireless connectivity. Besides LTE, Centauri 200 also supports GNSS/GPS using an external antenna interface. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 12 of 27 CENTAURI 200 Centauri 200 has a Nano(4FF) SIM card socket. The socket is user accessible and thus, SIM card can be changed without opening the Centauri 200 enclosure. Figure 7 : LTE Module Power Supply 3.7 The Centauri 200 has the following power options:

DC Jack: Uses a 5V, 3A DC power adaptor. Terminal Block: Uses a 9-27V, 1.6-0.6A DC power adaptor Rev 2.2 |25-Jun-20 Volansys - Confidential Page 13 of 27 4 PERIPHERAL INTERFACES This section describes interfaces of Centauri 200. Below figure shows the available interfaces of Centauri 200. Figure 5-1 describes the peripheral interfaces of Centauri 200 pictorially. CENTAURI 200 Figure 8 : Interfaces on Centauri 200 Ethernet 4.1 The Centauri 200 has 1 x 10/100Mbit/s Ethernet ports. Figure 9 : Ethernet Ports Rev 2.2 |25-Jun-20 Volansys - Confidential Page 14 of 27 CENTAURI 200 Ethernet MAC features:

Implements the full 802.3 specification with preamble/SFD generation, frame padding generation, CRC generation and checking, supports zero-length preamble. Dynamically configurable to support 10/100-Mbit/s operation. Supports 10/100 Mbit/s full-duplex and configurable half-duplex operation. Compliant with the AMD magic packet detection with interrupt for node remote power management. Seamless interface to commercial Ethernet PHY devices via one of the following:

A 4-bit Media Independent Interface (MII) operating at 2.5/25 MHz. A 4-bit non-standard MII-Lite (MII without the CRS and COL signals) operating at 2.5/25 MHz. A 2-bit Reduced MII (RMII) operating at 50 MHz. Simple 64-Bit FIFO user-application interface. CRC-32 checking at full speed with optional forwarding of the frame check sequence(FCS) field to CRC-32 generation and append on transmit or forwarding of user application provided FCS the client. selectable on a per-frame basis. In full-duplex mode:

Implements automated pause frame (802.3 x31A) generation and termination, providing flow control without user application intervention. Pause quanta used to form pause frames dynamically programmable. Pause frame generation additionally controllable by user application offering flexible traffic flow control. transmission. Optional forwarding of received pause frames to the user application. Implements standard flow-control mechanism. In half-duplex mode: provides full collision support, including jamming, back-off, and automatic re-

Supports VLAN-tagged frames according to IEEE 802.1Q Programmable MAC address: Insertion on transmit; discards frames with mismatching destination address on receive. (except broadcast and pause frames) Programmable promiscuous mode support to omit MAC destination address checking on receive. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 15 of 27 CENTAURI 200 Multicast and uni cast address filtering on receive based on 64-entry hash table, reducing higher layer processing load. Programmable frame maximum length providing support for any standard or proprietary frame length. levels. Statistics indicators for frame traffic and errors (alignment, CRC, length) and pause frames providing for IEEE 802.3 basic and mandatory management information database (MIB) package and remote network monitoring (RFC 2819). Simple handshake user application FIFO interface with fully programmable depth and threshold Provides separate status word for each received frame on the user interface providing information such as frame length, frame type, VLAN tag, and error information. Multiple internal loop back options. MDIO master interface for PHY device configuration and management supports two programmable MDIO base addresses, and standard (IEEE 802.3 Clause 22) and extended (Clause 45) MDIO frame formats. Supports legacy FEC buffer descriptors. IP protocol performance optimization features:

Interrupt coalescing reduces the number of interrupts generated by the MAC, reducing CPU loading. Operates on TCP/IP and UDP/IP and ICMP/IP protocol data or IP header only, enables wire-speed processing, Supports IPv4 and IPv6. Transparent passing of frames of other types and protocols. Supports VLAN tagged frames according to IEEE 802.1q with transparent forwarding of VLAN tag and control field. receive. Automatic IP-header and payload (protocol specific) checksum calculation and verification on Automatic IP-header and payload (protocol specific) checksum generation and automatic insertion on transmit configurable on a per-frame basis. Supports IP and TCP, UDP, ICMP data for checksum generation and checking. Supports full header options for IPv4 and TCP protocol headers. Provides statistics information for received IP and protocol errors. Configurable automatic discard of erroneous frames. Configurable automatic host-to-network (RX) and network-to-host (TX) byte order conversion for IP and TCP/UDP/ICMP headers within the frame. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 16 of 27 Configurable padding removes for short IP datagrams on receive. Configurable Ethernet payload alignment to allow for 32-bit word-aligned header and payload processing. Programmable store-and-forward operation with clock and rate decoupling FIFOs. CENTAURI 200 IEEE features:

4.2 Supports all IEEE 1588 frames. Allows reference clock to be chosen independently of network speed. Software-programmable precise time stamping of ingress and egress frames. Timer monitoring capabilities for system calibration and timing accuracy management. Precise time stamping of external events with programmable interrupt generation. Programmable event and interrupt generation for external system control. Supports hardware- and software-controllable timer synchronization. Provides a 4-channel IEEE 1588 timer. Each channel supports input capture and output compare using the 1588 counter. 4.3 USB Centauri 200 has one USB 2.0 Type A port on back side and is configured as a host device by default. Below are major features of USB interface:

High-Speed/Full-Speed/Low-Speed support. High Speed, and Full Speed operation in Peripheral mode (with UTMI transceiver). Hardware support for OTG signaling, session request protocol, and host negotiation protocol. Up to 8 bidirectional endpoints. Low-power mode with local and remote wake-up capability. Serial PHY interfaces configurable for bidirectional/unidirectional and differential/single ended. Embedded DMA controller. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 17 of 27 CENTAURI 200 Figure 10 : USB Port Selection Jumper The Centauri 200 can also be configured as a USB slave device. This is done by closing the selection jumper using a jumper shunt. The location of the selection jumper is on the Centauri 200 PCBA. Figure 5-

3 shows the jumper on a Centauri 200 PCBA. 4.4 Debug Port The Centauri 200 has an inbuilt debug UART port with three pins. Debug is only possible if the user can access Centauri 200 PCBA. It is to be noted that the UART signaling occurs at 3.3V logic levels and the pins are not 5V tolerant. A user can enter the debug prompt on a PC/Mac using a normal 3.3V logic USB to UART converter. These are the parameters to establish debug UART connection with Centauri 200:

Baud rate: 115200 Data bits: 8 Parity: None Stop bits: 1 Flow control: None Figure 11 : Debug Port Rev 2.2 |25-Jun-20 Volansys - Confidential Page 18 of 27 eMMC 4.5 For storage of data, Centauri 200 utilizes eMMC/NAND. Note that Centauri 200 also has an option of using NAND instead of eMMC as per the variant. The table below describes eMMC/NAND storage densities possible on Centauri 200. CENTAURI 200 Sr No 1 eMMC Memory Density Standard - 4 GB Table 17: Storage Options 4.6 DDR (Double Data Rate) RAM The Centauri 200 uses a DDR3L memory operating at 1866 MT/s . The standard density of the DDR RAM for Centauri 200 is 256 MB. The table below shows the possible densities possible with Centauri 200. Sr No 1 DDR RAM Memory Density Standard configuration - 256 MB Table 18: DDR Options Switches 4.7 The Centauri 200 has two tactile switches on the front panel. These switches are completely user configurable and users can use it as per their use case. Figure 5-6 describes switches on Centauri 200. Figure 12 : User Configurable Switches LED's 4.8 The Centauri 200 has three inbuilt LED's. One LED is used to indicate whether the Centauri 200 is powered ON or OFF and the remaining two are user configurable. The user can use these two LED's as per their use case. Figure 5-7 shows the location of these LED's on the Centauri 200. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 19 of 27 CENTAURI 200 Figure 13 : LED's on Centauri 200 Sr No 1 2 LED PWR LED Colour Green LED1 & LED2 Bi-colour Table 7: LED's Function ON: Centauri 200 powered ON OFF: Centauri 200 powered OFF Status: User configurable IO Table 4.9 Below table describes the IO interfacing to all the internal peripherals of the Centauri 200 and the IO addressing in Centauri 200 from the user perspective. Sr. Peripheral Section P IO P Pad Linux Use 1 ORing Control ORing GPIO5_IO09 R6 IO137 ORing - Used to know which input source is switched when two voltage inputs are available. Used to enable/disable power to the USB type A connector. Used to put the CT200 in master/slave mode. 2 3 4 5 6 RTC_INTA ORing + RTC GPIO1_IO04 M16 IO4 EN_USB GPIO1_IO01 USB USB_OTG_ID USB_OTG_N USB_OTG_P GPIO1_IO00 USB_OTG1_DN USB_OTG1_DP C15 K13 T15 U15 IO1 IO0

Rev 2.2 |25-Jun-20 Volansys - Confidential Page 20 of 27 7 CAN_PD 8 9 10 CAN_RX CAN_TX BLE_RST BLE_INT UART1_TX UART1_RX UART1_RTS UART1_CTS SPI1_CLK SPI1_MOSI SPI1_MISO SPI1_SS0 SPI1_SS1 SWITCH_1 SWITCH_2 LED_ST_2 LED_ST_3 LED_ST_4 LED_ST_5 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 WLAN_RST 28 WLAN_DAT0 29 WLAN_DAT1 30 WLAN_DAT2 31 WLAN_DAT3 32 WLAN_CMD 33 WLAN_CLK BT_RST 34 36 WLAN_TX 37 WLAN_RX 38 WLAN_CTS 39 WLAN_RTS ZWave_RST 40 ZWave_INT 41 42 43 44 45 BOOT_MODE BOOT_MODE RS485_DIR RS485_RX CAN nRF52840 BLE nRF52840 BLE

+ MikroBUS1 nRF52840 BLE

+ MikroBUS1

+ MikroBUS2 nRF52840 Switch LED's Wi-Fi MikroBUS2 Boot config selector RS485/

GPIO1_IO09 UART3_RTS UART3_CTS GPIO1_IO05 GPIO5_IO01 UART1_TX_DATA UART1_RX_DATA UART1_RTS UART1_CTS ECSPI1_SCLK ECSPI1_MOSI ECSPI1_MISO GPIO4_IO26 GPIO4_IO24 GPIO3_IO00 GPIO5_IO00 GPIO4_IO17 GPIO4_IO18 GPIO5_IO07 GPIO5_IO08 GPIO4_IO19 usdhc1_DAT0 usdhc1_DAT1 usdhc1_DAT2 usdhc1_DAT3 usdhc1_CMD usdhc1_CLK GPIO4_IO20 UART2_TX_DATA UART2_RX_DATA UART2_CTS UART2_RTS GPIO4_IO21 GPIO5_IO04 SRC_BOOT_MODE SRC_BOOT_MODE GPIO4_IO14 UART5_RX_DATA M15 G14 H15 M17 R9 K14 K16 J14 K15 D4 D2 D1 D3 E1 A8 R10 F5 E5 N10 N9 F2 B3 B2 B1 A2 C2 C1 F3 P11 J17 J16 H14 J15 E4 P9 T10 U10 B5 G13 35 BT_WAKE GPIO5_IO02 IO9

IO5 CENTAURI 200 Used to enable/disable CAN transmissions. CAN Receive. CAN Transmit. Used to reset the on board BLE module. Serial Peripheral Interface (SPI) Bus. UART1. Used to communicate with nRF58240 BLE module Slave Select (SS) for SPI BUS. User configurable switches. IO129

IO122 IO120 IO64 IO128 IO113 IO114 IO135 IO136 IO115 Used to reset on board

IO116 Used to reset BT/BLE Used for communicating with the Wi-Fi section of the on board Wi-Fi combo module. User configurable LED's. section of the on board IO130 Used to wake BT/BLE

IO117 IO132 section of the on board UART2 interface. Used for communicating with the BT/BLE section of the on board Wi-Fi Reset IO for MikroBUS Interrupt IO for MikroBUS module. Used for selecting boot mode configuration.

IO110 Used to enable/disable

UART5 interface for Rev 2.2 |25-Jun-20 Volansys - Confidential Page 21 of 27 46 47 48 49 RS485_TX LTE_DM LTE_DP LTE_NETW UART5_TX_DATA USB_OTG2_DN USB_OTG2_DP GPIO4_IO23 50 LTE_STATUS GPIO3_IO03 51 LTE_PWR_KEY LTE GPIO3_IO02 CENTAURI 200

IO119 Used to get network USB interface for communicating with the IO67 IO68 status. Used to get status of the module. Used to turn the module ON/OFF. module. Used to enable/disable power to the LTE module. I2C interface. UART3 Interface. UART4 interface. Used for debug. F17 T13 U13 E2 C9 D9 E3 L14 L17 H17 H16 G14 H15 G17 G16 52 LTE_RST GPIO4_IO22 IO118 Used to reset the LTE 53 EN_LTE_LDO GPIO5_IO03 P10 IO131 54 55 56 57 58 59 60 61 SCL SDA UART3_TX UART3_RX UART3_RTS UART3_CTS UART4_TX UART4_RX PMIC, RTC, EEPROM, MikroBUS2 MikroBUS2/

CAN Debug header I2C_SCL I2C_SDA UART3_TX_DATA UART3_RX_DATA UART3_RTS UART3_CTS UART4_TX_DATA UART4_RX_DATA Table 8: IO on Centauri 200

Rev 2.2 |25-Jun-20 Volansys - Confidential Page 22 of 27 CENTAURI 200 5 ELECTRICAL THERMAL & ANTENNA RANGE CHARACTERISTICS 5.1 Recommended Operating Conditions Sr No Description 1 Operating voltage 2 3 Operating temperature range (ambient) Current consumption Minimum 4.75

-10 Value Typical 5

25 Maximum 5.5 3 65 Unit V A C Table 9: Recommended Operating Conditions Thermal Analysis data 5.2 Thermal analysis of CT200 was done with 4 different configuration as per below table. Sr. No. 1 2 3 4 Objective CPU Runs in normal Condition CPU run at 33%

CPU run at 66%

CPU run at 100%

Processor Temperature 81 C 84 C 86 C 92 C Table 10 : Thermal Analysis Ambient Temperature 65 C 65 C 65 C 65 C Note : The CPU threshold limit of the processor is 100 C. As CPU temperature increased to 100 C then processor will shutdown the PMIC and all the interfaces are down till the temperature reaches to 25 C. 5.3 Range for CT200 Range of CT200 device for BLE and Wi-Fi interface. The below table shows the range test data. Sr. No. 1 2 3 4 5 Wi-Fi (AP6212) BLE (nRF52840) Wi-Fi (AP6212) BLE (nRF52840) Zwave (ZGM130S) RF Module RF Power (dBm) Max Range (m) 14 8 14 8 14 Table 11 : Range Test 200 145 200 145 130 Antenna Internal Internal External WHIP Antenna External Patch Antenna External Patch Antenna Rev 2.2 |25-Jun-20 Volansys - Confidential Page 23 of 27 6 MECHANICAL DIMENSIONS The table top dimensions of Centauri 200 are 100 x 150 x 30 mm (L x W x H). Figure 7-1 shows the dimensions in more detail. Note: All dimensions are in millimetre (mm), unless otherwise specified. CENTAURI 200 Figure 14 : Centauri 200 Dimensions table top The table wall mount dimensions of Centauri 200 are 180 x 100 x 30 mm (L x W x H). Figure 7-1 shows the dimensions in more detail. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 24 of 27 CENTAURI 200 Figure 15 : Centauri 200 Dimensions wall mount Rev 2.2 |25-Jun-20 Volansys - Confidential Page 25 of 27 CENTAURI 200 7 CERTIFICATION FCC (Federal Communications Commission) & IC (Industry Canada) 7.1 This equipment complies with FCC and IC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance of 20 cm between the radiator and your body. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. This device complies with part 15 of the FCC rules and RSS-247 of Industry Canada. 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. Le prsent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils 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. This Class B digital apparatus complies with Canadian ICES-003. Cet appareil numrique de la classe B est conforme la norme NMB-003 du Canada. APPLICATION NOTES Safety Precautions These specifications are intended to preserve the quality assurance of products as individual components. Before use, check and evaluate the modules operation when mounted on your products. Abide by these specifications when using the products. These products may short-circuit. If electrical shocks, smoke, fire, and/or accidents involving human life are anticipated when a short circuit occurs, then provide the following fail safe functions as a minimum:

1. 2. Ensure the safety of the whole system by installing a protection circuit and a protection device. Ensure the safety of the whole system by installing a redundant circuit or another system to prevent a single fault causing an unsafe status. Design Engineering Notes 1. Heat is the major cause of shortening the life of the modules. Avoid assembly and use of the target Rev 2.2 |25-Jun-20 Volansys - Confidential Page 26 of 27 CENTAURI 200 2. 3. 4. 5. 6. equipment in conditions where the products temperature may exceed the maximum allowable. Failure to do so may result in degrading of the products functions and damage to the product. If pulses or other transient loads (a large load applied in a short time) are applied to the products, before use, check and evaluate their operation when assembled onto your products. These products are not intended for other uses, other than under the special conditions shown below. Before using these products under such special conditions, check their performance and reliability under the said special conditions carefully, to determine whether or not they can be used in such a manner. In direct sunlight, outdoors, or in a dusty environment. In liquid, such as water, salt water, oil, alkali, or organic solvent, or in places where liquid may splash. In an environment where condensation occurs. In an environment with a high concentration of harmful gas (ex. salty air, HCl, Cl2, SO2, H2S, NH3, and NOx). If an abnormal voltage is applied due to a problem occurring in other components or circuits, replace these products with new products because they may not be able to provide normal performance even if their electronic characteristics and appearances appear satisfactory. 7. Mechanical stress during assembly of the board and operation must be avoided. 8. Pressing on parts of the metal cover or fastening objects to the metal cover is not permitted. Storage Conditions 1. The module must not be stressed mechanically during storage. 2. Do not store these products in the following conditions or the performance characteristics of the product, such as RF performance, may well be adversely affected:

- Storage in salty air or in an environment with a high concentration of corrosive gas, such as Cl2, H2S, NH3, SO2 or NOx.

- Storage (before assembly of the end product) for more than one year after the date of date of delivery even if all the above conditions have been met, should be avoided. Rev 2.2 |25-Jun-20 Volansys - Confidential Page 27 of 27 Datasheet ZWave 700 Module Revision: 2.3 Date: 13-Apr-2020 Volansys Technologies Private Limited Block A 7th Floor, Safal Profitaire, Corporate Road, Prahladnagar, Ahmedabad 380015, India www.volansys.com Phone: 91-79-4004-1994 Email: info@volansys.com Confidentiality Notice Copyright 2019Volansys All rights reserved. This document is authored by Volansys and is Volansys intellectual property, including the copyrights in all countries in the world. This document is provided under a license to use only with all other rights, including ownership rights, being retained by Volansys. This file may not be distributed, copied, or reproduced in any manner, electronic or otherwise, without the express written consent of Volansys. ZWave 700 Module Datasheet TABLE OF CONTENTS 1 INTRODUCTION.....................................................................................................................................................4 1.1 PURPOSE........................................................................................................................................................... 4 1.2 SCOPE...............................................................................................................................................................4 1.3 ACRONYMS AND ABBREVIATIONS........................................................................................................................... 4 1.4 REFERENCES.......................................................................................................................................................4 1.5 DOCUMENT CONVENTIONS...................................................................................................................................4 1.6 COPYRIGHT INFORMATION....................................................................................................................................4 1.7 WARRANTY........................................................................................................................................................5 2 PRODUCT OVERVIEW............................................................................................................................................6 2.1 MODULE FEATURES.............................................................................................................................................8 2.2 SUGGESTED APPLICATIONS................................................................................................................................... 8 2.3 MODULE PIN DETAILS....................................................................................................................................... 10 2.4 MODULE PIN DETAILS....................................................................................................................................... 11 2.5 ANTENNA........................................................................................................................................................ 15 2.6 MODULE POWER ON/OFF................................................................................................................................ 17 2.7 MODULE RESET................................................................................................................................................17 2.8 DEBUG AND PROGRAMMING.............................................................................................................................. 18 3 ELECTRICAL CHARACTERISTICS...........................................................................................................................23 3.1 ABSOLUTE MAXIMUM RATINGS.......................................................................................................................... 23 3.2 RECOMMENDED OPERATING CONDITIONS.............................................................................................................24 3.3 RF CHARACTERISTICS.........................................................................................................................................24 3.4 RF RANGE....................................................................................................................................................... 26 3.5 MODULE DIMENSIONS.......................................................................................................................................27 4 CERTIFICATIONS.................................................................................................................................................. 29 5 APPLICATION NOTE.............................................................................................................................................30 5.1 SAFETY PRECAUTIONS........................................................................................................................................30 5.2 DESIGN ENGINEERING NOTES............................................................................................................................. 30 5.3 STORAGE CONDITIONS....................................................................................................................................... 31 ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 2 of 31 ZWave 700 Module Datasheet LIST OF FIGURES FIGURE 2-1 : ZWAVE 700 MODULE BLOCK DIAGRAM........................................................................................................6 FIGURE 2 -2 ZWAVE WITH SAW FILTER............................................................................................................................7 FIGURE 3 -3 : WITHOUT SAW FILTER AND WITH SAW FILTER............................................................................................. 8 FIGURE 2-4 : MODULE PIN DETAILS...............................................................................................................................10 FIGURE 2-5 : ANTENNA CONNECTOR............................................................................................................................. 15 FIGURE 2-6 : FLEX PATCH ANTENNA - 1......................................................................................................................... 16 FIGURE 2-7 : FLEX PATCH ANTENNA - 2......................................................................................................................... 16 FIGURE 2-8 : MODULE POWER ON/OFF PIN................................................................................................................. 17 FIGURE 2-9 : ZWAVE 700 MODULE PROGRAMMING INTERFACE........................................................................................18 FIGURE 2-10 : SLWSTK6050A EVK FOR ZWAVE 700 MODULES.................................................................................... 19 FIGURE 2-11 : SIMPLICITY STUDIO LAUNCH.....................................................................................................................19 FIGURE 2-12 : SIMPLICITY STUDIO - ADD PRODUCTS........................................................................................................ 20 FIGURE 2-13 : SIMPLICITY STUDIO - MY PRODUCTS......................................................................................................... 20 FIGURE 2-14 : SIMPLICITY STUDIO - CONNECT JTAG/SWD.............................................................................................. 21 FIGURE 2-15 : SIMPLICITY STUDIO - LOCATION OF BINARY FILES........................................................................................ 21 FIGURE 2-16 : SIMPLICITY STUDIO - SELECT BINARY FILES................................................................................................. 22 FIGURE 2-17 : SIMPLICITY STUDIO - FLASH BINARY FILES.................................................................................................. 22 FIGURE 3-1 : RF RANGE TEST DATA.............................................................................................................................. 26 FIGURE 3-2 : ZWAVE 700 MODULE - DIMENSIONS (FOR MOUNTING ON FEMALE HEADERS)...................................................27 FIGURE 3-3 : ZWAVE 700 MODULE - DIMENSIONS (FOR ASSEMBLY USING WAVE SOLDERING)................................................28 LIST OF TABLES TABLE 1 : ACRONYMS AND ABBREVIATIONS.......................................................................................................................4 TABLE 2 : REFERENCES................................................................................................................................................... 4 TABLE 3 : MODULE OPTIONS.......................................................................................................................................... 7 TABLE 4 : MODULE PIN DETAILS................................................................................................................................... 10 TABLE 5 : IO ALTERNATE FUNCTIONALITIES..................................................................................................................... 14 TABLE 6 : ABSOLUTE MAXIMUM RATINGS.......................................................................................................................23 TABLE 7 : RECOMMENDED OPERATING CONDITIONS.........................................................................................................24 TABLE 8 : RF CHARACTERISTICS - RECEIVER..................................................................................................................... 25 TABLE 9 : RF CHARACTERISTICS - TRANSMITTER...............................................................................................................25 Revision History Revision 1.0 Date 23-12-19 2.0 2.1 2.2 2.3 13-01-20 13-03-20 13-04-20 06-03-2021 Details of change Initial Draft Initial Draft - Updated the document as per the PCB revision 2.0 Added Volansys SKU in table 3. Added antennas to section 2.6 and added range test section 3.4 Added saw filter, Changed shield SD SD SD YP Author SD Reviewer Approver JB KB KB KB YP JB KB KB KB KB ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 3 of 31 ZWave 700 Module Datasheet 1 INTRODUCTION 1.1 Purpose 1.2 Scope The purpose of this document is to provide introduction to key features, architecture and other relevant electrical and mechanical characteristics of ZWave 700 module. The scope of this document is to explain in detail the design of the ZWave 700 module. This document is henceforth, to be used as a direct reference by end customers intending to use this product as per their use case. 1.3 Acronyms and abbreviations Terms NC NP PCB FER IO TBD RF Definition Not Connected Not Present Printed Circuit Board Frame Error Rate Input Output To Be Defined Radio Frequency Table 1: Acronyms and Abbreviations Provided By Volansys Volansys Table 2: References Remarks Primary reference N/A 1.4 References Reference Document Title Schematics Design Layout Design 1.5 Document Conventions Note:

A requirement may include an explanation of the requirement or the interaction between requirements, or other information useful in determining the intent of the requirement. The note, however, is not part of the requirement. Notes are indicated by the prefix Note, by verbs other than shall, or by enclosure in parentheses. 1.6 Copyright Information The information contained in this document is the proprietary information of Volansys Technology. The contents are confidential and any disclosure to persons other than the officers, employees, agents or subcontractors of the owner or licensee of this document, without the prior written consent of Volansys, is strictly prohibited. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 4 of 31 ZWave 700 Module Datasheet Further, no portion of this document may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, without the prior written consent of Volansys, the copyright holder. Volansys publishes this document without making any warranty as to the content contained herein. Further Volansys reserves the right to make modifications, additions and deletions to this document due to typographical errors, inaccurate information, or improvements to reference design platforms or products mentioned in the document at any time and without notice. Such changes will, nevertheless be incorporated into new editions of this document. 1.7 Warranty For details on the Volansys ZWave 700 module warranty policy, please Email us on :-

Business@volansystech.com ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 5 of 31 ZWave 700 Module Datasheet 2 PRODUCT OVERVIEW The ZWave 700 module is based on the Silicon Labs ZGM130S SiP module supporting the newer Z Wave 700 protocol and is a fully integrated ZWave module enabling rapid development of ZWave based solutions. The ZWave 700 module is built with low power gecko technology and is an ideal solution for energy friendly smart home control applications such as motion sensors, door/window sensors, access control, appliance control, energy management, etc in the Internet of Things. The ZWave 700 module is fully complaint with MikroBUS standard. Figure 2-1: ZWave 700 Module Block Diagram ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 6 of 31 ZWave 700 Module Datasheet Figure 2-2 Zwave with SAW Filter Sr Volansys SKU Description 1 MS-ZGM130S-WP-E-02-TH-NS Module without power control integrated pin without SAW 2 MS-ZGM130S-WP-E-02-TH-WS Module without power control integrated pin wave solderable. Without SAW 3 MS-ZGM130S-WP-E-03-TH-NS Module without power control integrated pin SAW Filter Table 3: Module Options ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 7 of 31 ZWave 700 Module Datasheet Figure 3-3 : Without SAW filter and with SAW filter 2.1 Module Features MikroBUS compatible 6 general purpose IOs Module ON/OFF control through IO pin ZWave 9.6/40/100 kbps data rates Supports all Zwave Sub-GHz bands (865.2 MHz - 926.3 MHz) TX power up to 13 dBm Range greater than 100 meters

-97.9 dBm sensitivity at 100 kbps GFSK 9.8 mA RX current at 100 kbps GFSK 13.3 mA TX current at 0 dBm output power ARM Cortex - M4+ floating point unit @ 39 MHz 64 KB application and ZWave framework flash 8 KB application RAM 2.2 Suggested Applications Smart homes Security ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 8 of 31 Lighting Health and wellness Metering Building automation ZWave 700 Module Datasheet 2.3 Application of SAW filters in Zwave In several regions, upload in the LTE band occurs at frequencies located closer than 10 MHz from frequencies used by Z-Wave. Due to the high power level allowed, in addition to the loose restrictions on side band emissions granted to the LTE band, the LTE upload may interfere significantly with the operation of a listening Z-Wave node located nearby. To reduce the impact from other devices, the Z-wave device must incorporate a SAW filter which attenuates these technologies, thus preventing saturation of the receiver. The effects of interference from LTE is outlined in LTE Case Study. For Z-Wave gateways (outside EU freq.) with LTE embedded, it is recommended to analyze the specific need for a SAW filter in depth. Optionally, a SAW filter bank can be added and controlled via the SAW0 and SAW1 output pins for operation in different regions This means:

No SAW SAW recommended End-devices and gateways without LTE modem embedded no SAW filter is recommend. Gateways on EU frequency with LTE modem embedded no SAW filter is recommend. Gateways with LTE embedded on U and H related frequencies using a SAW filter is recommend. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 9 of 31 2.4 Module Pin Details The pin detail for the ZWave 700 module is as described below:

Note: All the pin marked as IOx are multiplexed internally and can be used to realise interfaces as per the details mentioned in table 5. ZWave 700 Module Datasheet Module Pin Name J1.1 J1.2 J1.3 J1.4 J1.5 J1.6 J1.7 J1.8 Pin NC RST IO1 IO2 IO3 IO4 3.3V GND 1 2 3 4 5 6 7 8 AN RST CS SCK MISO MOSI 3.3V GND Pin NC PWR RX TX IO6 IO5 NC GND Module Pin Name J3.1 J3.2 J3.3 J3.4 J3.5 J3.6 J3.7 J3.8 PWM INT RX TX SCL SDA 5V GND 16 15 14 13 12 11 10 9 Table 4: Module Pin Details Figure 2-4: Module Pin Details ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 10 of 31 2.5 Module Pin Details By default, the ZWave 700 module is configured to communicate with the host using the UART interface which is available on the pins 3 and 4 on the header J3. Refer to figure 2 for location of ZWave 700 Module Datasheet these pins. The Zwave 700 module also has total of 6 pins which can be used as general purpose IO pins. These IOs are also internally multiplexed in the ZGM130S SiP module and can be programmed to operate as either IOs or interface pins. Interfaces such as I2C, SPI, UART can be realised using this feature on any of the 6 available IOs. Table below shows the pin muxing details of each of the 6 available IOs. This feature proves itself useful when realising end device use cases with the ZWave 700 module. IO No. Pin No. Pin Pin Alternate Functionalities Analog Timer Communication Radio Other IO1 J1.3 PA2 VDAC0_OUT1ALT /

OPA1_OUTALT #1 BUSDY BUSCX OPA0_P TIM0_CC0 #2 TIM0_CC1 #1 TIM0_CC2 #0 TIM0_CDTI0 #31 TIM0_CDTI1 #30 TIM0_CDTI2 #29 TIM1_CC0 #2 TIM1_CC1 #1 TIM1_CC2 #0 TIM1_CC3 #31 WTIM0_CC0 #2 WTIM0_CC1 #0 LETIM0_OUT0 #2 LETIM0_OUT1 #1 PCNT0_S0IN #2 PCNT0_S1IN #1 US0_TX #2 US0_RX

#1 US0_CLK #0 US0_CS #31 US0_CTS #30 US0_RTS #29 US1_TX #2 US1_RX

#1 US1_CLK #0 US1_CS #31 US1_CTS #30 US1_RTS #29 LEU0_TX #2 LEU0_RX #1 I2C0_SDA #2 I2C0_SCL #1 FRC_DCLK #2 FRC_DOUT #1 FRC_DFRAME #0 MODEM_DCLK #2 MODEM_DIN #1 MODEM_DOUT #0 PRS_CH6 #2 PRS_CH7 #1 PRS_CH8 #0 PRS_CH9 #10 ACMP0_O #2 ACMP1_O #2 LES_CH10 ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 11 of 31 IO2 J1.4 PA3 BUSCY BUSDX VDAC0_OUT0 /

OPA0_OUT IO3 J1.5 PA4 VDAC0_OUT1ALT /

OPA1_OUTALT #2 BUSDY BUSCX OPA0_N ZWave 700 Module Datasheet FRC_DCLK #3 FRC_DOUT #2 FRC_DFRAME #1 MODEM_DCLK #3 MODEM_DIN #2 MODEM_DOUT #1 PRS_CH6 #3 PRS_CH7 #2 PRS_CH8 #1 PRS_CH9 #0 ACMP0_O #3 ACMP1_O #3 LES_CH11 GPIO_EM4WU8 FRC_DCLK #4 FRC_DOUT #3 FRC_DFRAME #2 MODEM_DCLK #4 MODEM_DIN #3 MODEM_DOUT #2 PRS_CH6 #4 PRS_CH7 #3 PRS_CH8 #2 PRS_CH9 #1 ACMP0_O #4 ACMP1_O #4 LES_CH12 TIM0_CC0 #3 TIM0_CC1 #2 TIM0_CC2 #1 TIM0_CDTI0 #0 TIM0_CDTI1 #31 TIM0_CDTI2 #30 TIM1_CC0 #3 TIM1_CC1 #2 TIM1_CC2 #1 TIM1_CC3 #0 WTIM0_CC0 #3 WTIM0_CC1 #1 LETIM0_OUT0 #3 LETIM0_OUT1 #2 PCNT0_S0IN #3 PCNT0_S1IN #2 TIM0_CC0 #4 TIM0_CC1 #3 TIM0_CC2 #2 TIM0_CDTI0 #1 TIM0_CDTI1 #0 TIM0_CDTI2 #31 TIM1_CC0 #4 TIM1_CC1 #3 TIM1_CC2 #2 TIM1_CC3 #1 WTIM0_CC0 #4 WTIM0_CC1 #2 WTIM0_CC2 #0 LETIM0_OUT0 #4 LETIM0_OUT1 #3 PCNT0_S0IN #4 PCNT0_S1IN #3 US0_TX #3 US0_RX

#2 US0_CLK #1 US0_CS #0 US0_CTS

#31 US0_RTS #30 US1_TX #3 US1_RX

#2 US1_CLK #1 US1_CS #0 US1_CTS

#31 US1_RTS #30 LEU0_TX #3 LEU0_RX #2 I2C0_SDA #3 I2C0_SCL #2 US0_TX #4 US0_RX

#3 US0_CLK #2 US0_CS #1 US0_CTS

#0 US0_RTS #31 US1_TX #4 US1_RX

#3 US1_CLK #2 US1_CS #1 US1_CTS

#0 US1_RTS #31 LEU0_TX #4 LEU0_RX #3 I2C0_SDA #4 I2C0_SCL #3 ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 12 of 31 IO4 J1.6 PA5 VDAC0_OUT0ALT /

OPA0_OUTALT #0 BUSCY BUSDX ZWave 700 Module Datasheet FRC_DCLK #5 FRC_DOUT #4 FRC_DFRAME #3 MODEM_DCLK #5 MODEM_DIN #4 MODEM_DOUT #3 CMU_CLKI0 #4 PRS_CH6 #5 PRS_CH7 #4 PRS_CH8 #3 PRS_CH9 #2 ACMP0_O #5 ACMP1_O #5 LES_CH13 ETM_TCLK #1 TIM0_CC0 #5 TIM0_CC1 #4 TIM0_CC2 #3 TIM0_CDTI0 #2 TIM0_CDTI1 #1 TIM0_CDTI2 #0 TIM1_CC0 #5 TIM1_CC1 #4 TIM1_CC2 #3 TIM1_CC3 #2 WTIM0_CC0 #5 WTIM0_CC1 #3 WTIM0_CC2 #1 LETIM0_OUT0 #5 LETIM0_OUT1 #4 PCNT0_S0IN #5 PCNT0_S1IN #4 TIM0_CC0 #29 TIM0_CC1 #28 TIM0_CC2 #27 TIM0_CDTI0 #26 TIM0_CDTI1 #25 TIM0_CDTI2 #24 TIM1_CC0 #29 TIM1_CC1 #28 TIM1_CC2 #27 TIM1_CC3 #26 LETIM0_OUT0 #29 LETIM0_OUT1 #28 PCNT0_S0IN #29 PCNT0_S1IN #28 US0_TX #5 US0_RX

#4 US0_CLK #3 US0_CS #2 US0_CTS

#1 US0_RTS #0 US1_TX #5 US1_RX

#4 US1_CLK #3 US1_CS #2 US1_CTS

#1 US1_RTS #0 US2_TX #0 US2_RX

#31 US2_CLK #30 US2_CS #29 US2_CTS #28 US2_RTS #27 LEU0_TX #5 LEU0_RX #4 I2C0_SDA #5 I2C0_SCL #4 US0_TX #29 US0_RX

#28 US0_CLK #27 US0_CS #26 US0_CTS #25 US0_RTS #24 US1_TX #29 US1_RX

#28 US1_CLK #27 US1_CS #26 US1_CTS #25 US1_RTS #24 US2_TX #18 US2_RX

#17 US2_CLK #16 US2_CS #15 US2_CTS #14 US2_RTS #13 LEU0_TX #29 LEU0_RX #28 I2C0_SDA #29 I2C0_SCL #28 IO5 J3.6 PF5 BUSAY BUSBX FRC_DCLK #29 FRC_DOUT #28 FRC_DFRAME #27 MODEM_DCLK #29 MODEM_DIN #28 MODEM_DOUT #27 PRS_CH0 #5 PRS_CH1 #4 PRS_CH2 #3 PRS_CH3 #2 ACMP0_O #29 ACMP1_O #29 ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 13 of 31 IO6 J3.5 PF4 BUSBY BUSAX ZWave 700 Module Datasheet FRC_DCLK #28 FRC_DOUT #27 FRC_DFRAME #26 MODEM_DCLK #28 MODEM_DIN #27 MODEM_DOUT #26 PRS_CH0 #4 PRS_CH1 #3 PRS_CH2 #2 PRS_CH3 #1 ACMP0_O #28 ACMP1_O #28 TIM0_CC0 #28 TIM0_CC1 #27 TIM0_CC2 #26 TIM0_CDTI0 #25 TIM0_CDTI1 #24 TIM0_CDTI2 #23 TIM1_CC0 #28 TIM1_CC1 #27 TIM1_CC2 #26 TIM1_CC3 #25 LETIM0_OUT0 #28 LETIM0_OUT1 #27 PCNT0_S0IN #28 PCNT0_S1IN #27 US0_TX #28 US0_RX

#27 US0_CLK #26 US0_CS #25 US0_CTS #24 US0_RTS #23 US1_TX #28 US1_RX

#27 US1_CLK #26 US1_CS #25 US1_CTS #24 US1_RTS #23 US2_TX #17 US2_RX

#16 US2_CLK #15 US2_CS #14 US2_CTS #13 US2_RTS #12 LEU0_TX #28 LEU0_RX #27 I2C0_SDA #28 I2C0_SCL #27 Table 5: IO Alternate functionalities ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 14 of 31 ZWave 700 Module Datasheet 2.6 Antenna The Zwave 700 module needs an external antenna to transmit and receive the Zwave RF traffic. The external antenna can be connected to the module using the U.FL connector marked CN1 on the module. The antenna can be a patch, trace or whip antenna capable of resonating in the Zwave operating frequency range (865.2 - 926.3 MHz) and having an U.FL female connector for connecting to the RF path. Figure 2-5: Antenna Connector The Zwave 700 module is tested with the following two flex patch antennas. W3312B0100 (Pulse Larsen Antennas) ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 15 of 31 ZWave 700 Module Datasheet Figure 2-6: Flex Patch Antenna - 1 Following are the features of the antenna:

Frequency range: 863 MHz - 928 MHz Number of bands: 2 Return loss: -8 dB Gain: 0.8 dBi Mounting type: Adhesive Dimensions: 75 x 15 mm Termination: U.FL connector 2111400100 (Molex) Figure 2-7: Flex Patch Antenna - 2 Following are the features of the antenna:

Frequency range: 868 MHz - 928 MHz Number of bands: 2 Return loss: -5 dB Gain: 1 dBi Mounting type: Adhesive Dimensions: 38 x 10 mm Termination: U.FL connector ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 16 of 31 ZWave 700 Module Datasheet 2.7 Module Power ON/OFF ZWave 700 module has a functionality through which a user can cycle power to the module. This can be done by using the pin 2 of the header J3 (Pin 15 or INT in MikroBUS). A logic high (3.3V) at this pin will turn the module ON and a logic low (0V) at this pin will turn the module OFF. Continuous operation of the module will require a constant logic high at pin 2 of the header J3(Pin 15 or INT in MikroBUS). ZWave 700 module is also available with a direct power scheme if this functionality is not desired. Figure 2-8: Module Power ON/OFF Pin 2.8 Module Reset Pin 2 of the header J2 (Pin 2 or RST in MikroBUS) is to be used for resetting the module externally. The reset input pin is active low. This pin is already pulled up internally and so would not require any external pull-up resistors on the host boards. To apply an external reset to this pin, only drive this pin low during reset and let the internal pull-up ensure that the reset is released. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 17 of 31 2.9 Debug and Programming Programming of the ZWave 700 module can be done through the JTAG/SWD interface provided on the header J2. The pin out of the programming header is shown in the figure 5 below. ZWave 700 Module Datasheet Figure 2-9: ZWave 700 Module Programming Interface To program the Zwave 700 module, following are the prerequisites;

ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 18 of 31 Install Simplicity Studio version 4.1.11.4 on a Windows Machine. Install Flex SDK 2.6.2.0 and Gecko SDK Suite 2.6.2. Connect Debug header of the SLWSTK6050A with J2 interface of the ZWave 700 module using a compatible JTAG cable. ZWave 700 Module Datasheet More information on the EVK SLWSTK6050A , please refer to UG381: ZGM130S Zen Gecko Wireless Starter Kit Users Guide available here, https://www.silabs.com/documents/login/user-guides/ug381-brd4202a-user-guide.pdf Figure 2-10: SLWSTK6050A EVK For ZWave 700 Modules Follow the below mentioned steps to program a ZWave 700 module. 1. Launch simplicity studio in windows machine. 2. Select the EVK Kit to be used for flashing in the Simplicity Studio available at upper left corner as shown below. Figure 2-11: Simplicity Studio Launch ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 19 of 31 3. Select the compatible product in My Products Menu as shown below. In our case, it will be ZWave 700 Module Datasheet ZGM130S module. 4. Once added, the selected product should be populated as shown below. Figure 2-12: Simplicity Studio - Add Products Figure 2-13: Simplicity Studio - My Products ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 20 of 31 5. To flash the Z-Wave-700 module, select Simplicity Commander from the Compatible Tools. Once done, it should launch the simplicity commander window. ZWave 700 Module Datasheet 6. Select the J-Link device connected to the machine as shown below and press Connect. 7. Connect ZGM130S module using the JTAG/SWD protocol at 8000KHz.If the module is detected on the JTAG/SWD interface, the device should appear as shown below. Figure 2-14: Simplicity Studio - Connect JTAG/SWD 8. Select the Flash option available in the left pane. 9. Once done, select the appropriate binary file to be flashed on the Z-wave-700 module as shown in below images. Figure 2-15: Simplicity Studio - Location of Binary Files ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 21 of 31 ZWave 700 Module Datasheet Figure 2-16: Simplicity Studio - Select Binary Files Figure 2-17: Simplicity Studio - Flash Binary Files 10. After the above step, perform Flash operation and the binaries should flash successfully. Note: The flashing of Z-Wave-700 module can be also performed only by Simplicity commander without installation of Simplicity Studio. To perform flashing using this method, follow the steps 6

- 10. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 22 of 31 ZWave 700 Module Datasheet 3 ELECTRICAL CHARACTERISTICS 3.1 Absolute Maximum Ratings Parameter Symbol Test Condition Min Typ Max Unit Storage temperature range Stag

-40 Voltage on any supply pin VDDmax 3.3 Voltage ramp up rate on any supply pin VDDrampmax DC voltage on any IO pin Vdigpin Standard IO pins 5V tolerant IO pins Total current into supply pins IVDDmax Source Total current into VSS ground lines IVSSmax Current per IO pin IIOmax Source Sink Sink Sink Current for all IO pins IIOMaxall Source Junction temperature TJ

-40 Table 6: Absolute Maximum Ratings

1 V/us 200 mA 85 3.3 5.25 3.6 200 50 50 200 200 105 oC V V V mA mA mA mA mA oC ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 23 of 31 3.2 Recommended Operating Conditions Parameter Symbol Test Condition Min Typ Max Unit ZWave 700 Module Datasheet 25 3.3 3.3 3.3

oC V V V MHz Operating ambient temperature range TA

-G temperature grade

-40 AVDD supply voltage VAVDD VREGVDD supply voltage VVREGVDD VREGVDD current IVREGVDD 200 mA IOVDD operating voltage VIOVDD All IOVDD pins HFCLK frequency fHFCLK VSCALE2 Table 7: Recommended Operating Conditions 3.3 RF Characteristics Sub-GHz RF Receiver Characteristics for 915 MHz Band Parameter Symbol Test Condition Min Typ Max Unit RF tuning frequency range Frange 902

930 MHz Max usable input level, 1%

FER SAT100K 10 dBm Desired is reference 100 kbps GFSK signal Desired is reference 100 kbps GFSK signal, 1% FER, Frequency

= 916 MHz, T<=85 oC Sensitivity SENS

-97.5 dBm Level above which RFSENSE will trigger RFSENSETRIG CW at 915 MHz Level below which RFSENSE will not trigger RFSENSETHRES CW at 915 MHz Upper limit of input power range over which RSSI RSSIMAX

-28.1

-50 dBm dBm

5 dBm ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 24 of 31 85 3.8 3.8 3.8 39

resolution is maintained Lower limit of input power range over which RSSI resolution is maintained RSSIMIN ZWave 700 Module Datasheet

-98

RSSI resolution RSSIRES Over RSSIMIN to RSSIMAX range

0.25 Table 8: RF Characteristics - Receiver Sub-GHz RF Transmitter Characteristics for 915 MHz Band Parameter Symbol Test Condition Min Typ Max Unit RF tuning frequency range Frange 902 930 MHz Maximum TX power POUTmax 4 dBm output power setting Minimum active TX power POUTmin Output power step size POUTstep output power > 0 dBm Output power variation vs temperature, peak to peak POUTvar_t

-40 to 85 C Output power variation vs RF frequency POUTvar_f T=25 C, over specified RF frequency range

Table 9: RF Characteristics - Transmitter

4

-30 0.5 1.79 1.11

dBm dBm dBm dBm dB dB dB ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 25 of 31 ZWave 700 Module Datasheet RF Range 3.4 The ZWave 700 module has been tested to and proven to provide 130 meters range in Line of Sight

(LOS) measurements. The range measurements of the ZWave 700 module were taken using W3312B0100 flex patch antenna mounted on a 3 mm thick plate of ABS plastic to simulate the loading effect on the antenna and considers a Packet Error Rate (PER) of <= 10%. The figure below shows the lobe patterns of the used antenna. Figure 3-1: RF Range Test Data ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 26 of 31 3.5 Module Dimensions The Zwave 700 module comes in two versions. ZWave 700 Module Datasheet 1. MikroBUS complaint for mounting on female headers. (SKU: MS-ZGM130S-XX-E-02-TH-NS) 2. MikroBUS complaint for assembly with wave soldering. (SKU: MS-ZGM130S-XX-E-02-TH-WS) Figure 3-2: ZWave 700 Module - Dimensions (for mounting on female headers) ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 27 of 31 ZWave 700 Module Datasheet Figure 3-3: ZWave 700 Module - Dimensions (for assembly using wave soldering) ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 28 of 31 4 CERTIFICATIONS For ZWave 700 module, pre-compliance has been done as per FCC CFR 47 part 15C. Operation is ZWave 700 Module Datasheet subject to the following conditions:

This device may not cause harmful interference, and This device must accept any interference received, including interference that may cause undesirable operation. FCC RF Radiation Exposure Statement This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. End users must follow the specific operating instructions for satisfying RF exposure compliance. This transmitter meets both portable and mobile limits as demonstrated in the RF Exposure Analysis. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter except in accordance with FCC multi-transmitter product procedures. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 29 of 31 ZWave 700 Module Datasheet 5 APPLICATION NOTE Safety Precautions 5.1 These specifications are intended to preserve the quality assurance of products as individual components. Before use, check and evaluate the modules operation when mounted on your products. Abide by these specifications when using the products. These products may short-circuit. If electrical shocks, smoke, fire, and/or accidents involving human life are anticipated when a short circuit occurs, then provide the following fail safe functions as a minimum:

Ensure the safety of the whole system by installing a protection circuit and a protection device. Ensure the safety of the whole system by installing a redundant circuit or another system to prevent a single fault causing an unsafe status. 5.2 Design Engineering Notes Heat is the major cause of shortening the life of the modules. Avoid assembly and use of the target equipment in conditions where the products temperature may exceed the maximum allowable. Failure to do so may result in degrading of the products functions and damage to the product. If pulses or other transient loads (a large load applied in a short time) are applied to the products, before use, check and evaluate their operation when assembled onto your products. These products are not intended for other uses, other than under the special conditions shown below. Before using these products under such special conditions, check their performance and reliability under the said special conditions carefully, to determine whether or not they can be used in such a manner. In liquid, such as water, salt water, oil, alkali, or organic solvent, or in places where liquid may splash. In direct sunlight, outdoors, or in a dusty environment. In an environment where condensation occurs. In an environment with a high concentration of harmful gas (ex. salty air, HCl, Cl2, SO2, H2S, NH3, and NOx). If an abnormal voltage is applied due to a problem occurring in other components or circuits, replace these products with new products because they may not be able to provide normal performance even if their electronic characteristics and appearances appear satisfactory. Mechanical stress during assembly of the board and operation has to be avoided. Pressing on parts of the metal cover or fastening objects to the metal cover is not permitted. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 30 of 31 ZWave 700 Module Datasheet Storage Conditions 5.3 The module must not be stressed mechanically during storage. Do not store these products in the following conditions or the performance characteristics of the product, such as RF performance, may well be adversely affected:

Storage in salty air or in an environment with a high concentration of corrosive gas, such as Cl2, H2S, NH3, SO2, or NOX. Storage (before assembly of the end product) of the modules for more than one year after the date of delivery at your company even if all the above conditions (1) to (3) have been met, should be avoided. ZWave 700 Module Datasheet | Rev 2.3 | 03-06-20 Volansys-Confidential Page 31 of 31 FCC regulatory conformance 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.

(2) This device must accept any interference received, including interference that may cause undesired operation. NOTE: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures:

is connected.

- Reorient or relocate the receiving antenna.

- Increase the separation between the equipment and receiver.

-Connect the equipment into an outlet on a circuit different from that to which the receiver

-Consult the dealer or an experienced radio/TV technician for help NOTE: The manufacturer is not responsible for any radio or TV interference caused by unauthorized modifications to this equipment. Such modifications could void the users authority to operate the equipment. RF Exposure This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance of 20 cm between the radiator and your body. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. IC regulatory conformance This device complies with CAN ICES-003 (B)/NMB-003(B). This device contains licence-exempt transmitter(s)/receiver(s) that comply with Innovation, Science and Economic Development Canada's licence-exempt RSS(s). Operation is subject to the following two conditions:

(1) This device may not cause interference. undesired operation of the device.

(2) This device must accept any interference, including interference that may cause Cet appareil est conforme la norme CAN ICES-003 (B)/NMB-003 (B). Cet appareil contient des metteurs / rcepteurs exempt (s) de licence qui sont conformes aux RSS exemptes de licence d'Innovation, Sciences et Dveloppement conomique Canada. Son fonctionnement est soumis aux deux conditions suivantes:

(1) Cet appareil ne doit pas provoquer d'interfrences.

(2) Cet appareil doit accepter toute interfrence, y compris les interfrences susceptibles de provoquer un fonctionnement indsirable de l'appareil. RF Exposure This equipment complies with IC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance of 20 cm between the radiator and your body. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. Cet quipement est conforme aux limites d exposition aux rayonnements de la IC tablies pour unenvironnement non contr. Cet quipement doit tre install et fonctionner au moins 20cm de distance dun radiateur ou de votre corps. Unauthorized modifications could void the user's authority to operate the equipment. This radio transmitter [lC: 22256-CT200LTE50] has been approved by Innovation, Science and Economic Development Canada to operate with the antenna types listed below, with the maximum permissible gain indicated. Antenna types not included in this list that have a gain greater than the maximum gain indicated for any type listed are strictly prohibited for use with this device. Frequency range Manufacturer Peak gain Impedance Antenna type 908.4-916MHz Pulse larsen 777-1910MHz Shengdacom 1dBi 4dBi 50 50 FPC antenna External Antenna

Agent Authorization Company: Volansys Technologies Pvt Ltd Address: Block A-7th Floor, Safal Profitaire, Corporate Road, Prahladnagar, Ahmedabad-380015, Gujarat, India Product Name: CENTAURI 200 Enterprise/Industrial IoT Gateway Model Number(s): CT200-LTE-50 Equipment Description: CENTAURI 200 Enterprise/Industrial IoT Gateway We authorize MiCOM Labs Inc., 575 Boulder Court, Pleasanton, California 94566, USA, to act on our behalf on all matters concerning the certification of above named equipment. We declare that MiCOM Labs Inc. is allowed to forward all information related to the approval and certification of equipment to the regulatory agencies as required and to discuss any issues concerning the approval application. Any and all acts carried out by MiCOM Labs on our behalf shall have the same effect as acts of our own. Signature:

Name:

Title:

Dhaval Parikh VP-Engineering Company: Volansys Technologies Pvt Ltd Date: 2021-07-08

Date: 13 July 2021 Volansys Technologies Pvt. Ltd. To:

Federal Communications Commission, Authorization & Evaluation Division, 7435 Oakland Mills Road, Columbia, MD 21046 Re: Volansys Technologies Pvt. Ltd. FCC ID:2AKNO-CT200LTE50 FCC Certification Confidentiality Request Gentlemen:

This letter is to comply with 47 CFR 0.457 and 0.459 pertaining to confidentiality material. Volansys Technologies Pvt. Ltd. the following documents regarding this submission for FCC ID:2AKNO-CT200LTE50 be kept confidential:

requests that File Name Block Diagram.pdf Schematics.pdf Operational Description.pdf BOM.pdf Tune up procedure.pdf Exhibit Type Block Diagram Schematics Operational Description Part list Tune-Up-Procedure And below exhibit kept short-term confidential (180 days):

External photos Test setup photos Internal photos User manual External photos.pdf test photo.pdf Internal photos.pdf User manual.pdf Those documents contain detailed system and equipment description and related information about the product which Volansys Technologies Pvt. Ltd. considers to be confidential proprietary, a custom design and, otherwise, not releasable to the general public. Since this design is a basis form which future technological products will evolve, Volansys Technologies Pvt. Ltd. considers this information would be of benefit to its competitors, and that the disclosure of the information in these documents would give competitors an unfair advantage in the market. Yours Sincerely, ______________ Dhaval Parikh Block A - 7TH Floor, Safal Profitaire, Corporate Road, Prahaladnagar, Ahmedabad - 380 015, India

Volansys Technologies Pvt. Ltd. Date: 27 April 2021 To: Federal Communications Commission, Authorization & Evaluation Division, 7435 Oakland Mills Road, Columbia, MD 21046 To Whom It May Concern:

The Volansys Technologies Pvt. Ltd., the undersigned, hereby authorizes Mr. Wu Xuewen from Shenzhen BALUN Technology Co., Ltd., to act on the behalf of the Volansys Technologies Pvt. Ltd. solely in matters relating to the application for an FCC equipment authorization for FCC ID:

2AKNO-CT200LTE50 including the signing of documents in connection with this Application. Necessary acts carried out by Shenzhen BALUN Technology Co., Ltd. in connection with the Application shall have the same effect as acts of the Volansys Technologies Pvt. Ltd. The Volansys Technologies Pvt. Ltd. also hereby certify that no party to this application is subject to a denial of benefits, including FCC benefits, pursuant to Section 5301 of the Anti-Drug Abuse Act of 1988, 21 U.S.C. Section 862. Yours Sincerely, ____________ Dhaval Parikh Block A - 7TH Floor, Safal Profitaire, Corporate Road, Prahaladnagar, Ahmedabad - 380 015, India CIN: U72200GJ2008PTC055203

+91 79 4004 1994 info@volansys.com www.volansys.com