______ _ / _____) _ | | ( (____ _____ ____ _| |_ _____ ____| |__ \____ \| ___ | (_ _) ___ |/ ___) _ \ _____) ) ____| | | || |_| ____( (___| | | | (______/|_____)_|_|_| \__)_____)\____)_| |_| (C)2013 Semtech-Cycleo Basic communication protocol between Lora gateway and server ============================================================= 1. Introduction ---------------- The protocol between the gateway and the server is purposefully very basic and for demonstration purpose only, or for use on private and reliable networks. There is no authentication of the gateway or the server, and the acknowledges are only used for network quality assessment, not to correct UDP datagrams losses (no retries). 2. System schematic and definitions ------------------------------------ ((( Y ))) | | + - -|- - - - - - - - - - - - - + xxxxxxxxxxxx +--------+ | +--+-----------+ +------+ | xx x x xxx | | | | | | | | xx Internet xx | | | | Concentrator |<--->| Host |<-------xx or xx-------->| | | | | SPI | | | xx Intranet xx | Server | | +--------------+ +------+ | xxxx x xxxx | | | ^ ^ | xxxxxxxx | | | | PPS +-------+ NMEA | | | | | +-----| GPS |-------+ | +--------+ | | (opt) | | | +-------+ | | | | Gateway | +- - - - - - - - - - - - - - - -+ __Concentrator__: radio RX/TX board, based on Semtech multichannel modems (SX130x), transceivers (SX135x) and/or low-power stand-alone modems (SX127x). __Host__: embedded computer on which the packet forwarder is run. Drives the concentrator through a SPI link. __GPS__: GNSS (GPS, Galileo, GLONASS, etc) receiver with a "1 Pulse Per Second" output and a serial link to the host to send NMEA frames containing time and geographical coordinates data. Optional. __Gateway__: a device composed of at least one radio concentrator, a host, some network connection to the internet or a private network (Ethernet, 3G, Wifi, microwave link), and optionally a GPS receiver for synchronization. __Server__: an abstract computer that will process the RF packets received and forwarded by the gateway, and issue RF packets in response that the gateway will have to emit. It is assumed that the gateway can be behind a NAT or a firewall stopping any incoming connection. It is assumed that the server has an static IP address (or an address solvable through a DNS service) and is able to receive incoming connections on a specific port. 3. Upstream protocol --------------------- ### 3.1. Sequence diagram ### +---------+ +---------+ | Gateway | | Server | +---------+ +---------+ | -----------------------------------\ | |-| When 1-N RF packets are received | | | ------------------------------------ | | | | PUSH_DATA (token X, GW MAC, JSON payload) | |------------------------------------------------------------->| | | | PUSH_ACK (token X) | |<-------------------------------------------------------------| | ------------------------------\ | | | process packets *after* ack |-| | ------------------------------- | | | ### 3.2. PUSH_DATA packet ### That packet type is used by the gateway mainly to forward the RF packets received, and associated metadata, to the server. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | random token 3 | PUSH_DATA identifier 0x00 4-11 | Gateway unique identifier (MAC address) 12-end | JSON object, starting with {, ending with }, see section 4 ### 3.3. PUSH_ACK packet ### That packet type is used by the server to acknowledge immediately all the PUSH_DATA packets received. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | same token as the PUSH_DATA packet to acknowledge 3 | PUSH_ACK identifier 0x01 4. Upstream JSON data structure -------------------------------- The root object can contain an array named "rxpk": ``` json { "rxpk":[ {...}, ...] } ``` That array contains at least one JSON object, each object contain a RF packet and associated metadata with the following fields: Name | Type | Function :----:|:------:|-------------------------------------------------------------- time | string | UTC time of pkt RX, us precision, ISO 8601 'compact' format tmms | number | GPS time of pkt RX, number of milliseconds since 06.Jan.1980 tmst | number | Internal timestamp of "RX finished" event (32b unsigned) freq | number | RX central frequency in MHz (unsigned float, Hz precision) chan | number | Concentrator "IF" channel used for RX (unsigned integer) rfch | number | Concentrator "RF chain" used for RX (unsigned integer) stat | number | CRC status: 1 = OK, -1 = fail, 0 = no CRC modu | string | Modulation identifier "LORA" or "FSK" datr | string | LoRa datarate identifier (eg. SF12BW500) datr | number | FSK datarate (unsigned, in bits per second) codr | string | LoRa ECC coding rate identifier rssi | number | RSSI in dBm (signed integer, 1 dB precision) lsnr | number | Lora SNR ratio in dB (signed float, 0.1 dB precision) size | number | RF packet payload size in bytes (unsigned integer) data | string | Base64 encoded RF packet payload, padded Example (white-spaces, indentation and newlines added for readability): ``` json {"rxpk":[ { "time":"2013-03-31T16:21:17.528002Z", "tmst":3512348611, "chan":2, "rfch":0, "freq":866.349812, "stat":1, "modu":"LORA", "datr":"SF7BW125", "codr":"4/6", "rssi":-35, "lsnr":5.1, "size":32, "data":"-DS4CGaDCdG+48eJNM3Vai-zDpsR71Pn9CPA9uCON84" },{ "time":"2013-03-31T16:21:17.530974Z", "tmst":3512348514, "chan":9, "rfch":1, "freq":869.1, "stat":1, "modu":"FSK", "datr":50000, "rssi":-75, "size":16, "data":"VEVTVF9QQUNLRVRfMTIzNA==" },{ "time":"2013-03-31T16:21:17.532038Z", "tmst":3316387610, "chan":0, "rfch":0, "freq":863.00981, "stat":1, "modu":"LORA", "datr":"SF10BW125", "codr":"4/7", "rssi":-38, "lsnr":5.5, "size":32, "data":"ysgRl452xNLep9S1NTIg2lomKDxUgn3DJ7DE+b00Ass" } ]} ``` The root object can also contain an object named "stat" : ``` json { "rxpk":[ {...}, ...], "stat":{...} } ``` It is possible for a packet to contain no "rxpk" array but a "stat" object. ``` json { "stat":{...} } ``` That object contains the status of the gateway, with the following fields: Name | Type | Function :----:|:------:|-------------------------------------------------------------- time | string | UTC 'system' time of the gateway, ISO 8601 'expanded' format lati | number | GPS latitude of the gateway in degree (float, N is +) long | number | GPS latitude of the gateway in degree (float, E is +) alti | number | GPS altitude of the gateway in meter RX (integer) rxnb | number | Number of radio packets received (unsigned integer) rxok | number | Number of radio packets received with a valid PHY CRC rxfw | number | Number of radio packets forwarded (unsigned integer) ackr | number | Percentage of upstream datagrams that were acknowledged dwnb | number | Number of downlink datagrams received (unsigned integer) txnb | number | Number of packets emitted (unsigned integer) Example (white-spaces, indentation and newlines added for readability): ``` json {"stat":{ "time":"2014-01-12 08:59:28 GMT", "lati":46.24000, "long":3.25230, "alti":145, "rxnb":2, "rxok":2, "rxfw":2, "ackr":100.0, "dwnb":2, "txnb":2 }} ``` 5. Downstream protocol ----------------------- ### 5.1. Sequence diagram ### +---------+ +---------+ | Gateway | | Server | +---------+ +---------+ | -----------------------------------\ | |-| Every N seconds (keepalive time) | | | ------------------------------------ | | | | PULL_DATA (token Y, MAC@) | |------------------------------------------------------------->| | | | PULL_ACK (token Y) | |<-------------------------------------------------------------| | | +---------+ +---------+ | Gateway | | Server | +---------+ +---------+ | ------------------------------------------------------\ | | | Anytime after first PULL_DATA for each packet to TX |-| | ------------------------------------------------------- | | | | PULL_RESP (token Z, JSON payload) | |<-------------------------------------------------------------| | | | TX_ACK (token Z, JSON payload) | |------------------------------------------------------------->| ### 5.2. PULL_DATA packet ### That packet type is used by the gateway to poll data from the server. This data exchange is initialized by the gateway because it might be impossible for the server to send packets to the gateway if the gateway is behind a NAT. When the gateway initialize the exchange, the network route towards the server will open and will allow for packets to flow both directions. The gateway must periodically send PULL_DATA packets to be sure the network route stays open for the server to be used at any time. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | random token 3 | PULL_DATA identifier 0x02 4-11 | Gateway unique identifier (MAC address) ### 5.3. PULL_ACK packet ### That packet type is used by the server to confirm that the network route is open and that the server can send PULL_RESP packets at any time. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | same token as the PULL_DATA packet to acknowledge 3 | PULL_ACK identifier 0x04 ### 5.4. PULL_RESP packet ### That packet type is used by the server to send RF packets and associated metadata that will have to be emitted by the gateway. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | random token 3 | PULL_RESP identifier 0x03 4-end | JSON object, starting with {, ending with }, see section 6 ### 5.5. TX_ACK packet ### That packet type is used by the gateway to send a feedback to the server to inform if a downlink request has been accepted or rejected by the gateway. The datagram may optionnaly contain a JSON string to give more details on acknoledge. If no JSON is present (empty string), this means than no error occured. Bytes | Function :------:|--------------------------------------------------------------------- 0 | protocol version = 2 1-2 | same token as the PULL_RESP packet to acknowledge 3 | TX_ACK identifier 0x05 4-11 | Gateway unique identifier (MAC address) 12-end | [optional] JSON object, starting with {, ending with }, see section 6 6. Downstream JSON data structure ---------------------------------- The root object of PULL_RESP packet must contain an object named "txpk": ``` json { "txpk": {...} } ``` That object contain a RF packet to be emitted and associated metadata with the following fields: Name | Type | Function :----:|:------:|-------------------------------------------------------------- imme | bool | Send packet immediately (will ignore tmst & time) tmst | number | Send packet on a certain timestamp value (will ignore time) tmms | number | Send packet at a certain GPS time (GPS synchronization required) freq | number | TX central frequency in MHz (unsigned float, Hz precision) rfch | number | Concentrator "RF chain" used for TX (unsigned integer) powe | number | TX output power in dBm (unsigned integer, dBm precision) modu | string | Modulation identifier "LORA" or "FSK" datr | string | LoRa datarate identifier (eg. SF12BW500) datr | number | FSK datarate (unsigned, in bits per second) codr | string | LoRa ECC coding rate identifier fdev | number | FSK frequency deviation (unsigned integer, in Hz) ipol | bool | Lora modulation polarization inversion prea | number | RF preamble size (unsigned integer) size | number | RF packet payload size in bytes (unsigned integer) data | string | Base64 encoded RF packet payload, padding optional ncrc | bool | If true, disable the CRC of the physical layer (optional) Most fields are optional. If a field is omitted, default parameters will be used. Examples (white-spaces, indentation and newlines added for readability): ``` json {"txpk":{ "imme":true, "freq":864.123456, "rfch":0, "powe":14, "modu":"LORA", "datr":"SF11BW125", "codr":"4/6", "ipol":false, "size":32, "data":"H3P3N2i9qc4yt7rK7ldqoeCVJGBybzPY5h1Dd7P7p8v" }} ``` ``` json {"txpk":{ "imme":true, "freq":861.3, "rfch":0, "powe":12, "modu":"FSK", "datr":50000, "fdev":3000, "size":32, "data":"H3P3N2i9qc4yt7rK7ldqoeCVJGBybzPY5h1Dd7P7p8v" }} ``` The root object of TX_ACK packet must contain an object named "txpk_ack": ``` json { "txpk_ack": {...} } ``` That object contain status information concerning the associated PULL_RESP packet. Name | Type | Function :----:|:------:|------------------------------------------------------------------------------ error | string | Indication about success or type of failure that occured for downlink request. The possible values of "error" field are: Value | Definition :-----------------:|--------------------------------------------------------------------- NONE | Packet has been programmed for downlink TOO_LATE | Rejected because it was already too late to program this packet for downlink TOO_EARLY | Rejected because downlink packet timestamp is too much in advance COLLISION_PACKET | Rejected because there was already a packet programmed in requested timeframe COLLISION_BEACON | Rejected because there was already a beacon planned in requested timeframe TX_FREQ | Rejected because requested frequency is not supported by TX RF chain TX_POWER | Rejected because requested power is not supported by gateway GPS_UNLOCKED | Rejected because GPS is unlocked, so GPS timestamp cannot be used Examples (white-spaces, indentation and newlines added for readability): ``` json {"txpk_ack":{ "error":"COLLISION_PACKET" }} ``` 7. Revisions ------------- ### v1.4 ### * Added "tmms" field for GPS time as a monotonic number of milliseconds ellapsed since January 6th, 1980 (GPS Epoch). No leap second. ### v1.3 ### * Added downlink feedback from gateway to server (PULL_RESP -> TX_ACK) ### v1.2 ### * Added value of FSK bitrate for upstream. * Added parameters for FSK bitrate and frequency deviation for downstream. ### v1.1 ### * Added syntax for status report JSON object on upstream. ### v1.0 ### * Initial version.