ver1
plans/ChannelPlan_EU868.h
- Committer:
- hnript
- Date:
- 2020-02-24
- Revision:
- 183:960b4e7df69d
- Parent:
- 172:7ec44396a51b
File content as of revision 183:960b4e7df69d:
/** __ ___ ____ _ ______ __ ____ __ ____ * / |/ /_ __/ / /_(_)__/_ __/__ ____/ / / __/_ _____ / /____ __ _ ___ / _/__ ____ * / /|_/ / // / / __/ /___// / / -_) __/ _ \ _\ \/ // (_-</ __/ -_) ' \(_-< _/ // _ \/ __/ __ * /_/ /_/\_,_/_/\__/_/ /_/ \__/\__/_//_/ /___/\_, /___/\__/\__/_/_/_/___/ /___/_//_/\__/ /_/ * Copyright (C) 2015 by Multi-Tech Systems /___/ * * * @author Jason Reiss * @date 10-31-2015 * @brief lora::ChannelPlan provides an interface for LoRaWAN channel schemes * * @details * */ #ifndef __CHANNEL_PLAN_EU868_H__ #define __CHANNEL_PLAN_EU868_H__ #include "Lora.h" #include "SxRadio.h" #include <vector> #include "ChannelPlan.h" namespace lora { const uint8_t EU868_125K_NUM_CHANS = 16; //!< Number of 125k channels in EU868 channel plan const uint8_t EU868_DEFAULT_NUM_CHANS = 3; //!< Number of defualt channels in EU868 channel plan const uint32_t EU868_125K_FREQ_BASE = 868100000; //!< Frequency base for 125k EU868 uplink channels const uint32_t EU868_125K_FREQ_STEP = 200000; //!< Frequency step for 125k EU868 uplink channels const uint32_t EU868_RX2_FREQ = 869525000; //!< Frequency default for second rx window in EU868 const uint8_t EU868_TX_POWER_MAX = 14; //!< Max power for EU868 channel plan // 0.1% duty cycle 863-868 // Limiting to 865-868 allows for 1% duty cycle const uint32_t EU868_MILLI_FREQ_MIN = 865000000; const uint32_t EU868_MILLI_FREQ_MAX = 868000000; const uint32_t EU868_MILLI_1_FREQ_MIN = 868700000; const uint32_t EU868_MILLI_1_FREQ_MAX = 869200000; // 1% duty cycle const uint32_t EU868_CENTI_FREQ_MIN = 868000000; const uint32_t EU868_CENTI_FREQ_MAX = 868600000; // 10% duty cycle const uint32_t EU868_DECI_FREQ_MIN = 869400000; const uint32_t EU868_DECI_FREQ_MAX = 869650000; // Below 7dBm there is no duty cycle for these frequencies // Up to 14dBm there is 1% duty cycle const uint32_t EU868_VAR_FREQ_MIN = 869700000; const uint32_t EU868_VAR_FREQ_MAX = 870000000; const uint32_t EU868_FREQ_MIN = 863000000; const uint32_t EU868_FREQ_MAX = 870000000; const uint8_t EU868_MIN_DATARATE = (uint8_t) DR_0; //!< Minimum transmit datarate for EU868 const uint8_t EU868_MAX_DATARATE = (uint8_t) DR_7; //!< Maximum transmit datarate for EU868 const uint8_t EU868_MIN_DATARATE_OFFSET = (uint8_t) 0; //!< Minimum transmit datarate for US915 const uint8_t EU868_MAX_DATARATE_OFFSET = (uint8_t) 5; //!< Maximum transmit datarate for US915 const uint8_t EU868_BEACON_DR = DR_3; //!< Default beacon datarate const uint32_t EU868_BEACON_FREQ = 869525000U; //!< Default beacon broadcast frequency class ChannelPlan_EU868 : public lora::ChannelPlan { public: /** * ChannelPlan constructor * @param radio SxRadio object used to set Tx/Rx config * @param settings Settings object */ ChannelPlan_EU868(); ChannelPlan_EU868(Settings* settings); ChannelPlan_EU868(SxRadio* radio, Settings* settings); /** * ChannelPlan destructor */ virtual ~ChannelPlan_EU868(); /** * Initialize channels, datarates and duty cycle bands according to current channel plan in settings */ virtual void Init(); /** * Get the next channel to use to transmit * @return LORA_OK if channel was found * @return LORA_NO_CHANS_ENABLED */ virtual uint8_t GetNextChannel(); /** * Add a channel to the ChannelPlan * @param index of channel, use -1 to add to end * @param channel settings to add */ virtual uint8_t AddChannel(int8_t index, Channel channel); /** * Get channel at index * @return Channel */ virtual Channel GetChannel(int8_t index); /** * Get rx window settings for requested window * RX_1, RX_2, RX_BEACON, RX_SLOT * @param window * @return RxWindow */ virtual RxWindow GetRxWindow(uint8_t window); /** * Get datarate to use on the join request * @return datarate index */ virtual uint8_t GetJoinDatarate(); /** * Calculate the next time a join request is possible * @param size of join frame * @returns LORA_OK */ virtual uint8_t CalculateJoinBackoff(uint8_t size); /** * Get next channel and set the SxRadio tx config with current settings * @return LORA_OK */ virtual uint8_t SetTxConfig(); /** * Set the SxRadio rx config provided window * @param window to be opened * @param continuous keep window open * @param wnd_growth factor to increase the rx window by * @return LORA_OK */ virtual uint8_t SetRxConfig(uint8_t window, bool continuous, uint16_t wnd_growth); /** * Set frequency sub band if supported by plan * @param sub_band * @return LORA_OK */ virtual uint8_t SetFrequencySubBand(uint8_t sub_band); /** * Callback for ACK timeout event * @return LORA_OK */ virtual uint8_t HandleAckTimeout(); /** * Callback for Join Accept packet to load optional channels * @return LORA_OK */ virtual uint8_t HandleJoinAccept(const uint8_t* buffer, uint8_t size); /** * Callback to for rx parameter setup ServerCommand * @param payload packet data * @param index of start of command buffer * @param size number of bytes in command buffer * @param[out] status to be returned in MoteCommand answer * @return LORA_OK */ virtual uint8_t HandleRxParamSetup(const uint8_t* payload, uint8_t index, uint8_t size, uint8_t& status); /** * Callback to for new channel ServerCommand * @param payload packet data * @param index of start of command buffer * @param size number of bytes in command buffer * @param[out] status to be returned in MoteCommand answer * @return LORA_OK */ virtual uint8_t HandleNewChannel(const uint8_t* payload, uint8_t index, uint8_t size, uint8_t& status); /** * Callback to for ping slot channel request ServerCommand * @param payload packet data * @param index of start of command buffer * @param size number of bytes in command buffer * @param[out] status to be returned in MoteCommand answer * @return LORA_OK */ virtual uint8_t HandlePingSlotChannelReq(const uint8_t* payload, uint8_t index, uint8_t size, uint8_t& status); /** * Callback to for beacon frequency request ServerCommand * @param payload packet data * @param index of start of command buffer * @param size number of bytes in command buffer * @param[out] status to be returned in MoteCommand answer * @return LORA_OK */ virtual uint8_t HandleBeaconFrequencyReq(const uint8_t* payload, uint8_t index, uint8_t size, uint8_t& status); /** * Callback to for adaptive datarate ServerCommand * @param payload packet data * @param index of start of command buffer * @param size number of bytes in command buffer * @param[out] status to be returned in MoteCommand answer * @return LORA_OK */ virtual uint8_t HandleAdrCommand(const uint8_t* payload, uint8_t index, uint8_t size, uint8_t& status); /** * Validate the configuration after multiple ADR commands have been applied * @return status to be returned in MoteCommand answer */ virtual uint8_t ValidateAdrConfiguration(); /** * Update duty cycle with at given frequency and time on air * @param freq frequency * @param time_on_air_ms tx time on air */ virtual void UpdateDutyCycle(uint32_t freq, uint32_t time_on_air_ms); /** * Get the time the radio must be off air to comply with regulations * Time to wait may be dependent on duty-cycle restrictions per channel * Or duty-cycle of join requests if OTAA is being attempted * @return ms of time to wait for next tx opportunity */ virtual uint32_t GetTimeOffAir(); /** * Get the channels in use by current channel plan * @return channel frequencies */ virtual std::vector<uint32_t> GetChannels(); /** * Get the channel datarate ranges in use by current channel plan * @return channel datarate ranges */ virtual std::vector<uint8_t> GetChannelRanges(); /** * Print log message for given rx window * @param wnd 1 or 2 */ virtual void LogRxWindow(uint8_t wnd); /** * Enable the default channels of the channel plan */ virtual void EnableDefaultChannels(); /** * Check if this packet is a beacon and if so extract parameters needed * @param payload of potential beacon * @param size of the packet * @param [out] data extracted from the beacon if this packet was indeed a beacon * @return true if this packet is beacon, false if not */ virtual bool DecodeBeacon(const uint8_t* payload, size_t size, BeaconData_t& data); protected: static const uint8_t EU868_TX_POWERS[8]; //!< List of available tx powers static const uint8_t EU868_RADIO_POWERS[21]; //!< List of calibrated tx powers static const uint8_t EU868_MAX_PAYLOAD_SIZE[]; //!< List of max payload sizes for each datarate static const uint8_t EU868_MAX_PAYLOAD_SIZE_REPEATER[]; //!< List of repeater compatible max payload sizes for each datarate typedef struct __attribute__((packed)) { uint8_t RFU[2]; uint8_t Time[4]; uint8_t CRC1[2]; uint8_t GwSpecific[7]; uint8_t CRC2[2]; } BCNPayload; }; } #endif //__CHANNEL_PLAN_EU868_H__