/* xdrv_48_timeprop.ino - Timeprop support for Sonoff-Tasmota Copyright (C) 2021 Colin Law and Thomas Herrmann This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #ifdef USE_TIMEPROP #ifndef FIRMWARE_MINIMAL /*********************************************************************************************\ * Code to drive one or more relays in a time proportioned manner give a * required power value. * * Given required power values in the range 0.0 to 1.0 the relays will be * driven on/off in such that the average power suppled will represent * the required power. * The cycle time is configurable. If, for example, the * period is set to 10 minutes and the power input is 0.2 then the output will * be on for two minutes in every ten minutes. * * A value for actuator dead time may be provided. If you have a device that * takes a significant time to open/close then set this to the average of the * open and close times. The algorithim will then adjust the output timing * accordingly to ensure that the output is not switched more rapidly than * the actuator can cope with. * * A facility to invert the output is provided which can be useful when used in * refrigeration processes and similar. * * In the case where only one relay is being driven the power value is set by * writing the value to the mqtt topic cmnd/timeprop_setpower_0. If more than * one relay is being driven (as might be the case for a heat/cool application * where one relay drives the heater and the other the cooler) then the power * for the second relay is written to topic cmnd/timeprop_setpower_1 and so on. * * To cope with the problem of temporary wifi failure etc a * TIMEPROP_MAX_UPDATE_INTERVALS value is available. This can be set to the max * expected time between power updates and if this time is exceeded then the * power will fallback to a given safe value until a new value is provided. Set * the interval to 0 to disable this feature. * * Usage: * Place this file in the sonoff folder. * Clone the library https://github.com/colinl/process-control.git from Github * into a subfolder of lib. * In user_config.h or user_config_override.h for a single relay, include * code as follows: #define USE_TIMEPROP // include the timeprop feature (+1.2k) // for single output #define TIMEPROP_NUM_OUTPUTS 1 // how many outputs to control (with separate alogorithm for each) #define TIMEPROP_CYCLETIMES 60 // cycle time seconds #define TIMEPROP_DEADTIMES 0 // actuator action time seconds #define TIMEPROP_OPINVERTS false // whether to invert the output #define TIMEPROP_FALLBACK_POWERS 0 // falls back to this if too long betwen power updates #define TIMEPROP_MAX_UPDATE_INTERVALS 120 // max no secs that are allowed between power updates (0 to disable) #define TIMEPROP_RELAYS 1 // which relay to control 1:8 * or for two relays: #define USE_TIMEPROP // include the timeprop feature (+1.2k) // for single output #define TIMEPROP_NUM_OUTPUTS 2 // how many outputs to control (with separate alogorithm for each) #define TIMEPROP_CYCLETIMES 60, 10 // cycle time seconds #define TIMEPROP_DEADTIMES 0, 0 // actuator action time seconds #define TIMEPROP_OPINVERTS false, false // whether to invert the output #define TIMEPROP_FALLBACK_POWERS 0, 0 // falls back to this if too long betwen power updates #define TIMEPROP_MAX_UPDATE_INTERVALS 120, 120 // max no secs that are allowed between power updates (0 to disable) #define TIMEPROP_RELAYS 1, 2 // which relay to control 1:8 * Publish values between 0 and 1 to the topic(s) described above * **/ #define D_CMND_TIMEPROP "timeprop_" #define D_CMND_TIMEPROP_SETPOWER "setpower_" // add index no on end (0:8) and data is power 0:1 #include "Timeprop.h" enum TimepropCommands { CMND_TIMEPROP_SETPOWER }; const char kTimepropCommands[] PROGMEM = D_CMND_TIMEPROP_SETPOWER; #ifndef TIMEPROP_NUM_OUTPUTS #define TIMEPROP_NUM_OUTPUTS 1 // how many outputs to control (with separate alogorithm for each) #endif #ifndef TIMEPROP_CYCLETIMES #define TIMEPROP_CYCLETIMES 60 // cycle time seconds #endif #ifndef TIMEPROP_DEADTIMES #define TIMEPROP_DEADTIMES 0 // actuator action time seconds #endif #ifndef TIMEPROP_OPINVERTS #define TIMEPROP_OPINVERTS false // whether to invert the output #endif #ifndef TIMEPROP_FALLBACK_POWERS #define TIMEPROP_FALLBACK_POWERS 0 // falls back to this if too long betwen power updates #endif #ifndef TIMEPROP_MAX_UPDATE_INTERVALS #define TIMEPROP_MAX_UPDATE_INTERVALS 120 // max no secs that are allowed between power updates (0 to disable) #endif #ifndef TIMEPROP_RELAYS #define TIMEPROP_RELAYS 1 // which relay to control 1:8 #endif static Timeprop timeprops[TIMEPROP_NUM_OUTPUTS]; static int relayNos[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_RELAYS}; static long currentRelayStates = 0; // current actual relay states. Bit 0 first relay struct { Timeprop timeprops[TIMEPROP_NUM_OUTPUTS]; int relay_nos[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_RELAYS}; long current_relay_states = 0; // current actual relay states. Bit 0 first relay long current_time_secs = 0; // a counter that counts seconds since initialisation } Tprop; /* call this from elsewhere if required to set the power value for one of the timeprop instances */ /* index specifies which one, 0 up */ void TimepropSetPower(int index, float power) { if (index >= 0 && index < TIMEPROP_NUM_OUTPUTS) { Tprop.timeprops[index].setPower( power, Tprop.current_time_secs); } } void TimepropInit(void) { // AddLog(LOG_LEVEL_INFO, PSTR("TPR: Timeprop Init")); int cycleTimes[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_CYCLETIMES}; int deadTimes[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_DEADTIMES}; int opInverts[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_OPINVERTS}; int fallbacks[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_FALLBACK_POWERS}; int maxIntervals[TIMEPROP_NUM_OUTPUTS] = {TIMEPROP_MAX_UPDATE_INTERVALS}; for (int i = 0; i < TIMEPROP_NUM_OUTPUTS; i++) { Tprop.timeprops[i].initialise(cycleTimes[i], deadTimes[i], opInverts[i], fallbacks[i], maxIntervals[i], Tprop.current_time_secs); } } void TimepropEverySecond(void) { Tprop.current_time_secs++; // increment time for (int i=0; i= 0 ? XdrvMailbox.topic : ""), (XdrvMailbox.data_len >= 0 ? XdrvMailbox.data : "")); */ if (0 == strncasecmp_P(XdrvMailbox.topic, PSTR(D_CMND_TIMEPROP), ua_prefix_len)) { // command starts with timeprop_ int command_code = GetCommandCode(command, sizeof(command), XdrvMailbox.topic + ua_prefix_len, kTimepropCommands); if (CMND_TIMEPROP_SETPOWER == command_code) { /* AddLog(LOG_LEVEL_INFO, PSTR("Timeprop command timeprop_setpower: " "index: %d data_len: %d payload: %d topic: %s data: %s"), XdrvMailbox.index, XdrvMailbox.data_len, XdrvMailbox.payload, (XdrvMailbox.payload >= 0 ? XdrvMailbox.topic : ""), (XdrvMailbox.data_len >= 0 ? XdrvMailbox.data : "")); */ if (XdrvMailbox.index >=0 && XdrvMailbox.index < TIMEPROP_NUM_OUTPUTS) { timeprops[XdrvMailbox.index].setPower( CharToFloat(XdrvMailbox.data), Tprop.current_time_secs ); } Response_P(PSTR("{\"" D_CMND_TIMEPROP D_CMND_TIMEPROP_SETPOWER "%d\":\"%s\"}"), XdrvMailbox.index, XdrvMailbox.data); } else { serviced = false; } } else { serviced = false; } return serviced; } /*********************************************************************************************\ * Interface \*********************************************************************************************/ #define XDRV_48 48 bool Xdrv48(uint32_t function) { bool result = false; switch (function) { case FUNC_INIT: TimepropInit(); break; case FUNC_EVERY_SECOND: TimepropEverySecond(); break; case FUNC_COMMAND: result = TimepropCommand(); break; case FUNC_SET_POWER: TimepropXdrvPower(); break; } return result; } #endif // FIRMWARE_MINIMAL #endif // USE_TIMEPROP