Beannachdan dha luchd-leughaidh na h-earrainn “DIY or Do It Yourself” air Habr! Bidh artaigil an-diugh mun suidse suathaidh air a’ chip TTP223 | . Bidh an suidse ag obair air an microcontroller nRF52832 | , chaidh modal YJ-17103 le antenna clò-bhuailte agus ceanglaiche airson antenna MHF4 taobh a-muigh a chleachdadh. Bidh an suidse suathaidh ag obair air bataraidhean CR2430 no CR2450. Chan eil caitheamh ann am modh tar-chuir nas motha na 8 mA, ann am modh cadail gun a bhith nas fhaide na 6 µA.
Coltach ris a h-uile pròiseact roimhe, tha am fear seo cuideachd na phròiseact Arduino, tha am prògram sgrìobhte anns an Arduino IDE. Tha buileachadh bathar-bog an inneil stèidhichte air protocol Mysensors | , ann am Mysensors. fòram coimhearsnachd na Beurla - , fòram coimhearsnachd cànan na Ruis -
(Dhaibhsan a tha airson ionnsachadh - , , , , | dhaibhsan a tha airson cuideachadh () ann an leasachadh a’ phròiseict - )
Chaidh am bòrd suidse suathaidh a leasachadh anns a’ phrògram Deeptrace, a’ toirt aire do shaothrachadh às deidh sin a’ cleachdadh an dòigh Teicneòlas iarnaigeadh Laser (LUT). Chaidh am bòrd a leasachadh ann an tomhasan 60x60mm (tha tomhasan de 80x80mm aig pannal glainne àbhaisteach). Chaidh an cuairteachadh a chlò-bhualadh air duilleagan iris Antenna agus a ghluasad le iarann Bosch leis an t-suidheachadh “Len” (an cumhachd as motha) air bòrd fiberglass foil le dà thaobh 1.5mm, 35µm (às aonais fear eile).
Chaidh sgeadachadh a dhèanamh le fuasgladh de chloride ferric, a chaidh ullachadh roimhe seo ann an cuibhreannan 1.5 spàin-tì gach 250 ml de uisge blàth. Thug am pròiseas 15 mionaidean.
Chaidh tuill drileadh airson vias interlayer agus airson an neach-gleidhidh bataraidh a cheangal le drile beag DREMEL 3000 air a chuir suas air seasamh drile DREMEL 220. Chaidh tuill airson vias interlayer a drileadh le drile 0,4mm, tuill airson an neach-gleidhidh bataraidh le drile 1,1mm . Chaidh bearradh air crìochan a’ bhùird a dhèanamh leis an aon drile beag le ceangal DREMEL 540 (Cearcall gearraidh d = 32.0mm). Chaidh an gearradh a dhèanamh ann an analach.
Chaidh a bhith a 'tinn a' bhùird eitseil le bhith a 'cleachdadh Rose alloy ann am fuasgladh uisgeach (1 teaspoon de dh' acid cititeach criostalach gach 300 ml de dh'uisge).
Thug am pròiseas solder timcheall air uair a thìde, chaidh a’ mhòr-chuid den ùine a chaitheamh a’ sèideadh uèir (tinn, 0.4 mm ann an trast-thomhas) anns na tuill airson vias interlayer.
Chaidh am bòrd a nighe le inneal-glanaidh aerosol FLUX OFF.
Chaidh dealbhadh corp an inneil a dhèanamh ann an deasaiche dealbhaidh trì-thaobhach le taic coimpiutair. Meud na cùise 78,5mm X 78,5mm X 12mm.
Chaidh am modail crìochnaichte den chùis agus còmhdach roinn bataraidh a shàbhaladh ann an cruth STL, agus an uairsin bha e riatanach na modalan sin ullachadh airson clò-bhualadh air clò-bhualadair SLA (a 'cur taic ris, stiùireadh). Aig an ìre seo, dh’ èirich duilgheadas beag, leis gu bheil raon clò-bhualaidh clò-bhualadairean dachaigh SLA beag. Cha robh modail cùis an inneil anns an t-suidheachadh as fheàrr an coimeas ri ùine clò-bhualaidh a’ freagairt ri tomhasan an àite clò-bhualaidh. Nuair a chuir e am modail aig 45 ceum, thug e cuideachd toradh briseadh-dùil; bha cuideam an taic co-ionann ri cuideam modail na buidhne. Chaidh co-dhùnadh am modail a chlò-bhualadh gu dìreach, a 'dèanamh taic air aon de na taobhan aghaidh, an dèidh aontachadh ro-làimh le fìrinn post-giollachd. Thug clò-bhualadh a’ chuirp 5 uairean le suidheachadh còmhdach de 50 micron. An uairsin, chaidh an giullachd a dhèanamh le bhith a’ cleachdadh pàipear-gainmhich fìor ghrinn (cha sgrìobh mi an àireamh oir chan eil fhios agam :)). Thug an còmhdach bataraidh 40 mionaid airson a chlò-bhualadh.
Bidh pannalan glainne bho Aliexpress air an reic le frèam plastaig air a ghleusadh mu thràth; cha robh duilgheadas sam bith ann le bhith a ’toirt air falbh am frèam. Thug mi air falbh am pannal glainne às deidh dhomh a bhith air a theasachadh le tiormaiche fuilt àbhaisteach.
Bha an diffuser airson an backlight LED air a dhèanamh de theip le dà thaobh le adhesive acrylic 3M 9088-200. Airson solais flùraiseach bha grunn stuthan ann airson taghadh, teip adhesive Sìneach agus pàipear adhesive air a ghearradh ann an teipichean bhon chompanaidh dachaigheil Luminofor. Chaidh an roghainn a dhèanamh airson neach-dèanamh dachaigheil; a rèir m ’fhaireachdainnean, bha e a’ deàrrsadh nas gile agus nas fhaide. Chaidh ceàrnag de phàipear le dath flùraiseach a ghleusadh air a’ mhullach le teip 3M 9088-200 le dà thaobh.
Chaidh a’ ghlainne a cheangal ris a’ bhodhaig suidse a’ cleachdadh teip le dà thaobh le adhesive acrylic 3M VHB 4910.
Chaidh an còmhdach a shuidheachadh le sgriubha M 1,4 X 5 mm.
B 'e cosgais an inneal 890 rubles.
An uairsin thàinig am pàirt den phrògram. Bha cuid de dhuilgheadasan ann. Tha e a ’tionndadh a-mach gu bheil sgoltagan mothachaidh TTP223 ag obair gu math le solar cumhachd 3.3V seasmhach agus nach eil e glè mhath nuair a thèid an cumhachd gu dìreach bho bataraidh a tha air a dheagh sgaoileadh. Nuair a thòisichear air an inneal le solar cumhachd timcheall air 2.5v, agus às deidh “tarraing sìos” a bharrachd nuair a bhathas ag obrachadh a-mach an taisbeanadh Mysensors, dh’ adhbhraich am microcircuit TTP223 (dìreach às deidh calibration) briseadh air an MK bhon a bha e le spionnadh gnìomhach.
Chaidh an cuairteachadh solar cumhachd chun microcircuit atharrachadh (riaghladh cumhachd TTP223 le gpio MK), chaidh talamh a bharrachd a thoirt seachad, agus chaidh resistors le neart nas àirde a chuir nan àite air na loidhnichean fo stiùir rgb (a tha a ’ruith air taobh eile a’ bhòrd mothachaidh capacitive). Chaidh a chur ris cuideachd am bathar-bog: gnìomhachadh cumhachd airson an capacitive microcircuit an dèidh tòiseachadh air frèam Mysensors agus obrachadh a-mach an taisbeanadh. Tha an dàil airson fèin-calibration a’ chip TTP223 nuair a thèid cumhachd a chuir an sàs air dùblachadh. Chuir na h-atharrachaidhean sin uile às don duilgheadas seo gu tur.
Mus coimhead thu air còd a ’phrògraim, tha mi a’ moladh gum bi thu eòlach air structar bunaiteach sgeidsichean ann an Mysensors.void before()
{
// Дополнительная функция, если сравнивать со стандартной структурой Ардуино скетчей, то before() это подобие setup(), отработка происходит до инициализации транспортного уровня Mysensors, рекомендуется например для инициализации устройств SPI
}
void setup()
{
}
void presentation()
{
//Тут происходит презентация ноды и ее сенсоров на контролере через маршрутизатор
sendSketchInfo("Name of my sensor node", "1.0"); // презентация названия ноды, версии ПО
present(CHILD_ID, S_WHATEVER, "Description"); // презентация сенсоров ноды, описания сенсоров
}
void loop()
{
}
Còd deuchainn prògram suidse suathaidh:deuchainn_sens.ino
/**
ТЕСТОВЫЙ СКЕТЧ СЕНСОРНОГО ВЫКЛЮЧАТЕЛЯ С ПРЕРЫВАНИЯМИ НА NRF_LPCOMP
*/
bool button_flag;
bool sens_flag;
bool send_flag;
bool detection;
bool nosleep;
byte timer;
unsigned long SLEEP_TIME = 21600000; //6 hours
unsigned long oldmillis;
unsigned long newmillis;
unsigned long interrupt_time;
unsigned long SLEEP_TIME_W;
uint16_t currentBatteryPercent;
uint16_t batteryVoltage = 0;
uint16_t battery_vcc_min = 2400;
uint16_t battery_vcc_max = 3000;
#define MY_RADIO_NRF5_ESB
//#define MY_PASSIVE_NODE
#define MY_NODE_ID 30
#define MY_PARENT_NODE_ID 0
#define MY_PARENT_NODE_IS_STATIC
#define MY_TRANSPORT_UPLINK_CHECK_DISABLED
#define IRT_PIN 3 //(PORT0, gpio 5)
#include <MySensors.h>
// see https://www.mysensors.org/download/serial_api_20
#define SENS_CHILD_ID 0
#define CHILD_ID_VOLT 254
MyMessage sensMsg(SENS_CHILD_ID, V_VAR1);
//MyMessage voltMsg(CHILD_ID_VOLT, V_VOLTAGE);
void preHwInit() {
sleep(2000);
pinMode(RED_LED, OUTPUT);
digitalWrite(RED_LED, HIGH);
pinMode(GREEN_LED, OUTPUT);
digitalWrite(GREEN_LED, HIGH);
pinMode(BLUE_LED, OUTPUT);
digitalWrite(BLUE_LED, HIGH);
pinMode(MODE_PIN, INPUT);
pinMode(SENS_PIN, INPUT);
}
void before()
{
NRF_POWER->DCDCEN = 1;
NRF_UART0->ENABLE = 0;
sleep(1000);
digitalWrite(BLUE_LED, LOW);
sleep(150);
digitalWrite(BLUE_LED, HIGH);
}
void presentation() {
sendSketchInfo("EFEKTA Sens 1CH Sensor", "1.1");
present(SENS_CHILD_ID, S_CUSTOM, "SWITCH STATUS");
//present(CHILD_ID_VOLT, S_MULTIMETER, "Battery");
}
void setup() {
digitalWrite(BLUE_LED, LOW);
sleep(100);
digitalWrite(BLUE_LED, HIGH);
sleep(200);
digitalWrite(BLUE_LED, LOW);
sleep(100);
digitalWrite(BLUE_LED, HIGH);
lpComp();
detection = false;
SLEEP_TIME_W = SLEEP_TIME;
pinMode(31, OUTPUT);
digitalWrite(31, HIGH);
/*
while (timer < 10) {
timer++;
digitalWrite(GREEN_LED, LOW);
wait(5);
digitalWrite(GREEN_LED, HIGH);
wait(500);
}
timer = 0;
*/
sleep(7000);
while (timer < 3) {
timer++;
digitalWrite(GREEN_LED, LOW);
sleep(15);
digitalWrite(GREEN_LED, HIGH);
sleep(85);
}
timer = 0;
sleep(1000);
}
void loop() {
if (detection) {
if (digitalRead(MODE_PIN) == 1 && button_flag == 0 && digitalRead(SENS_PIN) == 0) {
//back side button detection
button_flag = 1;
nosleep = 1;
}
if (digitalRead(MODE_PIN) == 1 && button_flag == 1 && digitalRead(SENS_PIN) == 0) {
digitalWrite(RED_LED, LOW);
wait(10);
digitalWrite(RED_LED, HIGH);
wait(50);
}
if (digitalRead(MODE_PIN) == 0 && button_flag == 1 && digitalRead(SENS_PIN) == 0) {
nosleep = 0;
button_flag = 0;
digitalWrite(RED_LED, HIGH);
lpComp_reset();
}
if (digitalRead(SENS_PIN) == 1 && sens_flag == 0 && digitalRead(MODE_PIN) == 0) {
//sens detection
sens_flag = 1;
nosleep = 1;
newmillis = millis();
interrupt_time = newmillis - oldmillis;
SLEEP_TIME_W = SLEEP_TIME_W - interrupt_time;
if (send(sensMsg.set(detection))) {
send_flag = 1;
}
}
if (digitalRead(SENS_PIN) == 1 && sens_flag == 1 && digitalRead(MODE_PIN) == 0) {
if (send_flag == 1) {
while (timer < 10) {
timer++;
digitalWrite(GREEN_LED, LOW);
wait(20);
digitalWrite(GREEN_LED, HIGH);
wait(30);
}
timer = 0;
} else {
while (timer < 10) {
timer++;
digitalWrite(RED_LED, LOW);
wait(20);
digitalWrite(RED_LED, HIGH);
wait(30);
}
timer = 0;
}
}
if (digitalRead(SENS_PIN) == 0 && sens_flag == 1 && digitalRead(MODE_PIN) == 0) {
sens_flag = 0;
nosleep = 0;
send_flag = 0;
digitalWrite(GREEN_LED, HIGH);
sleep(500);
lpComp_reset();
}
if (SLEEP_TIME_W < 60000) {
SLEEP_TIME_W = SLEEP_TIME;
sendBatteryStatus();
}
}
else {
//if (detection == -1) {
SLEEP_TIME_W = SLEEP_TIME;
sendBatteryStatus();
}
if (nosleep == 0) {
oldmillis = millis();
sleep(SLEEP_TIME_W);
}
}
void sendBatteryStatus() {
wait(20);
batteryVoltage = hwCPUVoltage();
wait(2);
if (batteryVoltage > battery_vcc_max) {
currentBatteryPercent = 100;
}
else if (batteryVoltage < battery_vcc_min) {
currentBatteryPercent = 0;
} else {
currentBatteryPercent = (100 * (batteryVoltage - battery_vcc_min)) / (battery_vcc_max - battery_vcc_min);
}
sendBatteryLevel(currentBatteryPercent, 1);
wait(2000, C_INTERNAL, I_BATTERY_LEVEL);
//send(powerMsg.set(batteryVoltage), 1);
//wait(2000, 1, V_VAR1);
}
void lpComp() {
NRF_LPCOMP->PSEL = IRT_PIN;
NRF_LPCOMP->ANADETECT = 1;
NRF_LPCOMP->INTENSET = B0100;
NRF_LPCOMP->ENABLE = 1;
NRF_LPCOMP->TASKS_START = 1;
NVIC_SetPriority(LPCOMP_IRQn, 15);
NVIC_ClearPendingIRQ(LPCOMP_IRQn);
NVIC_EnableIRQ(LPCOMP_IRQn);
}
void s_lpComp() {
if ((NRF_LPCOMP->ENABLE) && (NRF_LPCOMP->EVENTS_READY)) {
NRF_LPCOMP->INTENCLR = B0100;
}
}
void r_lpComp() {
NRF_LPCOMP->INTENSET = B0100;
}
#if __CORTEX_M == 0x04
#define NRF5_RESET_EVENT(event)
event = 0;
(void)event
#else
#define NRF5_RESET_EVENT(event) event = 0
#endif
extern "C" {
void LPCOMP_IRQHandler(void) {
detection = true;
NRF5_RESET_EVENT(NRF_LPCOMP->EVENTS_UP);
NRF_LPCOMP->EVENTS_UP = 0;
MY_HW_RTC->CC[0] = (MY_HW_RTC->COUNTER + 2);
}
}
void lpComp_reset () {
s_lpComp();
detection = false;
NRF_LPCOMP->EVENTS_UP = 0;
r_lpComp();
}
MyBoardNRF5.cpp
#ifdef MYBOARDNRF5
#include <variant.h>
/*
* Pins descriptions. Attributes are ignored by arduino-nrf5 variant.
* Definition taken from Arduino Primo Core with ordered ports
*/
const PinDescription g_APinDescription[]=
{
{ NOT_A_PORT, 0, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // LFCLK
{ NOT_A_PORT, 1, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // LFCLK
{ PORT0, 2, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A0, PWM4, NOT_ON_TIMER},
{ PORT0, 3, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A1, PWM5, NOT_ON_TIMER},
{ PORT0, 4, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A2, PWM6, NOT_ON_TIMER},
{ PORT0, 5, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A3, PWM7, NOT_ON_TIMER},
{ PORT0, 6, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT3
{ PORT0, 7, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT4
{ PORT0, 8, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM10, NOT_ON_TIMER}, //USER_LED
{ PORT0, 9, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // NFC1
{ PORT0, 10, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // NFC2
{ PORT0, 11, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // TX
{ PORT0, 12, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // RX
{ PORT0, 13, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // SDA
{ PORT0, 14, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // SCL
{ PORT0, 15, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // SDA1
{ PORT0, 16, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // SCL1
{ PORT0, 17, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // TP4
{ PORT0, 18, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // TP5
{ PORT0, 19, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT2
{ PORT0, 20, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT1
{ PORT0, 21, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT1
{ PORT0, 22, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM9, NOT_ON_TIMER},
{ PORT0, 23, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM8, NOT_ON_TIMER},
{ PORT0, 24, PIO_DIGITAL, PIN_ATTR_DIGITAL, No_ADC_Channel, NOT_ON_PWM, NOT_ON_TIMER}, // INT
{ PORT0, 25, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM11, NOT_ON_TIMER}, //RED_LED
{ PORT0, 26, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM11, NOT_ON_TIMER}, //GREEN_LED
{ PORT0, 27, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), No_ADC_Channel, PWM11, NOT_ON_TIMER}, //BLUE_LED
{ PORT0, 28, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A4, PWM3, NOT_ON_TIMER},
{ PORT0, 29, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A5, PWM2, NOT_ON_TIMER},
{ PORT0, 30, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A6, PWM1, NOT_ON_TIMER},
{ PORT0, 31, PIO_DIGITAL, (PIN_ATTR_DIGITAL|PIN_ATTR_PWM), ADC_A7, PWM0, NOT_ON_TIMER}
};
// Don't remove this line
#include <compat_pin_mapping.h>
#endif
MyBoardNRF5.h
#ifndef _MYBOARDNRF5_H_
#define _MYBOARDNRF5_H_
#ifdef __cplusplus
extern "C"
{
#endif // __cplusplus
// Number of pins defined in PinDescription array
#define PINS_COUNT (32u)
#define NUM_DIGITAL_PINS (32u)
#define NUM_ANALOG_INPUTS (8u)
#define NUM_ANALOG_OUTPUTS (8u)
/*
* LEDs
*
* This is optional
*
* With My Sensors, you can use
* hwPinMode() instead of pinMode()
* hwPinMode() allows to use advanced modes like OUTPUT_H0H1 to drive LEDs.
* https://github.com/mysensors/MySensors/blob/development/drivers/NRF5/nrf5_wiring_constants.h
*
*/
#define PIN_LED1 (16)
#define PIN_LED2 (15)
#define PIN_LED3 (17)
#define RED_LED (PIN_LED1)
#define GREEN_LED (PIN_LED2)
#define BLUE_LED (PIN_LED3)
#define INTERRUPT_PIN (5)
#define MODE_PIN (25)
#define SENS_PIN (27)
/*
* Analog ports
*
* If you change g_APinDescription, replace PIN_AIN0 with
* port numbers mapped by the g_APinDescription Array.
* You can add PIN_AIN0 to the g_APinDescription Array if
* you want provide analog ports MCU independed, you can add
* PIN_AIN0..PIN_AIN7 to your custom g_APinDescription Array
* defined in MyBoardNRF5.cpp
*/
static const uint8_t A0 = ADC_A0;
static const uint8_t A1 = ADC_A1;
static const uint8_t A2 = ADC_A2;
static const uint8_t A3 = ADC_A3;
static const uint8_t A4 = ADC_A4;
static const uint8_t A5 = ADC_A5;
static const uint8_t A6 = ADC_A6;
static const uint8_t A7 = ADC_A7;
/*
* Serial interfaces
*
* RX and TX are required.
* If you have no serial port, use unused pins
* CTS and RTS are optional.
*/
#define PIN_SERIAL_RX (11)
#define PIN_SERIAL_TX (12)
#ifdef __cplusplus
}
#endif
#endif
Tha putan suathaidh agus putan tact air cùl an inneil. Thèid am putan tact seo a chleachdadh airson modhan seirbheis, modh ceangail thar-an-adhair, agus ath-shuidheachadh inneal. Tha feart anti-breab iarainn aig a’ phutan. Tha loidhne an sensor capacitive agus loidhne a’ phutan gleoc ceangailte tro Schottky diodes agus ceangailte ris a ’phrìne analog p0.05, agus cuideachd bhon sensor capacitive agus am putan gleoc tha loidhnichean gu na prìnichean MK p0.25 agus p0.27 .0.05 airson stàitean leughaidh às deidh dhut a’ bhriseadh a chuir an gnìomh air prìne d0.05. XNUMX. Air prìne pXNUMX, thèid stad a chuir air a’ choimpiutair (NRF_LPCOMP) tro EVENTS_UP. Fhuair mi brosnachadh gus an duilgheadas fhuasgladh и .
Chaidh an tionndadh a chuir ris an lìonra Mysensors, air a riaghladh leis an rianadair dachaigh smart Majordomo ()
Còd PHP airson tionndadh a chur ris an dòigh statusUpdate
if (getGlobal("MysensorsButton01.status")==1) {
if (getGlobal('MysensorsRelay04.status') == 0) {
setGlobal('MysensorsRelay04.status', '1');
} else if (getGlobal('MysensorsRelay04.status') == 1) {
setGlobal('MysensorsRelay04.status', '0');
}
}
Faic an toradh anns a’ bhidio
Nas fhaide air adhart, chaidh roghainn a dhèanamh le inneal-tionndaidh àrdachadh, ach chan eil seo co-cheangailte ri gnìomhachd microcircuit capacitive TTP223; tha barrachd miann ann airson soillseachadh math agus èideadh nuair a bhios tu a ’brùthadh fad beatha a’ bhataraidh gu lèir.
Seall
Pròiseact Github saor an asgaidh -
Russian-labhairt Luchd-mothachaidh
- fuasgladh luath air duilgheadasan le Mysensors, molaidhean, cleasan, stàladh bùird, ag obair le atmega 328, stm32, nRF5 microcontrollers anns an Arduino IDE -
Cuid de dhealbhan
Source: www.habr.com