Hello everybody
made a project to open a lock with a sensor and for fun added a piezo sensor which works as a secret knock detector so there are two ways which activate the lock.
so the prototype worked started with the real project
powered everything with a usb from th computer in order to inspect the serial monitor
and it seem to work the sensor As well as the piezo . so disconnected the computer and powered with a usb via a usb wall plug 5v/2a and weired stuff started happening no longer works the LEDs which should work as indicators blink randomly and the relay opens and closes every 5 seconds in loop executes totally different
measured voltaaage All ok
what should i do? use a power supply? i have no idea how to solve it
using Arduino uno
Adafruit r503 fingerprint sensor
Wired as instructed
Red 3v
Black gnd
Green Tx
White Rx
attaching schematic
https://drive.google.com/file/d/1jjxJPGquXprIVF1iZj5lOBb5tH9-c8V_/view?usp=sharing
Thank you
#include <Adafruit_Fingerprint.h>
#if (defined(__AVR__) || defined(ESP8266)) && !defined(__AVR_ATmega2560__)
// For UNO and others without hardware serial, we must use software serial...
// pin #2 is IN from sensor (GREEN wire)
// pin #3 is OUT from arduino (WHITE wire)
// Set up the serial port to use softwareserial..
SoftwareSerial mySerial(2, 3);
#else
// On Leonardo/M0/etc, others with hardware serial, use hardware serial!
// #0 is green wire, #1 is white
#define mySerial Serial1
#endif
const int knockSensor = 0; // Piezo sensor on pin 0.
const int programSwitch = 7; // If this is high we program a new code.
const int lockMotor = 8; // Gear motor used to turn the lock.
const int redLED = 4; // Status LED
const int greenLED = 5; // Status LED
// Tuning constants. Could be made vars and hoooked to potentiometers for soft configuration, etc.
const int threshold = 7; // Minimum signal from the piezo to register as a knock
const int rejectValue = 25; // If an individual knock is off by this percentage of a knock we don't unlock..
const int averageRejectValue = 15; // If the average timing of the knocks is off by this percent we don't unlock.
const int knockFadeTime = 200; // milliseconds we allow a knock to fade before we listen for another one. (Debounce timer.)
const int lockTurnTime = 5000; // milliseconds that we run the motor to get it to go a half turn.
const int maximumKnocks = 20; // Maximum number of knocks to listen for.
const int knockComplete = 1111; // Longest time to wait for a knock before we assume that it's finished.
// Variables.
int secretCode[maximumKnocks] = {50, 25, 25, 50, 100, 50, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; // Initial setup: "Shave and a Hair Cut, two bits."
int knockReadings[maximumKnocks]; // When someone knocks this array fills with delays between knocks.
int knockSensorValue = 0; // Last reading of the knock sensor.
int programButtonPressed = false; // Flag so we remember the programming button setting at the end of the cycle.
Adafruit_Fingerprint finger = Adafruit_Fingerprint(&mySerial);
void setup()
{
pinMode(lockMotor, OUTPUT);
pinMode(redLED, OUTPUT);
pinMode(greenLED, OUTPUT);
pinMode(programSwitch, INPUT);
digitalWrite(greenLED, HIGH); // Green LED on, everything is go.
Serial.begin(9600);
while (!Serial); // For Yun/Leo/Micro/Zero/...
delay(100);
Serial.println("\n\nAdafruit finger detect test");
// set the data rate for the sensor serial port
finger.begin(57600);
delay(5);
if (finger.verifyPassword()) {
Serial.println("Found fingerprint sensor!");
} else {
Serial.println("Did not find fingerprint sensor :(");
while (1) { delay(1); }
}
Serial.println(F("Reading sensor parameters"));
finger.getParameters();
Serial.print(F("Status: 0x")); Serial.println(finger.status_reg, HEX);
Serial.print(F("Sys ID: 0x")); Serial.println(finger.system_id, HEX);
Serial.print(F("Capacity: ")); Serial.println(finger.capacity);
Serial.print(F("Security level: ")); Serial.println(finger.security_level);
Serial.print(F("Device address: ")); Serial.println(finger.device_addr, HEX);
Serial.print(F("Packet len: ")); Serial.println(finger.packet_len);
Serial.print(F("Baud rate: ")); Serial.println(finger.baud_rate);
finger.getTemplateCount();
if (finger.templateCount == 0) {
Serial.print("Sensor doesn't contain any fingerprint data. Please run the 'enroll' example.");
}
else {
Serial.println("Waiting for valid finger...");
Serial.print("Sensor contains "); Serial.print(finger.templateCount); Serial.println(" templates");
}
}
void loop() // run over and over again
{
// Listen for any knock at all.
knockSensorValue = analogRead(knockSensor);
//Serial.println(knockSensorValue);
if (digitalRead(programSwitch)==HIGH){ // is the program button pressed?
programButtonPressed = true; // Yes, so lets save that state
digitalWrite(redLED, HIGH); // and turn on the red light too so we know we're programming.
} else {
programButtonPressed = false;
digitalWrite(redLED, LOW);
}
if (knockSensorValue >= threshold){
listenToSecretKnock();
}
else {
getFingerprintID();
}
//delay(50); //don't ned to run this at full speed.
}
uint8_t getFingerprintID() {
uint8_t p = finger.getImage();
switch (p) {
case FINGERPRINT_OK:
Serial.println("Image taken");
break;
case FINGERPRINT_NOFINGER:
//Serial.println("No finger detected");
//finger.LEDcontrol(FINGERPRINT_LED_OFF, 0, FINGERPRINT_LED_PURPLE);
//finger.LEDcontrol(FINGERPRINT_LED_OFF, 0, FINGERPRINT_LED_RED);
return p;
case FINGERPRINT_PACKETRECIEVEERR:
Serial.println("Communication error");
return p;
case FINGERPRINT_IMAGEFAIL:
Serial.println("Imaging error");
return p;
default:
Serial.println("Unknown error");
return p;
}
// OK success!
p = finger.image2Tz();
switch (p) {
case FINGERPRINT_OK:
Serial.println("Image converted");
break;
case FINGERPRINT_IMAGEMESS:
Serial.println("Image too messy");
return p;
case FINGERPRINT_PACKETRECIEVEERR:
Serial.println("Communication error");
return p;
case FINGERPRINT_FEATUREFAIL:
Serial.println("Could not find fingerprint features");
return p;
case FINGERPRINT_INVALIDIMAGE:
Serial.println("Could not find fingerprint features");
return p;
default:
Serial.println("Unknown error");
return p;
}
// OK converted!
p = finger.fingerSearch();
if (p == FINGERPRINT_OK) {
Serial.println("Found a print match!");
finger.LEDcontrol(FINGERPRINT_LED_FLASHING, 25, FINGERPRINT_LED_PURPLE, 10);
delay(1000);
triggerDoorUnlock();
} else if (p == FINGERPRINT_PACKETRECIEVEERR) {
Serial.println("Communication error");
return p;
} else if (p == FINGERPRINT_NOTFOUND) {
finger.LEDcontrol(FINGERPRINT_LED_FLASHING, 25, FINGERPRINT_LED_RED, 10);
delay(1000);
Serial.println("Did not find a match");
return p;
} else {
Serial.println("Unknown error");
return p;
}
// found a match!
Serial.print("Found ID #"); Serial.print(finger.fingerID);
Serial.print(" with confidence of "); Serial.println(finger.confidence);
return finger.fingerID;
}
// Records the timing of knocks.
void listenToSecretKnock(){
Serial.println("tyk tuk tuk");
int i = 0;
// First lets reset the listening array.
for (i=0;i<maximumKnocks;i++){
knockReadings[i]=0;
}
int currentKnockNumber=0; // Incrementer for the array.
int startTime=millis(); // Reference for when this knock started.
int now=millis();
digitalWrite(greenLED, LOW); // we blink the LED for a bit as a visual indicator of the knock.
if (programButtonPressed==true){
digitalWrite(redLED, LOW); // and the red one too if we're programming a new knock.
}
delay(knockFadeTime); // wait for this peak to fade before we listen to the next one.
digitalWrite(greenLED, HIGH);
if (programButtonPressed==true){
digitalWrite(redLED, HIGH);
}
do {
//listen for the next knock or wait for it to timeout.
knockSensorValue = analogRead(knockSensor);
if (knockSensorValue >=threshold){ //got another knock...
//record the delay time.
Serial.println("knock.");
now=millis();
knockReadings[currentKnockNumber] = now-startTime;
currentKnockNumber ++; //increment the counter
startTime=now;
// and reset our timer for the next knock
digitalWrite(greenLED, LOW);
if (programButtonPressed==true){
digitalWrite(redLED, LOW); // and the red one too if we're programming a new knock.
}
delay(knockFadeTime); // again, a little delay to let the knock decay.
digitalWrite(greenLED, HIGH);
if (programButtonPressed==true){
digitalWrite(redLED, HIGH);
}
}
now=millis();
//did we timeout or run out of knocks?
} while ((now-startTime < knockComplete) && (currentKnockNumber < maximumKnocks));
//we've got our knock recorded, lets see if it's valid
if (programButtonPressed==false){ // only if we're not in progrmaing mode.
if (validateKnock() == true){
triggerDoorUnlock();
} else {
Serial.println("you are a spy.");
digitalWrite(greenLED, LOW); // We didn't unlock, so blink the red LED as visual feedback.
for (i=0;i<4;i++){
digitalWrite(redLED, HIGH);
delay(100);
digitalWrite(redLED, LOW);
delay(100);
}
digitalWrite(greenLED, HIGH);
}
} else { // if we're in programming mode we still validate the lock, we just don't do anything with the lock
validateKnock();
// and we blink the green and red alternately to show that program is complete.
Serial.println("New lock stored.");
digitalWrite(redLED, LOW);
digitalWrite(greenLED, HIGH);
for (i=0;i<3;i++){
delay(100);
digitalWrite(redLED, HIGH);
digitalWrite(greenLED, LOW);
delay(100);
digitalWrite(redLED, LOW);
digitalWrite(greenLED, HIGH);
}
}
}
// Sees if our knock matches the secret.
// returns true if it's a good knock, false if it's not.
// todo: break it into smaller functions for readability.
boolean validateKnock(){
int i=0;
// simplest check first: Did we get the right number of knocks?
int currentKnockCount = 0;
int secretKnockCount = 0;
int maxKnockInterval = 0; // We use this later to normalize the times.
for (i=0;i<maximumKnocks;i++){
if (knockReadings[i] > 0){
currentKnockCount++;
}
if (secretCode[i] > 0){ //todo: precalculate this.
secretKnockCount++;
}
if (knockReadings[i] > maxKnockInterval){ // collect normalization data while we're looping.
maxKnockInterval = knockReadings[i];
}
}
// If we're recording a new knock, save the info and get out of here.
if (programButtonPressed==true){
for (i=0;i<maximumKnocks;i++){ // normalize the times
secretCode[i]= map(knockReadings[i],0, maxKnockInterval, 0, 100);
}
// And flash the lights in the recorded pattern to let us know it's been programmed.
digitalWrite(greenLED, LOW);
digitalWrite(redLED, LOW);
delay(1000);
digitalWrite(greenLED, HIGH);
digitalWrite(redLED, HIGH);
delay(50);
for (i = 0; i < maximumKnocks ; i++){
digitalWrite(greenLED, LOW);
digitalWrite(redLED, LOW);
// only turn it on if there's a delay
if (secretCode[i] > 0){
delay( map(secretCode[i],0, 100, 0, maxKnockInterval)); // Expand the time back out to what it was. Roughly.
digitalWrite(greenLED, HIGH);
digitalWrite(redLED, HIGH);
}
delay(50);
}
return false; // We don't unlock the door when we are recording a new knock.
}
if (currentKnockCount != secretKnockCount){
return false;
}
/* Now we compare the relative intervals of our knocks, not the absolute time between them.
(ie: if you do the same pattern slow or fast it should still open the door.)
This makes it less picky, which while making it less secure can also make it
less of a pain to use if you're tempo is a little slow or fast.
*/
int totaltimeDifferences=0;
int timeDiff=0;
for (i=0;i<maximumKnocks;i++){ // Normalize the times
knockReadings[i]= map(knockReadings[i],0, maxKnockInterval, 0, 100);
timeDiff = abs(knockReadings[i]-secretCode[i]);
if (timeDiff > rejectValue){ // Individual value too far out of whack
return false;
}
totaltimeDifferences += timeDiff;
}
// It can also fail if the whole thing is too inaccurate.
if (totaltimeDifferences/secretKnockCount>averageRejectValue){
return false;
}
return true;
}
// Runs the motor (or whatever) to unlock the door.
void triggerDoorUnlock(){
Serial.println("Enter if you dare!");
int i=0;
// turn the motor on for a bit.
digitalWrite(lockMotor, HIGH);
digitalWrite(greenLED, HIGH); // And the green LED too.
delay (lockTurnTime); // Wait a bit.
digitalWrite(lockMotor, LOW); // Turn the motor off.
// Blink the green LED a few times for more visual feedback.
for (i=0; i < 5; i++){
digitalWrite(greenLED, LOW);
delay(100);
digitalWrite(greenLED, HIGH);
delay(100);
}
}
Thank you