Difference between revisions of "Serial Port Voice Recognition Module V2"

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(Created page with "== Introduction == We all know that there is some kind of moudle that can control the light on and off by voice. If you make a sound, the light will turn on. Then after a whi...")
 
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We all know that there is some kind of moudle that can control the light on and off by voice. If you make a sound, the light will turn on. Then after a while the light turns off. This is not voice recognition. We may call it Sound Control. Voice recognition is something that knows exactly what you were saying. We've been thinking about a module which helps to control other devices by voice and it will not cost too much. Finally we designed this module. Well, what can this module do? It can recognize as many  as 15 voice instructions, which is suitable for most cases involving voice control.
 
We all know that there is some kind of moudle that can control the light on and off by voice. If you make a sound, the light will turn on. Then after a while the light turns off. This is not voice recognition. We may call it Sound Control. Voice recognition is something that knows exactly what you were saying. We've been thinking about a module which helps to control other devices by voice and it will not cost too much. Finally we designed this module. Well, what can this module do? It can recognize as many  as 15 voice instructions, which is suitable for most cases involving voice control.
  
[[File:serial voice v2.jpg]]
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[[File:1-173.jpg]]
 
 
  
 
== Features ==
 
== Features ==

Latest revision as of 05:16, 5 April 2016

Introduction

We all know that there is some kind of moudle that can control the light on and off by voice. If you make a sound, the light will turn on. Then after a while the light turns off. This is not voice recognition. We may call it Sound Control. Voice recognition is something that knows exactly what you were saying. We've been thinking about a module which helps to control other devices by voice and it will not cost too much. Finally we designed this module. Well, what can this module do? It can recognize as many as 15 voice instructions, which is suitable for most cases involving voice control.

1-173.jpg

Features

  • Voltage:4.5-5.5V
  • Current:<40mA
  • Digital Interface: 5V TTL level UART interface
  • Analog Interface: 3.5mm mono-channel microphone connector + microphone pin interface
  • Size: 30mm x 47.5mm

Usage

This module can store 15 pieces of voice instruction. Those 15 pieces are divided into 3 groups, with 5 in one group. First we should record the voice instructions group by group. After that, we should import one group by serial command before it could recognize the 5 voice instructions within that group. If we need to implement instructions in other groups, we should import the group first. This module is speaker-dependent. If your friend speaks the voice instruction instead of you, it may not identify the instruction.

Example

Here I will show you an example how to control RGB by voice.

1. Recording

M13 listing 1.jpg

We need to send serial command to this module. You may need a USB-TTL module (Product Page) to connect it with PC. Send command 0xaa11 to record. Please refer to the manual for more information. Please record the following voice instructions in order: 1. WHITE 2. RED 3. GREEN 4. BLUE 5. OFF Then send command 0xAA21 to import group 1.

2. Hardware connection

M13 listing 2.jpg

3. Code

<syntaxhighlight lang="c">

int redPin = 11; // R petal on RGB LED module connected to digital pin 11 int greenPin = 9; // G petal on RGB LED module connected to digital pin 9 int bluePin = 10; // B petal on RGB LED module connected to digital pin 10 byte com = 0; //reply from voice recognition

void setup() { Serial.begin(9600); pinMode(ledPin, OUTPUT); // sets the ledPin to be an output pinMode(redPin, OUTPUT); // sets the redPin to be an output pinMode(greenPin, OUTPUT); // sets the greenPin to be an output pinMode(bluePin, OUTPUT); // sets the bluePin to be an output delay(2000); Serial.write(0xAA); Serial.write(0x37); delay(1000); Serial.write(0xAA); Serial.write(0x21); }

void loop() // run over and over again {

while(Serial.available()) { com = Serial.read(); switch(com) { case 0x11: color(255,255,255); // turn RGB LED on -- white break;

case 0x12: color(255, 0, 0); // turn the RGB LED red break;

case 0x13: color(0,255, 0); // turn the RGB LED green break;

case 0x14: color(0, 0, 255); // turn the RGB LED blue break;

case 0x15: color(0,0,0); // turn the RGB LED off break;

} }

}

void color (unsigned char red, unsigned char green, unsigned char blue) // the color generating function { analogWrite(redPin, red*102/255); analogWrite(bluePin, blue*173/255); analogWrite(greenPin, green*173/255); }


</syntaxhighlight>


Upload the code above to Arduino. Please disconnect TX and RX while uploading code because uploading would occupy serial interface.

4. Video

After uploading is done, connect RX and TX, and then press RESET button on Arduino.

You can see the video on Youtube.