Make with Karkhana

This Video will illustrate you how to visualize audio left and right signals in bar-graph in 16X2 LCD Display using Arduino. Components Required: 1. Arduino UNO 2. 16X2 LCD Display 3. 3.5mm Audio Jack 4. Jumper Wires   Connection Diagram: Video Link Arduino Code #include <LiquidCrystal.h> #include <fix_fft.h> #define DEBUG 0 #define L_IN 1 // Audio input A0 Arduino #define R_IN 0 // Audio input A1 Arduino const int Yres = 8; const int gain = 3; float peaks[64]; char im[64], data[64]; char Rim[64], Rdata[64]; char data_avgs[64]; int debugLoop; int i; int load; LiquidCrystal lcd(11, 10, 7, 6, 5, 4); // pins to LCD // Custom CHARACTERS byte v1[8] = {   B00000, B00000, B00000, B00000, B00000, B00000, B00000, B11111 }; byte v2[8] = {   B00000, B00000, B00000, B00000, B00000, B00000, B00000, B11111 }; byte v3[8] = {   B00000, B00000, B00000, B00000, B00000, B11111, B11111, B11111 }; byte v4[8] = {   B00000, B00000, B00000, B0

This Blog will illustrate to you how to make Color changing Emblen light using the PWM of Arduino. using this you can make your emblems look more attractive. Video Link Components Required 1> Arduino UNO 2> 12V RGB led strip 3> 2N2222 Transistor 4> 10K ohm Resistor 5> Jumper Wires 6> Small Breadboard 7> Acrylic Engraved Emblem 8>IC7805 Power Regulator Circuit Diagram  Arduino Code const int greenPin = 10 ; const int bluePin = 9 ; void setup () { // Start off with the LED off. setColourRgb ( 0 , 0 , 0 ); } void loop () { unsigned int rgbColour[ 3 ]; // Start off with red. rgbColour[ 0 ] = 255 ; rgbColour[ 1 ] = 0 ; rgbColour[ 2 ] = 0 ;

This video will illustrate to you how to make a simple piano by using IR Modules. Based on the frequency of sa, re, ga, ma, pa, dha, ni and sa the tone of the buzzer will change. Video Link Components Required: 1> I.R. Modules 2> Arduino Uno 3> Jumper Wires 4>Small Breadboard Circuit Diagram Arduino Code: int button_C = 2; int button_D = 3; int button_E = 4; int button_F = 5; int button_G = 6; int button_A = 7; int button_B = 8; int button_Cup = 9; int speaker = 10; int buttonstate_C = 0; int buttonstate_D = 0; int buttonstate_E = 0; int buttonstate_F = 0; int buttonstate_G = 0; int buttonstate_A = 0; int buttonstate_B = 0; int buttonstate_Cup = 0; //NOTES         'c'  , 'd',  'e',  'f',  'g', 'a',  'b',  'C' int tones[] = { 240, 254, 285, 320, 359, 280, 427, 956 }; //freq int Cur_tone = 0; void setup() {   pinMode(button_C, OUTPUT);   pinMode(button_D, INPUT);   pinMode(button_E, INP

Hello Makers This Blog is about making a generic dancing bot which will move his hand entertainingly responsive to interruptions. Video Link Components you need: Arduino UNO  ( Click here to Buy Arduino UNO ) I.R. Module ( Click here to buy IR Module ) Servo-2 ( Click here to buy servos ) Jumper Wire ( Click here to buy jumper wire ) Cardboard ( Click here to buy cardboard ) Follow the steps and do the connections As given in Video Arduino Code : Servo myServo0;     //Object Name of your first Servo Servo myServo1;     //Object Name of your Second Servo int a;              //Variable to Store Value of IR int count = 0;      //A Counter Variable void setup() {   // put your setup code here, to run once:   myServo.attach(3);   //Attaching pin No. of first Servo will be 3   myServo1.attach(4);  //Attaching pin No. of first Servo will be 4   pinMode(5, INPUT);   //Attaching pin No. of IR   Serial.begin(9600);  //To Start your Serial Monitor } void loop() {   // put

Raspberry Pi, This tutorial is about the Voice Recording and Test to speech Using Raspberry Pi. But First, let's have a small introduction about Raspberry Pi. Introduction Raspberry Pi 3 Model B System on Chip(SoC) What is System on Chip?                 - A complex IC that integrates the major functional elements into a single chip or chipset. Programmable processors On-chip memory Accelerating function hardware (e.g. GPU) Both hardware and Software Analog components Benefits of SoC                   - Reduce overall system cost                   - Increase performance                   - Lower power consumption                   - Reduce size Soc in Raspberry Pi: Broadcom BCCM2835 SoC Multimedia Processor CPU             - ARM 1176JZF-S (armv6k) 700MHz             - RISC Architecture and low power draw             - Not compatible with traditional PC software GPU             - Broadcom Video IV             -

Hey Folks, In this tutorial, we will learn, how to change the colour of RGB LED using accelerometer of the ARM (FRDM-KL25Z). INTRODUCTION The FRDM-KL25Z is an ultra-low-cost development platform for Kinetis L Series KL1x (KL14/15) and KL2x (KL24/25) MCUs built on ARM® Cortex™-M0+ processor.  The FRDM-KL25Z has been designed by NXP in collaboration with mbed for prototyping all sorts of devices, especially those requiring the size and price point offered by Cortex-M0+ and the power of USB Host and Device. The FRDM-KL25Z is supported by a range of NXP and third-party development software. It is packaged as a development board with connectors to break out to stripboard and breadboard and includes a built-in USB FLASH programmer.               FEATURES NXP KL25Z Kinetis KL2x MCU (MKL25Z128VLK4) High-performance ARM® Cortex™-M0+ Core 48MHz, 16KB RAM, 128KB FLASH USB (Host/Device) SPI (2) I2C (2) UART (3) PWM (TPM) ADC (16 bit) DAC (1x 12bit) Touch Se

MQ-5 Module(Overview ) In this tutorial, will learn, how to interface MQ-5 Module with Node Mcu(ESP8266). The Grove - Gas Sensor(MQ5) module is useful for gas leakage detection (in home and industry). It is suitable for detecting H2, LPG, CH4, CO, Alcohol. Due to its high sensitivity and fast response time, measurements can be taken as soon as possible. The sensitivity of the sensor can be adjusted by using the potentiometer. MQ-5 Module(backside) Components Required NodeMcu(ESP8266)  MQ-5 LPG SENSOR Module  Few male to female connecting wires  Breadboard  Follow the image below for circuit connection reference:- In this circuit, we have connected the A0 pin of the MQ-5 to the A0 pin of the NodeMcu module and D0 pin remain disconnected. After making the circuit dump the code given below:- // Karkhana Report // Analyse the volume of the gas using thingspeak.com // Hardware: NodeMCU,MQ-5 #include <ESP8266WiFi.h> String apiKey = "Enter the API key

In this tutorial, we will learn how to interface a switch(push button) with ATMEGA16 using AVR studio. In the previous video, we learnt how to interface LEDs with ATMEGA16 using AVR studio. The push-button is a component that connects two points in a circuit when you press it. The example turns on an LED when you press the button. Here we have connected two push button to PORT C in  PC0 & PC1. And for LEDs connection please refer my previous blog. Components Required:- AVR Controller(Atmega16) LEDs Push Button Connecting Wires USBASP Programmer Dump the following code after connection  and select chip ATMEGA 16. #include<avr/io.h> #include<util/delay.h> void main()  {    DDRB=0b11111111;    int S1;    int S2;      while(1)    {     S1=PINC&0b00000001;     S2=PINC&0b00000010;     if(S1==0b00000001)     {      PORTB=0b00000001;      _delay_ms(100);      }      if(S2==0b00000010)     {      PORTB=0b00000010;      _delay_ms(100);  

In this tutorial, we will learn how to interface LED with Atmega16 using AVR Studio . An embedded system is built around a processor. The design goals of an embedded system are to reduce size, cost and power consumption and to increase performance and reliability. The microprocessor we are using is ATMEGA16 . The processor has limited internal memory, and if this is not sufficient for a given application external memory devices are used. The hardware also includes any components that facilitate the user-application interaction such as display units, keypad. The light-emitting diodes are used for getting status information, such as power on, check output(high/low). You all must have observed led decoration lights, which can glow in different patterns. First, we will learn to interface a single Led and then 8 LEDs to learn a simple toggling technique. Components Required:- AVR controller(Atmega16) LEDs Connecting wires USBASP Programmer For

In this tutorial, we will learn how to interface a servo motor using Arduino UNO. The motor inside the setup of a servo is attached by gears to the control wheel. When the motor rotates, the potentiometer’s resistance changes hence the control circuit can precisely regulate how much movement there is and in which direction. The motor’s speed is proportional to the difference between its actual position and desired position. When the shaft is near the desired position it turns slowly else fast. This is called proportional control. They are controlled by sending PWM (pulse width modulated) signals through the control wire. They are available in many sizes and are of three types Positional rotation  Continuous rotation  Linear The most common type is the positional rotational one. So now we are familiar with the motor let us interface it Components Required: Servo motor 1No Arduino UNO 1No Few connecting wires Breadboard Follow the video below for cir