Gesture Controlled Robot Ardunio

Gesture Controlled Robot Ardunio 

////gesture.ino
const int ap1 = A0;
const int ap2 = A1;
int sv1 = 0;      
int ov1 = 0;  
int sv2 = 0;    
int ov2= 0;
void setup()
{
  // initialize serial communications at 9600 bps:
  Serial.begin(9600);
  pinMode(13,OUTPUT);
  pinMode(12,OUTPUT);
  pinMode(11,OUTPUT);
  pinMode(10,OUTPUT);
}
void loop()
{
  analogReference(EXTERNAL);    //connect 3.3v to AREF
  // read the analog in value:
  sv1 = analogRead(ap1);          
   ov1 = map(sv1, 0, 1023, 0, 255);
  delay(2);                    
  sv2 = analogRead(ap2);          
 ov2 = map(sv2, 0, 1023, 0, 255);
    delay(2);                

  Serial.print("Xsensor1 = " );                      
  Serial.print(sv1);    
  Serial.print("\t output1 = ");    
  Serial.println(ov1);  

  Serial.print("Ysensor2 = " );                      
  Serial.print(sv2);    
  Serial.print("\t output2 = ");    
  Serial.println(ov2);  

  if(analogRead(ap1)<514 &&analogRead (ap2)<463) // for backward movement
  {
    digitalWrite(13,HIGH);
    digitalWrite(12,LOW);
    digitalWrite(11,HIGH);
    digitalWrite(10,LOW);
  }
  else
  {
    if(analogRead(ap1)<486 &&analogRead (ap2)>508) // for left turn
    {
      digitalWrite(13,LOW);
      digitalWrite(12,HIGH);
      digitalWrite(11,HIGH);
      digitalWrite(10,LOW);
    }
    else
    {
      if(analogRead(ap1)>512 &&analogRead (ap2)>560) // for forward
      {
        digitalWrite(13,LOW);
        digitalWrite(12,HIGH);
        digitalWrite(11,LOW);
        digitalWrite(10,HIGH);
      }
      else
      {
        if(analogRead(ap1)>550 &&analogRead (ap2)>512)//for right turn
        {
          digitalWrite(13,HIGH);
          digitalWrite(12,LOW);
          digitalWrite(11,LOW);
          digitalWrite(10,HIGH);
        }

        else
        {
          digitalWrite(13,HIGH);
          digitalWrite(12,HIGH);
          digitalWrite(11,HIGH);
          digitalWrite(10,HIGH);
        }
      }
    }
  }
}

The different between HC-03 HC-04 HC-05 HC-06

The different of HC-03/HC-04/HC-05/HC-06

The modules with the HC-03 and HC-05 firmware are the Master and Slave integrated Bluetooth serial modules with firmware which allows you to modify master and slave mode at any time. HC-03 are industrial grade products, HC-05 are commercial grade products.

The modules with the HC-04 and HC-06 firmware are the modules which are factory set to be Master or Slave modules. Master and slave mode cannot be switched from the factory setting. HC-04 is an industrial grade product, HC-06 is a commercial grade product.

The modules with the HC-09 firmware are replacements for the HC-06 and HC-07 modules.

The modules with Linvor firmware are the same as the HC-06 firmware modules (see above).

TPS-00641

Bluetooth Modem Bluetooth Modem

Difference between 8051 PIC and AVR Micrcontrollers

Difference between 8051,PIC and AVR Micrcontrollers 
A microcontroller (sometimes abbreviated µC, uC or MCU) is a small computer on a single integrated circuit containing a processor core, memory, and programmable input/output peripherals. Program memory in the form of Ferroelectric RAM, NOR flash or OTP ROMis also often included on chip, as well as a typically small amount of RAM. Microcontrollers are designed for embedded applications, in contrast to the microprocessors used in personal computers or other general purpose applications.

you'll have to study the architecture of all the 3 micros in question to know exact differences, but briefly we can distinguish between the 3 as:

8051 - 8 bit micro based on CISC architecture ( Complex Instruction Set Computer)

PIC - 8 bit micro based on RISC architecture ( Reduced Instruction Set Computer)

AVR - 8 bit micro based on RISC architecture ( Reduced Instruction Set Computer)


there are also 16bit and 32 bit micros from the same family

invention wise, 8051 is the forefather ( date of birth = 1985), next cam PIC s and then came the AVRs.


its essential to learn 8051 to be able to learn other micros. if we come to instruction set of these micros :

8051 has 250 instructions which take 1 to 4 machine cycles to executive
PIC has nearly 40 instructions which are mostly 4 cycles instructions
AVRs have 140 instructions whcih are mostly 1 cycle based

if we come to speed factor:

1 machine cycle in 8051 (normal) divides the clock freq. by 12 ( some derivatives divide by 6 and by 1 also)

1 machine cycle in PIC divides the clock freq by 4

1 M.C in AVRs divides the clock freq by 1

for eg: if we use 12 Mhz Xtal in all the 3 micros then the speed of execution will be as follows:

8051 = 12Mhz /12 = 1 Mhz i,e = 1 million instructions per second
PIC = 12Mhz/4 = 3 Mhz i,e = 3 million instructions per second
AVR = 12Mhz/1 = 12 MHz i,e = 12 Million instructions per second

so you can clearly see the that AVR executes more no:of instructions per given time and can be considered as the fastest among the 3.

also 8051 consumes more power than the other two and PIC consumes the least power.

Both PIC and AVR are RISC based but their instruction Sets are entirely different.

from Programming ( i,e writing code ) point of view : 8051s are easy to code , next come PIcs and last comes AVRs.

8051 has very powerful instruction set, it has commands which do more complex calculations, it also has got strong arithmetic logic unit which makes computation simple.

whereas PICs and AVRs have simple single instrcutions and the programmer has to tell (dictate) each and every step to achieve the final outcome.

for eg:

you would be surprised to know that normal AVRs do not have Multiplication instruction.

in 8051 Assembly we can simple use the instruction : MUL A,B

but in AVR you have to write some 20 lines of code to multiply two resgisters or values.

similiarly division also : in 8051 we have DIV A,B but in AVR again you have to write some 20 lines of code.

There is no ADD instruction in AVRs, in 8051 we can Compliment a port bit or a bit variable by using CPL instruction but in AVR we don't have this instruction.

in 8051 we can easily access the individual port bits but in AVRs we don't have this freedom.

8051 is still in use bcoz of its simplicity and popularity and lowest cost.

AVRs and PICS are costly and come with many on chip peripherals like : hardware SPI, ADC, I2C, USART , Analog comparator, internal RC oscillator, in-system programmablity etc.

also if see vendor support: 8051 are manufactured by over 50 companies whereas PIC & AVRs are manufactured only by their parent companies i,e microchip and Atmel.

for eg: if you are using a particular variant of AVR and Atmel discontinues it then you'll have no other choice than to shift to another variant offered by Atmel which may be costly and need program changes.

but with 8051 you can run the code in any 8051s manufactured by so many companies.

i hope my answer has given you enough insight into the topic.

16f877 A/D channel asm hex files

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;**********************************************************
;*  This program configures the A/D Module to convert on
;*  A/D channel 6 (the potentiometer) and display the
;*  results on the LEDS on PORTB.
;**********************************************************

list p=16f877
include "p16f877.inc"
goto Start


Start
;-----------INTIALISATION-------------------------------
BSF STATUS, RP0 ;
BCF STATUS, RP1;
movlw  b'11111111';
movwf TRISC
clrf PORTB ;Clear PORTB
clrf TRISB
clrf    PORTC
movlw B'01000000' ;Fosc/8, A/D enabled
movwf PIE1
movlw B'00000000' ;Left justify,1 analog channel
movwf ADCON1 ;VDD and VSS references
BCF STATUS,RP0;
movlw B'01101001' ;Fosc/8, A/D enabled
movwf ADCON0
;-------------ADC CHECK PROGRAM-----------------------
Main

bsf ADCON0,GO ;Start A/D conversion

Wait
btfss PIR1,ADIF ;Wait for conversion to complete
goto Wait

swapf ADRESH,W ;Swap A/D result nibbles
movwf PORTB ;Write A/D result to PORTB
clrf PORTB

WaitPush ;Pause while switch is pressed
btfsc PORTD,2 ; CHECK DIP SWITCH8
goto WaitPush
goto Main ;Do it again

;----------------------------THE END-------------------
end

SWG AWG Wire Gauge diameter Resistance Calculator

SWG-AWG  Wire Weight-Resistance Calculator

*Helpful Charts

Untinned copper wires
Stranded tinned copper wires SWG to AWG Conversion

See also

• American Wire Gauge (AWG), used primarily in the US and Canada
• Standard Wire Gauge (SWG), the British imperial standard BS3737
• Circular mil, Electrical industry standard for wires larger than 4/0.
• Jewelry wire gauge
• Body jewelry sizes

American Wire Gauge - Untinned copper wires

AWG standard notation Nominal diameter Cross-section area, mm X mm Running weight Running resistance mm inch g/m lb/1000 ft ohm/m ohm/1000 ft 10 2.600 0.1024 5.309 46.77 31.43 0.0033 0.999 11 2.300 0.0906 4.155 37.09 24.92 0.0041 1.260 12 2.050 0.0807 3.301 29.42 19.77 0.0052 1.588 13 1.830 0.0720 2.630 23.33 15.68 0.0066 2.003 14 1.630 0.0642 2.087 18.50 12.43 0.0083 2.525 15 1.450 0.0571 1.651 14.67 9.858 0.0104 3.184 16 1.290 0.0508 1.307 11.63 7.818 0.0132 4.016 17 1.150 0.0453 1.039 9.23 6.200 0.0166 5.064 18 1.020 0.0402 0.817 7.32 4.917 0.0209 6.385 19 0.912 0.0359 0.653 5.80 3.899 0.026 8.051 20 0.813 0.0320 0.519 4.60 3.092 0.033 10.15 21 0.724 0.0285 0.412 3.65 2.452 0.042 12.80 22 0.643 0.0253 0.325 2.89 1.945 0.053 16.14 23 0.574 0.0226 0.259 2.29 1.542 0.067 20.36 24 0.511 0.0201 0.205 1.82 1.223 0.084 25.67 25 0.455 0.0179 0.163 1.44 0.9699 0.106 32.37 26 0.404 0.0159 0.128 1.14 0.7692 0.134 40.81 27 0.361 0.0142 0.102 0.908 0.6100 0.169 51.47 28 0.320 0.0126 0.080 0.720 0.4837 0.213 64.90 29 0.287 0.0113 0.065 0.571 0.3836 0.268 81.83 30 0.254 0.0100 0.051 0.453 0.3042 0.339 103.2 31 0.226 0.0089 0.040 0.359 0.2413 0.427 130.1 32 0.203 0.0080 0.032 0.285 0.1913 0.538 164.1 33 0.180 0.0071 0.025 0.226 0.1517 0.679 206.9 34 0.160 0.0063 0.020 0.179 0.1203 0.856 260.9 35 0.142 0.0056 0.016 0.142 0.09542 1.086 331.0 36 0.127 0.0050 0.013 0.113 0.07568 1.361 414.8 37 0.114 0.0045 0.010 0.091 0.06130 1.680 512.1 38 0.102 0.0040 0.008 0.071 0.04759 2.128 648.6 39 0.089 0.0035 0.006 0.056 0.03774 2.781 847.8 40 0.079 0.0031 0.005 0.045 0.02993 3.543 1080.0 AWG standard notation mm inch Cross-section area mm X mm g/m lb/1000 ft ohm/m ohm/1000 ft Nominal diameter Running weight Running resistance Adjusted average wire diameter is calculated from the formula, as follows:

Valve_Radio_Receiver HAM and free resource

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Total Project Solutions
E7/83F, Ashoka Society
Arera Colony,Bhopal
462016(M.P.),India
+91-9826015410/9826050109
+91-755-2420735

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Simple Water Level Indicator cum Alarm

Get Electronics component online In India Visit www.onlineTPS.com

 Get Electronics component online In India Visit www.onlineTPS.com

 


Simple Water Level Indicator cum Alarm

Resistance at LED side is 1.5 K ohms