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Saturday, July 20, 2013

Enable God Mode In Windows 7 And Vista

windows 7 god mode

In this tutorial i will show you to enable God Mode in Windows 7 and Windows Vista. By enabling God mode you can access all your windows setting from one folder and it makes really easy to access and change windows settings. This work 32 as well as 64 bit operating system. So lets enable God mode on your computer.

How to do it ?

  1. On your desktop right click and create a New Folder.
  2. Rename this folder to the code given below.

GodMode.{ED7BA470-8E54-465E-825C-99712043E01C}

  3. Done now double click on this folder and you will have access to all your windows operating system settings.

----Video Tutorial On Enabling God Mode:--
http://www.youtube.com/watch?feature=player_embedded&v=lcTfhevsQs4

Making Nameless Folder In Windows

creating nameless folder
In this small tutorial i will show you a smilpe windows trick. Basically you can not make folder with no name on windows. This trick will allow you to make folder without any name. This trick works on any windows  operating system.


How To Make Nameless Folder----------------------------------------

Before attempting this trick, try to make a folder with no name and you will fail to do so. This is what this trick will let you do. Below is screenshot of folder before and after doing this interesting trick.
creating nameless folder
creating nameless folder

>> Make a Newfolder on desktop or where ever you want.

Right click on this newly created folder and select Rename.

Erase the text showing "New Folder".

Now keep Pressing Alt (i.e alter key) and type 255. If you are on laptop then you need to enable your Num Lock and type from the highlighted number keys not from those below function keys.

After that leave alt key and Press enter.

Done you just created nameless folder.

HTC mobile secret codes


These codes work on most
HTC Mobile Phones

Phone information b>
*#*#7780#*#*
Battery information:
*#*#7780#*#*
Battery history: *#*#7780#*#*
This code for Bluetooth test:
*#*#232331#*#*
Bluetooth device address:
*#*#232337#*#
LCD test: *#*#0*#*#*
View RAM version:
*#*#3264#*#*
WiFi MAC address:
*#*#232338#*#*
Melody test: *#*#0673#*#* OR
*#*#0289#*#*
touch screen version:
*#*#2663#*#*
touch screen test:
*#*#2664#*#*
proximity sensor test:
*#*#0588#*#*
GPS test: *#*#1472365#*#* or
*#*#1575#*#*
PDA, Phone, H/W, RFCallDate:
*#*#4986*2650468#*#*
for PDA and Phone:
*#*#1234#*#*
FTA SW Version: *#*#1111#*#*
FTA HW Version: *#*#2222#*#*
This code for PDA, Phone, CSC,
Build Time,Changelist number:
*#*#44336#*#*
This code for Packet Loopback:
*#*#0283#*#*
to test device press(Vibrationt
and BackLight test also)
b>*#*#0842#*#*

Learning PHP, MYSQL and Javascript



     This book will help you to:----------------

Understand PHP essentials and the basics of object-oriented programming
Master MySQL, from database structure to complex queries
Create web pages with PHP and MySQL by integrating forms and other HTML features
Learn about JavaScript, from functions and event handling to accessing the Document Object Model
Use libraries and packages, including the Smarty web template system, PEAR program repository, and the Yahoo! User Interface Library
Make Ajax calls and turn your website into a highly dynamic environment

    NOTE : Password for the rar file is tricks4u
DOWNLOAD HERE

Programmable Home Security Alarm System






Introduction

In this project we design low cost high performance programmable home security system. This system uses a few LDR's as input sensors. When above sensor(s) get triggered system may dial the user specified phone number (using build-in DTMF generator) and activate the high power audio alarm and lights. All the parameters of DTMF generator, audio alarm and light interface are programmed through the RS232 serial interface.
Current firmware of this system presents interactive control system through the RS232 interface. This control system consist with the menu driven configuration options, self tests, system report generators, etc.
This system also contain 5W (with 4Ω speaker) audio alarm with three selectable tone configurations, which include Police siren, Fire engine siren and Ambulance siren.

System Features

- Touch tone phone dialing interface
- 5W High powerful audio alarm
- 2 sensor interface with separate sensitivity adjustments
- Programmed through the RS232 interface
- Build-In intelligent light ON/OFF switch


Integrated Circuits

This system uses a Microchip's PIC16F877A as a main controller, LM339 as sensor interface, UM3561 as a tone generator and μPC2002 as a speaker driver (audio amplifier). LM7805, LM7812 and LM317 voltage regulators are used to obtain +5V, +12V and +3V respectively.

Assembly



Fig.1 - Connectors, Jumpers and other controls of the Programmable Home Security Alarm System
The PCB design given with this article makes the assembly much simpler. As PCB contain 230V AC main lines care must be taken while assembling the circuit. As shown in the fig.1 all the photoelectric sensors, some of the switches and alarm speaker are connected with the circuit through the connector bars.

External connectors and controls

DC Power input : Attach DC power supply with 18V - 25V (2A Max.) output.
RS232 Connector : Connect RS232 serial cable to the port to configure the system. Do not use RS232 Null Modem cable with this port.
PHONE/LINE connector : Attach standard RJ12/RJ11 telephone cable connector to this port. One port is need to use with the phone line and remaining port is for the phone (and it is optional).
3V LASER supply : 3V supply line for LASER diode assembly.
Connectors for Sensor 1/2 : Attach high sensitive LDRs for these ports. To get the maximum sensitivity it is recommended to use EG&G VACTEC LDRs.
Status Indicator : Indicate run, program and sensor trigger modes.
Reset Switch : Press this button to reset entire alarm system. This button enable only when the audible alarm get activated. It is not possible to use this function at the phone dialing/ringer states.
Phone dialer enable switch : Turn on this switch to enable the phone dialing feature of this system. Environment Sensor :In-circuit LDR to detect light conditions of the environment.
Alarm Volume Control : Use this to control the output power (volume) of the audible alarm.
230V Light connector : Attach 230V AC light (or related peripheral) to these terminals.
Tone Selector : Configure the master alarm tone from this jumper as follows,
1-2 : Fire Engine Siren
2-3 : Ambulance Siren
Open : Police Siren
(Do not connect jumper terminal 1-3, this combination may permanently damage the entire system) Beeper : Produce beeps (e.g: at the input error, etc.)
Program / Run Switch connector : Attach switch to this header to select Program or Run mode.
Alarm Audio Output : Attach 8Ω (8W) or 4Ω (10W) speaker to this connector.

Calibration and Testing

Once everything is assembled take following steps to calibrate the system,
1. Remove IC1, IC2, IC3 and IC4 from the IC bases.
2. Apply 18V ( to 22V Max.) DC source to the power connector (J3).
3. Check the voltage between Pin12 (GND) and Pin3 of IC2. It need to be 4.8V - 5.1V DC.
4. Check the voltage between GND and E$4 jumper. It need to be 11.7V - 12.3V DC.
5. Check the voltage between Pin1 and Pin3 (GND) of JP1. It need to be 2.5V - 3.1 V
6. If all the above Step 3, 4 and 5 are correct, disconnect the power supply and insert IC1, IC2, IC3 and IC4 in to the appropriate IC bases. Attach suitable speaker to the X4 and connect RS232 cable to the system.
7. Close the jumper J2 (Program Mode) and power on the system.
8. Download and install PuTTY on to the target computer and setup the "Serial" connection with 9600 baud rate (see Fig. 3).

9. Press "2" and enter into the "Parameter Setup" mode. Configure all the parameter options with the appropriate settings.
10. Attach phone line to the PHONE/LINE connector and fix photoelectric LDR sensors to the X1 and X2 connectors.

Fig.2 - DTMF output generated by the system at the testing stages. (Test points : TRN1 input terminals)

11. Press "3" and execute "Self Test".
12. Adjust R4*, R6* and R8* preset controls, if the sensors are not trigged as expected.
13. Adjust R11 preset to control the "Day" and "Night" mode detection.
14. Open the Jumper J2 and press 5 to return to the Run mode.
15. Shutdown the power supply and disconnect the RS232 cable.


Fig.3 - PuTTY configuration setup for Programmable Home Security Alarm System
* R6 - X1 sensor sensitivity, R8 - X2 sensor sensitivity, R4 - sensor gain controller (Common mode)

Download





Schematic 



Click for higher resolution

PCB



Download Parts Layout in PDF format




Download PCB in PDF format





Download


Voltage Doubler Circuit Using IC 4049

The voltage doubler circuit is based on NOT gate CD4049 IC. We are utilizing all 6 gates of NOT gate. To understand the working you should know about the truth table of NOT gate are as follows-

In NOT gate, we will get output as logic high when logic zero is provided and we will get logic zero when logic1 is provided in input.


CD4049 contain six inverter gates in one package as shown in diagram. In this pin 3 is in and 2 is for output for  first gate similarly pin 5 is input and pin 4 is output for second gate similarly we have four more gate. In this 1 is for supply voltage and pin is connected to ground and pin 13 and 16 are unused pin.

In this circuit we are utilizing all six gates of NOT gate. Firstly we have made an oscillator with the help of gate 3 and 4, capacitor C1 and resistor  R1. The frequency of oscillation is determined by the value of R1 and C1. The remaining gates are joined in parallel to act as a buffer. Input pins 3, 5, 14 and 11 are connected together and join to the frequency source from oscillator. Similarly we have connected all output pin 2,4,15 and 12 and terminated to voltage enhancer circuit.

A voltage multiplier circuit can be made with the help of a diode and a capacitor. This can be used to generate more output voltage than the supplied input. Here we are using most popular commonly used half wave series multiplier.

The requirement to make a voltage doubler circuit is 2 diodes, 2 capacitors and an oscillating voltage. As you can see from the circuit in this diode D1 is forward bias and conducts which in turns chare the capacitor C2 to the peak value of input voltage which now turns as a battery in series with the power supply. At the same time D2 conducts because of D1 and charges capacitor C3.Therefore voltage across C3 will be sum of supply voltage and voltage across C2. The main advantage of this voltage doubler circuit is that it allows higher voltage to be created from a low source without the need of a transformer.

Hence at the output of Diode D2 you can operate 12V relay with the help of 6volts supply.
Also check the Voltage Doubler Circuit using 555 Timer IC


Wireless motor control through RF


 Wireless remote controlled toy cars work on the concept explained in this project. Motor control through RF communication is a very interesting application and is widely used in robotics, electronics toys, automation systems etc. This topic covers the way DC motors can be driven by using the controls from a distant place. The controls are transferred from one end to another by employing an RF module.

The remote control application of RF has been extended to operate a motor driver which in turn controls the direction of motors.

The circuit of this project uses RF module to control DC motors through a motor driver IC L293D. Transmission is enabled by giving a low bit to pin14 (TE, active low) of encoder HT12E. The controls for motor are first sent to HT12E. Pins 10 and 11 (D0-D1) are used to control one motor while pins 12 and 13 (D2-D3) to control another motor. The data signals of encoder HT12E work on negative logic. Therefore a particular signal is sent by giving a low bit to the corresponding data pin of encoder.

The parallel signals generated at transmission end are first encoded (into serial format) by HT12E and then transferred through RF transmitter (434 MHz) at a baud rate of around 1-10 kbps. The same signals are acquired by RF receiver after which it is decoded by HT12D. For more details, refer RF remote control.

Since the encoder/decoder pair used here works on negative logic, the decoded signals are fed to an inverter (NOT gate) IC 74LS04. The proper (inverted) signals are then supplied to L293D. L293D contains two inbuilt H-bridge driver circuits to drive two DC motors simultaneously, both in forward and reverse direction.

The motor operations of two motors can be controlled by input logic at pins 2 & 7 and pins 10 & 15. Input logic 00 or 11 will stop the corresponding motor. Logic 01 and 10 will rotate it in clockwise and anticlockwise directions, respectively. Thus, depending upon the signals generated at the transmission end, the two motors can be rotated in desired directions.
CIRCUIT DIAGRAM:---------

COMPONENTS:-----------------
L293D Motor Driver IC Image
66,465-Reads
L293D
L293D is a dual H-bridge motor driver integrated circuit (IC). Motor drivers act as current amplifiers since they take a low-current control signal and provide a higher-current signal. This higher current signal is used to drive the motors.

74LS04 | IC 7404
45,680-Reads
IC 74LS04
7404 is a NOT gate IC. It consists of six inverters which perform logical invert action. The output of an inverter is the complement of its input logic state,

HT12D | HT12D Decoder IC Image
30,929-Reads
HT12D Decoder IC
HT12D is a decoder integrated circuit that belongs to 212 series of decoders. This series of decoders are mainly used for remote control system applications, like burglar alarm, car door controller,

HT12E Encoder IC Image
39,648-Reads
HT12E Encoder IC
HT12E is an encoder integrated circuit of 212 series of encoders. They are paired with 212 series of decoders for use in remote control system...
RF Module : Transmitter & Receiver
105,249-Reads
RF Module (Transmitter & Receiver)

The RF module, as the name suggests, operates at Radio Frequency. The corresponding frequency range varies between 30 kHz & 300 GHz. In this RF system...