Memory modules - DDR, DDR2 and DDR3

Memory modules - DDR, DDR2 and DDR3

SD, DDR, DDR2 and DDR3 are all different types of RAM (Random Access Memory). 

RAM is a kind of computer memory that temporarily stores information, improving your systems performance. 

Or in other words RAM simply holds data for the processor.

The processor also has its own memory known as the L2 cache, the cache lies between the processor and the RAM. The processor sends and retrieves data from this cache, when this cache overflows data is sent to the RAM.

There are mainly four types of RAM; SD, DDR, DDR2 and DDR3.

They differ in the way they operate and mainly in their operation speeds.

All RAM's used in computers today have a synchronous interface meaning they wait for a clock signal before it can respond to clock signals.

SD RAM:

SDRAM stands for synchronous dynamic random access memory.

SDRAM is Single Data Rate meaning that SDRAM can accept one command and transfer one word of data per clock cycle.

As mentioned above SDRAM's have synchronous interface therefore they depend on the computer clock signals to perform operations.

Typical speeds of SDRAM are 100 and 133 MHz.

DDR SDRAM:

DDR SDRAM stands for double data rate synchronous dynamic random access memory.

DDR RAM transfers data twice per clock cycle, hence the name double data rate.

DDR clock speeds range between 200 MHz (DDR-200) and 400 MHz (DDR-400).

DDR-200 transfers 1600 MB/s, while DDR-400 transfers 3200 MB/s.

DDR2 SDRAM:

DDR2 SDRAM stands for double data rate 2 synchronous dynamic random access memory.

DDR2 is twice as fast as DDR which means twice as much data is carried to the module for each clock cycle.

Also due to the design improvements DDR2 consumes less power as compared to the DDR memory.

DDR2 speeds range between 400 MHz (DDR2-400) and 800 MHz (DDR2-800).

DDR2-400 transfers 3200 MB/s.

DDR2-800 transfers 6400 MB/s.

DDR3 SDRAM:

So by now after reading the above it is quite obvious what DDR3 SDRAM stands for, double data rate 3 synchronous dynamic random access memory.

In theory DDR3 is supposed to act twice as fast as DDR2 memories.

Thus DDR3 speeds range between 800 MHz (DDR3-800) and

1600 MHz (DDR3-1600).

DDR3-800 transfers 6400 MB/s; DDR3-1600 transfers 12800 MB/s.

Only gamers may notice the difference between DDR2 and DDR3 speeds, while for everyone else, even DDR will be sufficient.

But if you are buying a new PC spending a little extra for the increased speed is always appreciated.

But in the end it all depends on your requirements and your budget.

DDR3 will cost a lot more than DDR2, also for DDR3 speeds you will also need a motherboard that can support it, so if you are planning on upgrading your RAM to DDR3 you should be certain that your motherboard can support it.

If your requirements do not involve heavy gaming or video editing and video processing then you have no need for the powerful DDR3 memory.

Automatic Bathroom Light Switch

Automatic Bathroom Light Switch

 Here is a simple and low cost automatic bathroom light circuit. The light automatically turns on when the bathroom door is opened, and remains lit in the occupied state. When the door is opened again the lamp turns off after a very short delay. This automatic circuit saves energy and greatly assists your visitors, especially at night. The “single-chip” circuit, built around the popular decade counter CD4017 (IC1), is very compact, and can be powered from any 5VDC/500mA mobile phone travel charger/similar smps adaptor. After construction, try to enclose the whole circuit in a suitable plastic case for total convenience. Next, arrange the door switch (S1) such that when the door is closed it should be in closed state.

Schematic of the Automatic Bathroom Light Control Circuit

Circuit Tested at TechNode on 12 March 2014

4017 datasheet

How does the automatic toiled light works?
The heart of this circuit is CD4017 (IC1), CMOS counter with decoded output. On each pulse received on its clock input, this IC drives high the next output. Output 0 (pin 3) of IC1 drives a green “Toilet Free” indicator (LED1), and output 1 (pin 2) of IC1 drives the 1W light source (LED2) through a driver transistor (T1). Note that T1 (2N2222) is here wired as an emitter-follower to avoid the use of a base resistor.
Initially when the circuit is powered, IC1 is resetted by the RC network R1-C1 and as a result LED1 lights up. When the door is opened for the first time, switch S1 is opened and as a result IC1 is clocked by the clock pulse generator R2-C2. Now LED1 goes off and LED2 lights up. IC1 stays in this condition to provide the interior lighting, even if the door is closed. However, when the bathroom door is opened again IC1 is clocked again, and this resets the chip by the signal from Output 2 (pin 4) of IC1 through D1 (1N4148). When IC1 activates its Output 2 and reset itself, LED1 lights up again!

Component Selection
Regarding components selection, nothing is really critical. But try to use a good quality “normally-opened” (N/O) switch as S1. The 3.6V/1W White LED (LED2) current is limited by resistor R3. It may become necessary to adjust this value to get the best from your circuit.

• IC1: CD4017
• T1: 2N2222
• D1: 1N4148
• LED1: 5mm Green
• LED2: 3.6V/1W White
• R1: 10K ¼ w
• R2: 100K ¼ w
• R3: 2.2Ω ¼ w (see text)
• R4: 1K ¼ w
• C1,C2 : 10µF/16V
• C3: 100nF
• S1: N/O Push Switch (see text)
• J1: DC Socket – PCB mountable

Lab Note

Clock pulse (DSO probed at Pin 14 of IC1)

Since the clock generator for IC1 is realized using a tricky RC network, erratic switching may be occurred. Although the bumps are rare, you can defeat this by adding a manual reset switch (again one N/O push switch) between +5V and pin 15 of IC1.


Thanks: http://www.electroschematics.com

Resistor Calculator

 5 Band Resistor Calculator

 This is a helpful site to calculate 4 band as well as 5 band resistor. Simply select the color code in order and find the value of a resister with Resistance Tolerance

 http://www.eeweb.com/toolbox/5-band-resistor-calculator

Electronic Stethoscope

 Electronic Stethoscope

An electronic stethoscope is used to listen to your heartbeat and you would normally use a listening tube or stethoscope. This electronic stethoscope circuit uses a piezo sounder from a musical greetings card or melody generator, as a microphone. This transducer has an output signal in the order of 100 mV and its low frequency response is governed by the input impedance of the amplifier.

For this reason we have chosen to use an emitter follower transistor amplifier. This has a high input impedance and ensures that the transducer will have a very low frequency response. At the output you just need to connect a set of low impedance headphones to be able to listen to your heartbeat.
Replacing the emitter follower with a Darlington transistor configuration will further increase the input impedance of the amplifier.

Electronic Stethoscope Circuit diagram

 
piezo sounder

Electronic fly dis-infestation

Electronic fly dis-infestation

 Electronic Fly utilizes high-voltage power line applied pulse voltage killed OCS flies. Use the web site when the bait to attract flies, fly Fly online for all to be able to kill flies. Electronic Fly circuit as shown, when the base integrated circuit ICl 555 and resistors Rl, R2 and capacitor Cl composition astable oscillator circuit from the output frequency of ICl ③ feet around 30Hz, continuous duty cycle of 10% square wave. The square wave is coupled through resistor R3 to the transistor VTl, VT2, boosted promote amplification step-up transformer T, so that the high voltage transformer secondary is connected with the IED kV grid, in order to achieve the function of killing flies. Fly No. l4 wire mesh making available adjacent wire distance of about 6mm. To prevent children inadvertently high-voltage grid, Fly should be placed in the ground a few meters high, and should be fixed firmly.