Tuesday, 21 December 2010

solution for blog reader

I am KANTH ,
I am an INDIAN, U R beside state ANDHRA PRADESH, Vijayawada
I found u r email id at , http://ecare-electronics.blogspot.com/
while i browsing the , http://humphreykimathi.blogspot.com/
I am kid in this electronics field I am intersted on MONITORS, SMPS , MOTHER BOARDS servicing , how to
FASTLY troubleshoot procedures on the LOT fault finding problems
solving them ,
i.e; tips how to use BULB loads OR RESISTOR high watt at Horizontal
section at Horizontal yoke , at the LOT as the series Load, Problems finding ,SMPS quick methods
troubleshooting. With GOD`s help i browsed websites and learned .
PLS respond
Thank u
KANTH
**************************************************************************************************************************

Hi Kanth,

Thanks for the belief in me and my friend Kimathi.
Let us take one by one each time.


tips how to use BULB loads OR RESISTOR high watt

See in order to check weather the SMPS is working fine or not we use bulb load.
If TV is having power supply problem inorder to check if the power supply is producing constant voltage 110 v (or as mentioned by the manufacturer ) we can use a 40 watts bulb for the load.
we need to disconnect the horizontal output transistor from the circuit and need to connect the bulb one point to collector point of the H out transistor and another to emmitor point of the H out transistor. Then we can start repairing the power supply. If power supply is working properly by producing constant voltage then the bulb glows with a constant brightness.Other wise it starts blinking as the voltage is unregulated.
also for the further accuracy of the SMPS circuit you can slightly vary the preset given in the power supply.as you vary the preset it bulb brightness starts varying. This shows power supply is perfect. Now you can connect the HOut to the board and switch on the TV. If Hout goes with tik-tick-tick sound means the problem will be in Line Output transformer (99 percent).
Also we can use the same bulb loading to find out SMPS short circuit.I will explain that in next post.
Please feel free to ask any question.
Regards
Raghavendra kumar

Wednesday, 15 December 2010

zener diodes

A Zener diode is a type of diode that permits current not only in the forward direction like a normal diode, but also in the reverse direction if the voltage is larger than the breakdown voltageknown as "Zener knee voltage" or "Zener voltage". The device was named after Clarence Zener, who discovered this electrical property.

A conventional solid-state diode will not allow significant current if it is reverse-biased below its reverse breakdown voltage. When the reverse bias breakdown voltage is exceeded, a conventional diode is subject to high current due to avalanche breakdown. Unless this current is limited by circuitry, the diode will be permanently damaged. In case of large forward bias (current in the direction of the arrow), the diode exhibits a voltage drop due to its junction built-in voltage and internal resistance. The amount of the voltage drop depends on the semiconductor material and the doping concentrations.

A Zener diode exhibits almost the same properties, except the device is specially designed so as to have a greatly reduced breakdown voltage, the so-called Zener voltage. By contrast with the conventional device, a reverse-biased Zener diode will exhibit a controlled breakdown and allow the current to keep the voltage across the Zener diode at the Zener voltage. For example, a diode with a Zener breakdown voltage of 3.2 V will exhibit a voltage drop of 3.2 V even if reverse bias voltage applied across it is more than its Zener voltage. The Zener diode is therefore ideal for applications such as the generation of a reference voltage (e.g. for anamplifier stage), or as a voltage stabilizer for low-current applications.

The Zener diode's operation depends on the heavy doping of its p-n junction allowingelectrons to tunnel from the valence band of the p-type material to the conduction band of the n-type material. In the atomic scale, this tunneling corresponds to the transport of valence band electrons into the empty conduction band states; as a result of the reduced barrier between these bands and high electric fields that are induced due to the relatively high levels of dopings on both sides.[1] The breakdown voltage can be controlled quite accurately in the doping process. While tolerances within 0.05% are available, the most widely used tolerances are 5% and 10%. Breakdown voltage for commonly available zener diodes can vary widely from 1.2 volts to 200 volts.

Another mechanism that produces a similar effect is the avalanche effect as in the avalanche diode. The two types of diode are in fact constructed the same way and both effects are present in diodes of this type. In silicon diodes up to about 5.6 volts, the Zener effect is the predominant effect and shows a marked negative temperature coefficient. Above 5.6 volts, the avalanche effect becomes predominant and exhibits a positive temperature coefficient[1]. In a 5.6 V diode, the two effects occur together and their temperature coefficients neatly cancel each other out, thus the 5.6 V diode is the component of choice in temperature-critical applications. Modern manufacturing techniques have produced devices with voltages lower than 5.6 V with negligible temperature coefficients, but as higher voltage devices are encountered, the temperature coefficient rises dramatically. A 75 V diode has 10 times the coefficient of a 12 V diode.

All such diodes, regardless of breakdown voltage, are usually marketed under the umbrella term of "Zener diode".

General SMPS troubleshooting approach

The following sections provide a set of guidelines for attacking SMPS problems. Those in the next 5 paragraphs are common to SMPS using both discrete and integrated controllers:

  1. First, determine that it is not something trivial like a blown fuse due to a legitimate overload (that has since been removed). I have a SCSI peripheral box that will blow its SMPS fuse if the SCSI cable is inserted live.

  2. Categorize the problem into: startup problem, catastrophic failure, incorrect outputs, or excessive ripple or noise.

  3. Determine what the proper output voltages should be. Identify the main (regulated) output.

  4. Disconnect the supply from the equipment it is powering if possible. This will prevent the possibility of expensive damage should the output voltages soar to stratospheric levels for some reason. If this is not possible, you will need to be extra careful - always use a Variac to bring up the input slowly and monitor the main output at all times.

    Note: Some SMPS designs require power to be applied instantly to provide the startup voltage to the controller. If this is the case with yours, it won't be possible to bring up the voltage slowly (unless you power that chip separately). However, it should still be possible to run the unit somewhat reduced line voltage.

    CAUTION: Running any SMPS at greatly reduced line voltage will be stressful for it, especially if the output load is a significant fraction of its full load ratings. In addition, at some range of line voltage, the output regulation may not work properly and the output(s) may go much higher than expected. Use dummy loads in place of the valuable equipment if possible when doing such testing!

  5. Determine an appropriate load for the outputs (if not connected to the equipment). A typical SMPS will want a minimum of 5% to 20% of full load current at least on the main output to regulate properly. Others may not need any load - it depends on the design or they may have an internal load. Here are some typical load currents:

Tips on SMPS troubleshooting

The diagnosis of problems in switchmode power supplies is sometimes made complicated due the interdependence of components that must function properly for any portion of the power supply to begin to work. Depending on design, SMPS may or may not be protected from overload conditions and may fail catastrophically under a heavy load even when supposedly short circuit proof. There is particular stress on the switching devices (they are often 800 V transistors) which can lead to early or unexpected failure. Also, SMPS may fail upon restoration of power after a blackout if there is any kind of power spike since turn-on is a very stressful period - some designs take this into account and limit turn on surge.

However, the cause of many problems are immediately obvious and have simple fixes - the blown chopper transistor or dried up main filter capacitor. Don't assume your problem is complex and convoluted. Most are not. You should not avoid attempting a repair just because there is a slight chance it will be more challenging!

A low power (e.g., 25 W) fine tip soldering iron and fine rosin core solder will be needed if you should need to disconnect any soldered wires (on purpose or by accident) or replace soldered components. A higher power iron or small soldering gun will be needed for dealing with larger components. Never use acid core solder or the type used for sweating copper pipes!

CAUTION: You can easily turn a simple repair (e.g., bad solder connections) into an expensive mess if you use inappropriate soldering equipment and/or lack the soldering skills to go along with it. If in doubt, find someone else to do the soldering or at least practice, practice, practice, soldering and desoldering on a junk circuit board first! See the document: Troubleshooting and Repair of Consumer Electronic Equipment for additional info on soldering and rework techniques.

The switchmode power supply (SMPS)


Until the 1970s or so, most consumer electronic equipment used a basic power transformer/rectifier/filter capacitor type of power supply for converting the AC line into the various voltages needed by internal circuitry. Even regulation was present only where absolutely needed - the high voltage supplies of color TV sets, for example. Remember those old TVs with boat anchor type power transformers? (Of course, if you recall those, you also recall the fond days of vacuum tube sets and the corner drugstore with a public tube tester!)

Switchmode supplies had been commonplace in military and avionic equipment long before they found their way into consumer electronics. I have some DC-DC and DC-AC converter modules from a Minuteman I missile from around 1962 as one example. I suppose that the cost of the switching transistors wasn't as big a deal with a $100 million missile as a $300 TV (even in 1960s dollars).

Nowadays, all TVs, monitors, PCs; most laptop and camcorder power packs; many printers, fax machines, and VCRs; and even certain audio equipment like portable CD players use this technology to reduce cost, weight, and size.

Switchmode power supply repair

Unlike PC system boards where any disasters are likely to only affect your pocketbook, power supplies, especially line connected switchmode power supplies (SMPSs) can be dangerous. Read, understand, and follow the set of safety guidelines provided later in this document whenever working on line connected power supplies as well as TVs, monitors, or other similar high voltage equipment.

Having said that, repairing a power supply yourself may in fact be the only economical option. It is very common for service centers to simply replace the entire power supply board or module even if the problem is a 25 cent capacitor. It may simply not pay for them to take the bench time to diagnose down to the component level. Many problems with switchmode power supplies are easy to find and easy and inexpensive to fix. Not all, but surprisingly many.

This document will provide you with the knowledge to deal with a large percentage of the problems you are likely to encounter with the common small switchmode power supplies found in many types of consumer electronic equipment including PCs, printers, TVs, computer monitors, and laptop or camcorder power packs. It will enable you to diagnose problems and in many cases, correct them as well. With minor exceptions, specific manufacturers and models will not be covered as there are so many variations that such a treatment would require a huge and very detailed text. Rather, the most common problems will be addressed and enough basic principles of operation will be provided to enable you to narrow the problem down and likely determine a course of action for repair. In many cases, you will be able to do what is required for a fraction of the cost that would be charged by a repair center - assuming they would even bother.

Should you still not be able to find a solution, you will have learned a great deal and be able to ask appropriate questions and supply relevant information if you decide to post to sci.electronics.repair. It will also be easier to do further research using a repair text such as the ones listed at the end of this document. In any case, you will have the satisfaction of knowing you did as much as you could before taking it in for professional repair. With your new-found knowledge, you will have the upper hand and will not easily be snowed by a dishonest or incompetent technician.

Most Common Problems

The following probably account for 95% or more of the common SMPS ailments:

  • Supply dead, fuse blown - shorted switchmode power transistor and other semiconductors, open fusable resistors, other bad parts. Note: actual cause of failure may be power surge/brownout/lightning strikes, random failure, or primary side electrolytic capacitor(s) with greatly reduced capacity or entirely open - test them before powering up the repaired unit.

  • Supply dead, fuse not blown - bad startup circuit (open startup resistors), open fusable resistors (due to shorted semiconductors), bad controller components.

  • One or more outputs out of tolerance or with excessive ripple at the line frequency (50/60 Hz) or twice the line frequency (100/120 Hz) - dried up main filter capacitor(s) on rectified AC input.

  • One or more outputs out of tolerance or with excessive ripple at the switching frequency (10s of kHz typical) - dried up or leaky filter capacitors on affected outputs.

  • Audible whine with low voltage on one or more outputs - shorted semiconductors, faulty regulator circuitry resulting in overvoltage crowbar kicking in, faulty overvoltage sensing circuit or SCR, faulty controller.

  • Periodic power cycling, tweet-tweet, flub-flub, blinking power light - shorted semiconductors, faulty over voltage or over current sensing components, bad controller.

In all cases, bad solder connections are a possibility as well since there are usually large components in these supplies and soldering to their pins may not always be perfect. An excessive load can also result in most of these symptoms or may be the original cause of the failure. And don't overlook the trivial: a line voltage select switch in the wrong position or between positions (possibly by accident when moving the supply, particularly with PCs), or damaged.

Repair or replace

Some manufacturers have inexpensive flat rate service policies for power supplies. If you are not inclined or not interested in doing the diagnosis and repair yourself, it may be worthwhile to look into these. In some cases, $25 will get you a replacement supply regardless of original condition. However, this is probably the exception and replacements could run more than the total original cost of the equipment - especially as in the case of most TVs and many computer monitors, where the power supply is built onto the main circuit board.

Nothing really degrades in a switchmode power supply except possibly the electrolytic capacitors (unless a catastrophic failure resulted in a total meltdown) and these can usually be replaced for a total cost of a few dollars. Therefore, it usually makes sense to repair a faulty supply assuming it can be done reasonably quickly (depending on how much you value your time and the down time of the equipment) and, of course, assuming that the equipment it powers is worth the effort. Most replacement parts are readily available and kits containing common service components are also available for many popular power supplies (such as those found in some terminals, MacIntosh and other Apple computers, various brands of video monitors, and some TVs and VCRs).

Where an exact replacement power supply is no longer available or excessively expensive, it may be possible to simply replace the guts if space allows and the mounting arrangement is compatible. For example, for an older full size PC tower, the original power supply may be in a non-standard box but the circuit board itself may use a standard hole configuration such that an inexpensive replacement may be installed in its place.

Alternatively, many surplus electronics distributors have a wide selection of power supplies of all shapes, sizes, output voltages, and current capacities. One of these may make a suitable replacement for your custom supply with a lot less hassle than attempting to repair your undocumented original. It will likely be much newer as well with no end-of-life issues like dried up electrolytic capacitors to deal worry about. Of course, you must know the voltage and current maximum current requirements of each of the outputs in order to make a selection.

For the specific case of SMPSs for standard computers (PC, Macs, workstations, servers), it often doesn't make sense to spend much time or money on repair. The cost of replacement of power supplies for PCs in particular is so low, that just buying a new power supply may be the best course of action. Furthermore, the risk of a faulty repair causing expensive or fatal damage to the mainboard and peripherals including total loss of all data stored on disk, makes repair a risky endeavor unless thorough testing can be performed before installation. However, it won't hurt to check for obvious problems like bad connections. Put the dead one aside and considering trying to repair it if there isn't anything better to do. Realistically, this will be never. :)

Saturday, 11 December 2010

Transcend Information, Inc. (Transcend®) have announced the addition of 64GB models


Transcend Information, Inc. (Transcend®) have announced the addition of 64GB models to its Ultra Speed series USB flash drives. Featuring an incredible combination of storage capacity and transfer performance, the JetFlash 600 and JetFlash 620 Flash Drives can satisfy even the most demanding users, allowing them to store a lot more in significantly less time.

It is hard to imagine how many files and data one can operate in this age of information explosion. Transcend’s Ultra Speed USB flash drives now come in an enormous 64 GB of storage capacity, enabling users to store over 16,000 high-quality pictures or songs, 640 minutes of Full HD videos, or seemingly limitless amount of documents—all in a tiny thumb-sized storage device.

Friday, 10 December 2010

How to Find Your Computer IP Address (Windows)

Finding a computer IP address may be extremely easy for many of us, but not necessarily to everyone out there.

1) Go to the Start menu, go to Run, and type "CMD" in the dialog box (without the quotes.)

2) Now you should see a dark (DOS) window that looks just like the picture on the left of this article step.

Without the quotes, type "IPCONFIG" and press ENTER.

3) Now you should see some network information, along with the IP ADDRESS of your computer listed.

Tips & Warnings

· If performing the IPCONFIG command gives you the following error: "'ipconfig is not recognized as an internal or external command" you may need to approach a slightly different method: - From the C: drive in DOS, type CD\WINDOWS\SYSTEM32 - Try the IPCONFIG command from this location again

The future of Indian IT in 2011



There is positive news to start with that; the Indian semiconductor industry is expected to achieve a healthy growth in 2011 due to growth in all the related sectors to it.

According to a report presented by The Indian Semiconductor Association and Frost & Sullivan, jointly, the semiconductor industry of the nation, coping up with global trend, is ready for an extraordinary growth, with sales hoped to reach the mark of $8 Billion by the end of 2011.

Intel's President and Chief Operating Officer, Paul Otellini, suggested that ‘what oil was to Saudi Arabia, information technology would shortly be to India’, not recently almost 10 years back.

The major competitor to India in the Asia region no doubt is China. The major advantage of India over china is the English speaking, highly educated young generation. Also the birth control steps taken by the china left it with lesser youngsters in the population.

Also, with increasing Internet speed and rising income levels throughout India, sales of technology like laptops and mobile phones have increased dramatically. In middle of 2010, nine companies participated in the bidding process for the 3G mobile phone licenses. This will further increase the sales once the roll-out takes off.

The hiring process in most of the companies has already reached to the pre-recession stages. This in turn has provided the higher demand for the technical education throughout the urban India.

But, the fluctuating US economy always keeps the Indian IT sector in a nervous situation (also Obama’s statements too) and this is the best time to look toward non-European IT market.
So, let us be ready to enjoy a happy IT year of 2011.

Monday, 6 December 2010

A beutifull song from My Mother tongue Kannada

To all My Non Indian visitors of blog giving a beautiful song. Have a look

Thursday, 2 December 2010

Capacitors tutorial

Capacitors are very important component in any electronic circuit board. Here I found a video regarding to that.Please have a look.

Wednesday, 1 December 2010

Journey done to Bandipur.


Four months ago I just to get out of bored, simply started the bike and traveled nearly 100 kms to a Tiger sanctuary in my state of Karnataka. Some of the photos are as follows.