Re: how to test lcd led backlight?

No....
It's because you have essential nil current flowing thru the diode (1Meg+air losses), so the P-N junction doesn't really work.
It's acting as an antenna, only capacitive parasitic factor of diode matters (~50-1000pF).

Re: how to test lcd led backlight?

...... acting as an antenna, only capacitive parasitic factor of diode matters (~50-1000pF).

That's why the sinewave has a little bit distortion....... Good......

Near the Transformer, two transistors on each side are D1816, D1816( 2sd1816 both are NPNs ) the two small ones are 8550ss(NPN) and 8050ss(PNP)






I know ,we gonna have a circuits diagram very quick........
I double- check still the Transister are D1816, D1816

Re: how to test lcd led backlight?

Hmm--Uncle Walt's been working Overtime again......

Re: how to test lcd led backlight?

For Mains Isolation--Again Cheap Cheerful, --with possibility of voltage customisation (within limits)

Two std low-voltage transformers--Say a pair of lighting Toroids or whatever you've got around--providing they the same O/P voltage, and the same/similar VA rating/size.....

Connect the first Secondary to the Secondary of the Second.

Connect the First Primary to the mains...

You'll have an isolated 240V (Assuming mains is 240V) at the primary of the second.....

I use two 650VA toroids like this--as a Mains Isolation Transformer to run sets from--Works pretty well!


Thinks for the good tip ....... two donuts (isolate-transformer) gonna look nice.


Find 2 microwave HV transformers (which a lots people rewired to make welding machine).
Put two primary coil together and weld it back and u have 10A isolate-transformer (higher efficiency) but it's kinda heavy.

How is your project doing ? I would like to know,one more way to light up whole LED screen penal (directly from AC outlet cheap and simple like u idea before )....... as household light source......cheap and e-recycle.........

Re: how to test lcd led backlight?

Usually power factor is used in businesses that have a lot of inductive motors. The meters only see apparent power not real power, so they get charged more then they are actually using. These companies will use large Capacitors to counter act the inductive resistance with capacities resistance leaving only the actual resistance that is in the circuit.

Re: how to test lcd led backlight?

Back to the {how to test lcd led backlight?} .....Are u ready!......OK ......let us ...R....R..O...C..K.........
Background music....We gonna use this https://www.youtube.com/watch?v=09R8_2nJtjg

LG 55LN5400-UA.... EAY62810701 (3PAGC10124A-R) Power Supply / LED Board.... EBT62359788 (EAX65049104(1.0)) Main Board.

LED screen's connector marked (LED- LED+ LED+ LED-) is easy enough.
first group (top) LEDs 48 LEDs ( back....led- , blue.......led+)
second group (bottom) LEDs 36 LEDs ( white.......led- , bule.......led+) Total 84 LEDs

Let's rock with this LG-55' LED-2/2013-screen has 4 wires connector -BD9483F drived-84 LEDs-divided by two groups -TV, which I found in dumpster.......

https://cdn.badcaps-static.com/pdfs/...a8607cbf1a.pdf

The LED-screen-light works good ! So I destroy it with 110AC . Now, one LED is blow out, another LED is no light but look OK. Screen won't come on anymore.........

Simulation Case 1: TV come in with no backlit...Pic, sound is OK

Solution: Open LED screen, use CCFL tester find two LEDs not work.

......After change two LEDs ......... YYYY...EE......S.............. it work.....

Theoretically: One LED not work , the whole LED screen won't light up.........

I forgot the most importance thing: Penal No:LG LN54M550060 V12

Next project:

Isn't that a beautiful one (picture last one,from Samsung 50' LED TV.).

Re: how to test lcd led backlight?

Well done it looks beautiful. Love the video and the 65 Lincoln.

Re: how to test lcd led backlight?

The 65 Lincoln ...Wow ....you're GOOD!


Today, we are very happy, we have our special guests from British …..Round and his cat ...welcome to our show.......

Background music..also from British......one of my favorite songs......
https://www.youtube.com/watch?v=dzXcyUJjJD4


...... A........action.......

First question: Why your cat has no whiskers?
Round: I used them all.
Question : What kind of materials need to use.....to have light?
Round : I just pick up rocks in my backyard.
Question : Do you know ,you change the whole TV industry!
Round: Pardon me, what is TV?? ....And ...And ..I...I.... just a assistant for Marconi......
Question : Final one. Do you know, how to test LED?
Round: ...(Happily)...... I know this one .....with my cat.

.......................Cut..................

...........................The Founder father of the LED......................................

If someone ask me....Who invented the LED... I would say H. J. Round
If you say is Viking or Russian, I have no argument, too.

https://www.youtube.com/watch?t=20&v=8quZrUcRFlw

This is USA movie..... Sorry! …..They did forget …..H. J. Round....... they put him in Electroluminescence (EL) categories.................not fair...........But we will always remember his Cat's-whisker detector........

http://lighting.com/how-leds-are-made/
https://www.youtube.com/watch?v=CAgRF8TibJ0

This is my version of Cat's-whisker detector........with HV CCFL tester... tips put a piece of Kanthal wire.......go to my backyard..... ZAP.....the scorpion... see if any Fluorescent light come out.......If I win Nobel Prizes, I would donate to Badcaps.net......


Qusetion : Who invented the LED
Jose's answer : Creo que tal vez chino.

Re: how to test lcd led backlight?

Love the LED videos.

Re: how to test lcd led backlight?

So....so...... beautiful voice, but xxx- video- MTV ,I don't like ....so let's play this one..... Before I get banned.....
https://www.youtube.com/watch?v=ZnI-WKYqp3E.......I need Viagra for that...

How to change LEDs.........
1. Solder iron
2. Hot air gun
3 Oven bake (BBQ)
4 My favor... gas touch.............. collect,sort,and reuse all the LEDs

Next .....I will teach you ,how to test and group them... in case U need one...... because different TV use different LEDs...................most important thing is current......next project......

PS: collect as many LEDs as u can (damper dive)........ we gonna use for making a car head light...........

Re: how to test lcd led backlight?

How to test backlight LED ?...............let's go.....

Pic 1: Look that parts-No.
Pic 2: LEDs.... I took out yesterday.
Pic 3: You can use swab to pick the LED, with help of month-water.
Pic 4: Taped on the tester.
Pic 5: read out the information.
Pic 6: sorting....

Re: how to test lcd led backlight?

What is the 819mV VF, the protection diode?
What is t he P/N printed on the bottom of the LED?

Re: how to test lcd led backlight?

The $18.00-wonderful tester-a must have toy.
The tester thinks have two diodes inside. And it is, first Blue diode(2.61V) and dropping with yellow diode (at 819mV) will give the almost white color.......But they put the symbol wrong side.....Don't worry, someone wrote that program not perfect, yet

Pic 1: I tested with a red LED


.....What is the P/N printed on the bottom of the LED?....
Hard to read....but just collect them, that was an old stocks. From now on , I will put Penal No. model No.

Next project:

We can establish a Data Base for all kinds of LED screens.... pins layout .... how many LEDs ......what's kind of LED .......V and A they used.....

Pic 2,3: A yellow LED.

A refreshment (From Wi Ki):

There are three main categories of miniature single die LEDs:
Low-current: typically rated for 2 mA at around 2 V (approximately 4 mW consumption).
Standard: 20 mA LEDs (ranging from approximately 40 mW to 90 mW) at around:
1.9 to 2.1 V for red, orange and yellow,
3.0 to 3.4 V for green and blue,
2.9 to 4.2 V for violet, pink, purple and white.
Ultra-high-output: 20 mA at approximately 2 V or 4–5 V, designed for viewing in direct sunlight.
5 V and 12 V LEDs are ordinary miniature LEDs that incorporate a suitable series resistor for direct connection to a 5 V or 12 V supply.

reference:
http://www.electronicsweekly.com/new...kages-2008-08/

http://spectrum.ieee.org/semiconduct...ds-dark-secret

http://www.ledsmagazine.com/articles...s-domains.html


This proof H J Round is the first one:
The first-ever report of light emission from a semiconductor was by the British radio engineer Henry Joseph Round, who noted a yellowish glow emanating from silicon carbide in 1907. However, the first devices at all similar to today’s LEDs arrived only in the 1950s, at Signal Corps Engineering Laboratories, at Fort Monmouth, in New Jersey. Researchers there fabricated orange-emitting devices; green, red, and yellow equivalents followed in the ’60s and ’70s, all of them quite inefficient.

https://www.badcaps.net/forum/showth...t=45234&page=4

Which I posted #68 and nobody believe me.......Like they don't pay attention to the H J Round ( look the years gap about 40 years late)....all because he is not famous as Guglielmo Marconi ( the wireless radio)......

Re: how to test lcd led backlight?

There is only a blue diode in there.

The LED surfaces are coated in CE:YAG or similar phosphor which emits yellow light when blue light hits its surface (fluroscent)

So it will test around 2.8-4V forward voltage when good, at If=1mA. (Higher If, greater Vf.)

Re: how to test lcd led backlight?

That 819mV (it is shown on the meter in reverse polarity in that test mode, it test the two legs of the DUT under two conditions, forward and reverse, look at the symbol on your display) got to be some kind of protection diode, there is no LED with that low Vf that I know of, or that meter is doing something funny. I think you need to understand what the meter is showing and how to read the result.

"The tester thinks have two diodes inside. And it is, first Blue diode(2.61V) and dropping with yellow diode (at 819mV) will give the almost white color.......But they put the symbol wrong side.....Don't worry, someone wrote that program not perfect, yet" I think you mis-undetand about LED function. I has only ONE LED.

Re: how to test lcd led backlight?

The printing on the bottom is something like K8CD8C111???? If you can get the number then you can look up the spec sheet.
"Next project:

We can establish a Data Base for all kinds of LED screens.... pins layout .... how many LEDs ......what's kind of LED .......V and A they used....."
If you cannot get the spesheet then you will not know the current handling, color temprature, viewing angle, etc.

Re: how to test lcd led backlight?

Could it be the minimum and maximum voltages that the LED will pass current. Perhaps at the minimum one can not see light, but the diode is passing current and when it is at the maximum voltage one can see it at its brightest.

Re: how to test lcd led backlight?

The chip is traditionally positioned on top of the cathode lead. Applying several volts across this device makes the chip emit blue light. Passing the light through a yellow phosphor yields white light. Modern, high-power LEDs are {variants of this architecture, featuring more complex packages} for superior thermal management.
Once you’ve got blue light, you can get white by passing the blue rays through a yellow phosphor. The phosphor absorbs some of the blue and reradiates it as yellow; the combination of blue and yellow makes white.


Applying several volts across this device makes the chip emit blue light. Passing the light through a yellow phosphor yields white light. (Modern, high-power LEDs are variants of this architecture, featuring more complex packages) for superior thermal management.


the first practical bright-blue LED using nitride-based compound semiconductors. ......Once you’ve got blue light, you can get white by passing the blue rays through a yellow phosphor.

All LEDs are fabricated as aggregated sections, or regions, of different semiconductor materials. Each of these regions plays a specific role. One region serves as a source of electrons; it consists of a crystal of a compound semiconductor into which tiny amounts of an impurity, such as silicon, have been introduced. Each such atom of impurity, or dopant, has four electrons in its outer shell, compared with the three in an atom of gallium, aluminum, or indium. When a dopant takes a place that one of these other atoms would normally occupy, it adds an electron to the crystalline lattice. The extra electron moves easily though the crystal, acting as (a carrier of negative charge). With this surfeit of negative charges, such a material is called n -type.

At the opposite end of the LED is a region of p -type material, so called because it has excess positive-charge carriers, created by doping with an element such as zinc or magnesium. These metals are made up of atoms with only two electrons in their outer shell. When such an atom sits in place of an atom of aluminum, gallium, or a chemically similar element (from group III in the periodic table), the lattice ends up an electron short. That vacancy behaves as a positive charge, moving throughout the crystal like the missing tile in a sort-the-number puzzle. That mobile vacancy is called a hole.

In the middle of .......the sandwich...... are several extraordinarily ....thin layers...... These constitute the active region, where light is produced. (Some layers made of one semiconducting material surround a central layer made of another, creating a “well” just a few atoms thick—a trench so confined that the laws of quantum mechanics rule supreme. ) When you inject electrons and holes into the well by applying a voltage to the n - and p -type regions, .......the two kinds of charge carriers .......will be trapped, maximizing the likelihood that they will recombine. When they do, a photon pops out.

Unfortunately, blue and green LEDs lack such a good platform. They’re called nitride LEDs because their fundamental semiconductor is gallium nitride. The n -type gallium nitride is doped with silicon, the p -type with magnesium. The quantum wells in between are gallium indium nitride. To alter the light color emitted from green to violet, researchers vary the gallium-to-indium ratio in the quantum wells. A little indium produces a violet LED; a little more of it produces green.
Combatting Droop Droop—the loss of efficiency at high power—afflicts conventional nitride LED structures. These feature an active region with gallium indium nitride quantum wells and GaN barriers, and an electron-blocking layer to keep electrons in this region. Researchers at Rensselaer Polytechnic Institute have reduced droop with new active regions, made first by combining GaInN wells and aluminum gallium indium nitride barriers and, more recently, by pairing GaInN wells with GaInN barriers. Meanwhile, Philips Lumileds has also developed a structure that is less prone to droop, thanks to a far thicker quantum well.

In 2007, Humphreys’s Cambridge team, together with researchers at the University of Oxford, described how they had attacked the problem with what’s known as a three-dimensional atom probe. This device applies a high voltage that evaporates atoms on a surface, then sends them individually through a mass spectroscope, which identifies each one by its charge-to-mass ratio. By evaporating one layer after the other and putting all the data together, you can render a 3-D image of the surface with atomic precision.
Krames’s team used a laser to probe a layer of gallium indium nitride, the semiconductor used for quantum wells in a nitride LED. They tuned the laser to a wavelength that only the gallium indium nitride layer would absorb, so that each zap created pairs of electrons and holes that then recombined to produce photons. When the researchers graphed the resulting photoluminescence against different intensities impinging on the sample, they produced curves that closely fit an equation that described the effects of Auger recombination.

The company does so with what’s known as a double heterostructure (DH), essentially a quantum well that’s 13 nanometers wide, rather than the usual 3 or 4 nm. It still shows quantum effects, although they are not so pronounced, and the design is less efficient than the standard one at low currents. Still, it excels at higher currents. The Lumileds team has created a test version that delivers a peak efficiency slightly higher than that of a conventional LED.

The good news, though, is that Lumileds has shown that you can push the peak of your efficiency to far higher currents by cutting carrier density—that is, by spreading the carriers over more material. The company does so with what’s known as a double heterostructure (DH), essentially a quantum well that’s 13 nanometers wide, rather than the usual 3 or 4 nm. It still shows quantum effects, although they are not so pronounced, and the design is less efficient than the standard one at low currents. Still, it excels at higher currents. The Lumileds team has created a test version that delivers a peak efficiency slightly higher than that of a conventional LED.
However, it is possible to detect electrons in the p -type region by modifying the standard LED structure, and researchers at UCSB have done just this. This team, led by Steven DenBaars and Nakamura, did the job of fitting the p -type region with an additional quantum well, one that emits light of a color different from that of the main LED. At a workshop in Montreux, Switzerland, in the fall of 2008, the group reported that they had found just this sort of emission.

However, it is possible to detect electrons in the p -type region by modifying the standard LED structure, and researchers at UCSB have done just this. This team, led by Steven DenBaars and Nakamura, did the job of fitting the p -type region with an additional quantum well, one that emits light of a color different from that of the main LED. At a workshop in Montreux, Switzerland, in the fall of 2008, the group reported that they had found just this sort of emission.

Although this experiment proved that electrons do flow into the p -type region, it can’t tell us where they came from. And while Schubert’s theory of electron leakage could explain the results, there may well be other things that can also account for them. We can’t even rule out Auger recombination as the dominant mechanism, because the proportion of electrons flowing into the p -type region is still to be quantified.

I only know , the tester think has two diodes inside by the voltage they detected, how this happen ? I need more research......

Re: how to test lcd led backlight?

https://www.badcaps.net/forum/attach...3&d=1428689792
When you test with 1 junction device, it will show Vf (Forward Voltage, 1.6V), Ir (leakage current, 4nA), Junction capacitance (28pF).

https://www.badcaps.net/forum/attach...8&d=1428684053
If you look at this picture, only test pads 2 and 3 are used.
If you draw up the test result, you will see I what I draw. It is probably protection diode:

You can simulate the reading by connecting a diode in parallel with the LED as shown, and you will see what I mean.

Re: how to test lcd led backlight?

For BUD M... yes , but you drew the diagram mean SHORT


by search D3GE-400SMA-R2 Pop a lots.... come out......


D3GE-400SMA-R1, LM41-00001V, 2013SVS40, UN40EH5300F, LED BACKLIGHT,DE400BGS-V1

http://www.ebay.com/itm/D3GE-400SMA-...-/271496440642

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US02LH40MDCPLGA/ZA US02
PART DESCRIPTION IS.

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Wow....I did not know, you can sell that, I already parting out

SAMSUNG 40" LED BACKLIGHT (SAMSUNG_2013SVS40_T1_3228N1_B2_13_REV1.5) UNIT FULL FUNCTION TESTED & CERTIFIED BY TECHNICIAN (100% WORKING CONDITION).

WHAT YOU SEE ON PICTURE, THAT IS RIGHT PARTS YOU NEED.

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