Tuesday, January 30, 2018

Panel COF Data ( Chip On Flim)

Panel COF Data ( Chip On Film)

OB3372KP
SONY KDL42W670A
NT61804-C6520A1A
8697-BC562
RM76A30FA-906
ILD50711
RM76370FA-80A
8656H-C502
NT39538H-C1272B
SSD3272
--------------------------------
8658-B CBHI Cof Data
LN362038 Cof Data
8658-B CBHU Cof Data
RM76153FM-OCN Cof Data
RM76180FC-086 Cof Data
8656-F CY0B Cof Data
NT39530H-C5208A Cof Data
RM76112FD-032 Cof Data
RM76153FL-0C1 Cof Data
RM76190FA-0AO Cof Data
T7C75A1 LE4CCDN Cof Data
NT39538H-C1272A Cof Data
LS0306M1-C2LX Cof Data
RM7611WFD0-006 Cof Data
NT39329H-C0264A Cof Data

Nt39538H-C1288A
NT39563H-C6502A Cof Data
NT39504H-C02E8C Cof Data
NT39329H-C02A5A Cof Data
SSD3273U2R4 Cof Data
NT39530H-C5203A Cof Data
RM7611WFD0-006C Cof Data
8651-A CBD7 Cof Data
LH169K01 Cof Data
HM1OC005K-C1 Cof Data
8656M CY61 Cof Data
DB7931-FT01M Cof Data
T7C75A1 LE4CCDN Cof Data
S6CG242-51U Cof Data
8656-B CBJV Cof Data
56CG23A-52 Cof Data
8658-H C258 Cof Data
NT39530H-C5208A cof Data
NT39538H-1272A-B Cof Data
NT39538H-C12E4A Cof Data
NT61237H Cof Data
RM76152FJOA8 Cof Data
VHIL S0327B6-2L cof data
-------------------------------------------------
Raydium RM7611WFD0-006 Cof Data
Novatek NT39530H-C5203A Cof data
Sharp LH169K01 Cof Data
Novatek NT39329H-C02A5A Cof Data
Rayidum RM76153FL-0C1 Cof Data
T7C75A1 LE4CCDN Cof Data
Novatek NT39504H-C02E8C T400HW04 V.2 Cof Data
Rayidum RM76180FC-086 Cof Data
Novatek NT39538H-C1272A Cof Data
HM1OC005K-C1 Cof Data
8658-B CBJV Cof Data

ILI5271M2AA1

6 pin Regulator SMD Chip Codes
6 pin PWM IC code
5xy= NCP1251,
IDP606 = R7731A,
63xxx = OB2263,
WP35/XP35 = LD7535,
ABx = FAN6862,
xxP/50 = LD7550IL_BL,
xxP/50 = LD7550IL_BL
52xxx = OB2252
62xxx = OB2262
73xxx = 0B2273
AAIxx = SG6858TZ
G6G = AP4313
37x = LD7537

Service Manuals Free Downlaods

Monday, January 29, 2018

LG 55EM9800

The 55EM9800 OLED HDTV is basically the 2013 equivalent to LG's 55EM9700 we have seen during CES2012, but with a slightly curved screen. Apart from being the most expensive, it is also the thinnest TV presently available; at just 4.5mm thick at the panel thinnest point, it is significantly thinner than the Samsung OLED TV proposal.

This ultra slim panel design has been made possible thanks to the use of carbon fiber-reinforced plastics into the rear of the television, thus providing the necessary support while keeping weight down to just 38 pounds, that is half the weight a typical 55-inch LED TV. Complimenting the slim design is an equally incredible 1mm-thick bezel.

The slim design calls for the use of an external media hub - same as Samsung breakout box concept that connects to the TV panel via a single cable to provide both AV connectivity to the outside world and power; this is necessary to house all relevant electronics and AV connections.

Yet there is more than just a most appealing and incredibly slim design. This OLED TV comes with what the industry is calling 'infinite' contrast ratio, one that is more than 100,000,000:1; so no more mega ratings as we were used to with LED TVs, instead, the terminology has now shifted to infinite contrast!

Picture Courtesy: LG

LG is making use of a new pixel architecture called W-OLED, or White-OLED that generates white light only for each sub-pixel element; colored filters are then used to generate the color information.

Both the White-OLED and RGB OLED have their pros and cons as we will further explain in this article. Direct-patterned RGB OLED is what Samsung is using on its OLED TVs.

The main advantage of RGB OLED is that no color filters are used since each sub-pixel generates its own colored light. We do not have any information on how much light is blocked by the color filters used in W-OLED pixel, but in LCD displays, the use of color filters can block as much as 70% of the light from the backlight source. Hence, removing the color filters as in the case of RGB OLED, should yield a more efficient TV display.

The main problem with this conventional direct-patterned RGB OLED emitter approach is that the different organic materials for the red, green, and blue sub-pixels age at different rates over time. This differential aging with time leads to color shifts as one sub-pixel color within the RGB OLED fads more quickly than the others.

LG adopted a smart twist to the conventional RGB OLED pixel structure by sandwiching the red, green, and blue organic materials, effectively stacking the blue, green, and red OLED film deposits on top of each other for each sub-pixel element.

The resultant organic sandwich produces white light instead of colored light once activated, hence the name While OLED, or W-OLED.

This means that each sub-pixel in a W-OLED display produces only white light. Color is added by adding red, green, and blue color filters on top of the white light emitting sub-pixel organic sandwich. LG uses the term 'Color Refiner' instead of color filters, but these are in effect red, green, and blue color filters placed on top of the white-light emitting sub-pixels.

Unlike the differential aging of the direct-patterned red, green, and blue sub-pixel structure in an RGB OLED, the resultant white light OLED formulation exhibits a more stable performance with no color shifts over an expected lifetime in excess of 100,000hrs! This means that unlike RGB OLED, with W-OLED there is a complete elimination of color shift since each sub-pixel ages at exactly the same rate as the rest of the sub-pixels within the pixel structure.

LG did not stop there however; there is also a fourth sub-pixel element in LG's White OLED pixel structure, a white sub-pixel. This fourth sub-element within the pixel structure does not include any color filters on top. The diagram here by LG depicts the RGBW sub-pixel structure as used by LG in its White OLED display technology. This extra white sub-pixel is said to help produce a brighter image while allowing for a wider color gamut and more accurate colors.

Compared to conventional direct patterned individual RGB sub-pixel emitters, White OLED pixel architecture offers additional advantages apart from the improved long-term color stability referred to above. In particular, White-OLED technology is easier to produce, highly scalable over large substrates, requires lower manufacturing times, and has a high production yield. This means that LG's White OLED display technology should be less expensive to produce. LG 55EM9800

Instead, 'direct-patterned' RGB OLED uses the conventional red, green, and blue sub-pixel structure where each OLED sub-pixel emits its own colored light; this is very much the same in concept as the pixel structure in a plasma display.LG is making use of a new pixel architecture called W-OLED, or White-OLED that generates white light only for each sub-pixel element; colored filters are then used to generate the color information.

Both the White-OLED and RGB OLED have their pros and cons as we will further explain in this article. Direct-patterned RGB OLED is what Samsung is using on its OLED TVs.

The resultant organic sandwich produces white light instead of colored light once activated, hence the name While OLED, or W-OLED.

Compared to conventional direct patterned individual RGB sub-pixel emitters, White OLED pixel architecture offers additional advantages apart from the improved long-term color stability referred to above. In particular, White-OLED technology is easier to produce, highly scalable over large substrates, requires lower manufacturing times, and has a high production yield. This means that LG's White OLED display technology should be less expensive to produce.

Sunday, January 28, 2018

5 Pin and 6pin SMD Chips

Pin SMD Data

DC / DC converters
***********************

http://www.s-manuals.com/smd/

FAN6862 = ABx

LD7550IL_BL = xxP/50

OB2252 = 52xxx

OB2262 = 62xxx

OB2273 = 73xxx

SG6858TZ = AAIxx

UC3863G_L = U863

USING CERAMIC OUTPUT CAPACITORS WITH THE MAX1734 VOLTAGE-MODE BUCK CONVERTER

Abstract: The MAX1734 voltage-mode buck DC-DC converter was design to work with medium ESR tantalum capacitors; however, by slightly changing the feedback scheme, small, low-ESR ceramic capacitors may be used. A schematic, design equations, and load-transient response waveforms are provided.

Many stepdown (buck) DC-DC controller ICs incorporate a voltage-mode control algorithm. As a result (for stable operation in continuous-conduction mode), the resulting application circuit's output capacitor is normally a high-ESR tantalum type. The circuit of Figure 1, however, allows use of an inexpensive ceramic output capacitor. To remove the effects of phase lag in the feedback loop, feedback is derived from the LX pin instead of the output.

Figure 1. In this simple application circuit, a stepdown DC-DC converter operates with a ceramic output capacitor.

A ceramic-capacitor circuit offers several benefits over the standard application circuit. First, ceramic capacitors are more readily available than tantalum types. Second, (see Figure 2) they cause less output ripple (<5mVPP vs. >20mVPP), and less load-transient overshoot (<50mVPP vs. >100mVPP). IC11 needs 20mVPP or more at the OUT pin for stable operation under load. To meet this requirement, first calculate the R1 value:

Figure 2. Load-transient response waveforms (top traces) show that a ceramic output capacitor produces lower output ripple and less overshoot.

Per the MAX1734 data sheet, VOUT is 1.5V or 1.8V, L1 is 10µH, Tmin is 0.4µsec, ILOADMAX is 250mA, and IOUTSENSE is 4µA. The result is R1 = 4.3kΩ for VOUT = 1.8V, and R1 = 5.2kΩ for VOUT = 1.5V. R1 may therefore be rounded to 5kΩ. Next, calculate the feedforward-capacitor value:

If R1 = 5kΩ and VOUT = 1.5V, then Cff < 12nF. Select Cff = 10nF. Choosing a much smaller value will cause excessive load-transient overshoot, and choosing a larger value will cause instability under loaded conditions. For optimized load transients, the inductor series resistance should be

In this case the RL value should be about 200mΩ, which allows use of a small inductor and causes an approximate efficiency drop of only 3% at maximum load. Because the inductor time constant L1/RL is matched to the feedback time constant R1 × Cff, the short-term load-transient response equals the DC load regulation (Figure 2). If RL is chosen less than 200mΩ, the peak-to-peak load-transient voltage will increase but the DC load regulation will decrease.

Finally, choose COUT large enough for stability:

where ΔIL is approximately 100mA when the MAX1734 operates with a 10µH inductor. In this case, COUT should be greater than 4µF.

1The MAX1734 stepdown DC-DC converter supplies a fixed 1.8V or 1.5V output at 250mA from an input voltage range of 2.7V to 5.5V. Its 5-pin SOT23 package and internal synchronous rectifier allows a small application circuit with a minimum number of external components.

NCP1403 Step-down DC-DC Converter with 1.6V Output Voltage for DSP Circuit. The NCP1403 is a monolithic PFM step-up DC-DC converter. This device is designed to boost a single Lithium or two cell AA/AAA battery voltage up to 15 V (with internal MOSFET) output for handheld applications

RT9266B

The RT9266B is a compact, high efficiency, and low voltage step-up DC/DC converter with an Adaptive Current Mode PWM control loop, includes an error amplifier, ramp generator, comparator, switch pass element and driver in which providing a stable and high efficient operation over a wide range of load currents. It operates in stable waveforms without external compensation.The low start-up input voltage below 1V makes RT9266B suitable for 1 to 4 battery cells applications with a 500mA internal switch. The 550kHz high switching rate minimized the size of external components. Besides, the 25μA low quiescent current together with high efficiency maintains long battery lifetime.

Friday, 26 January 2018

SMPS Chips Data

PWM IPS in the housings SOT-23-6, SOT-26, TSOP-6

By Imran Ashraf Khan

In the circuitry of modern pulsed power supplies (SMPS), PWM regulators, made in small-sized planar cases with six terminals, have gained wide popularity. The body type designation can be SOT-23-6, SOT-23-6L, SOT-26, TSOP-6, SSOT-6. The layout and layout of the pins are shown in the figure below. In this case, the left fragment of the picture shows the code marking LD7530A

Pin Assignment:
1 - GND. (Common wire).
2 - FB. (FeedBack - Feedback). Input for controlling the pulse duration with a signal from the output voltage. Sometimes it can have the designation COMP (input comparator).
3 - RI / RT / CT / COMP / NC - Depending on the type of chip, it can be used for a frequency-assigning RC circuit (RI / RT / CT) or for protection, as a PWM tripping comparator input with a threshold value at its input, specified in the document. In some types of microcircuits this input can be not involved in any way (NC - No Connect).
4 - SENSE, different CS (Current Sense) - Input from the current sensor at the source of the key.
5 - VCC - Input voltage supply and start the chip.
6th - OUT (GATE) - Output to control the gate of the key.

Functionally similar regulators work on the principle of popular earlier PWM chips xx384x series, which have proved themselves in terms of reliability and stability.

Some difficulties often arise when replacing or selecting an analog for similar PWM controllers due to the use of code marking in the designation of the type of microcircuit. The situation is complicated by a large number of component manufacturers, which do not always provide documentation for mass access, and not all manufacturers of ready-made devices supply repair service centers with circuits, so real repair schemes often have to be studied by repairers on the installed components and wiring connections directly on the board.

In practice, PWM chips and EAxxx and Eaxxx marking codes are often found. Official documents on them are not found in free access, but discussions on the forums and pieces of pictures from the PDF from System General, which publishes them as SG6848T and SG6848T2, have been preserved. The picture is attached.

To the attention of the masters we offer tables made up of information available on the Internet and PDF documents for the selection of analogs when replacing the most common six-legged planar PWM with pinout: pin1 - GND, pin2 - FB (COMP), pin4 - Sense, pin5 - Vcc, pin6 - OUT .
Their main difference is the application and purpose of the output 3.

PWM controllers (PWM), without using output 3.

Name	Part Namber	Diler	Marking
SG6849	SG684965TZ	Fairchild / ON Semi	BBxx
SG6849	SG6849-65T, SG6849-65TZ	System General	MBxx EBxx
SGP400	SGP400TZ	System General	AAKxx

PWM-regulators (PWM) with the installation of the resistor 95-100 kOhm to pin 3.

Using the PWM listed below, the frequency should be set by the resistor RT (RI) from pin 3 to ground. Usually its rating is chosen 95-100 kOhm for frequency 65-100 KHz. More precisely see the attached documentation. PDF files are packaged in RAR.

Name	Part Namber	Diler	Marking
AP3103A	AP3103AKTR-G1	Diodes Incorporated	GHL
AP8263	AP8263E6R, A8263E6VR	AiT Semiconductor	S1xx
AT3263	AT3263S6	ATC Technology	3263
CR6848	CR6848S	Chip-Rail	848H16
CR6850	CR6850S	Chip-Rail	850xx
CR6851	CR6851S	Chip-Rail	851xx
FAN6602R	FAN6602RM6X	Fairchild / ON Semi	ACCxx
FS6830	FS6830	FirstSemi
GR8830	GR8830CG	Grenergy	30xx
GR8836	GR8836C, GR8836CG	Grenergy	36xx
H6849	H6849NF	HI-SINCERITY
H6850	H6850NF	HI-SINCERITY
HT2263	HT2263MP	HOT-CHIP	63xxx
KP201		Kiwi Instruments
LD7531	LD7531GL, LD7531PL	Leadtrend	xxP31
LD7531A	LD7531AGL	Leadtrend	xxP31A
LD7535 / A	LD7535BL, LD7535GL, LD7535ABL, LD7535AGL	Leadtrend	xxP35-xxx35A
LD7550	LD7550BL, LD7550IL	Leadtrend	xxP50
LD7550B	LD7550BBL, LD7550BIL	Leadtrend	xxP50B
LD7551	LD7551BL / IL	Leadtrend	xxP51
LD7551C	LD7551CGL	Leadtrend	xxP51C
NX1049	XN1049TP	Xian-Innuovo	49xxx
OB2262	OB2262MP	On-Bright-Electronics	62xx
OB2263	OB2263MP	On-Bright-Electronics	63xx
PT4201	PT4201E23F	Powtech	4201
R7731	R7731GE / PE	Richtek	0Q =
R7731A	R7731AGE	Richtek	IDP = xx
SD4870	SD4870TR	Silan Microelectronics	4870
SF1530	SF1530LGT	SiFirst	30xxx
SG5701	SG5701TZ	System General	AAExx
SG6848	SG6848T, SG6848T1, SG6848TZ1, SG6848T2	Fairchild / ON Semi	AAHxx EAxxx
SG6858	SG6858TZ	Fairchild / ON Semi	AAIxx
SG6859A	SG6859ATZ, SG6859ATY	Fairchild / ON Semi	AAJFxx
SG6859	SG6859TZ	Fairchild / ON Semi	AAJMxx
SG6860	SG6860TY	Fairchild	AAQxx
SP6850	SP6850S26RG	Sporton Lab	850xx
SP6853	SP6853S26RGB, SP6853S26RG	Sporton Lab	853xx
SW2263	SW2263MP	SamWin
UC3863 / G	UC3863G-AG6-R	Unisonic Technologies Co	U863 U863G

PWM controllers in which pin 3 is used differently.

When using the PWM controllers listed below, you should pay attention to pin 3, which can be used to organize protection - thermal or from exceeding the input voltage.
The frequency can be fixed at 65kHz, or be set by the capacitor rating on pin 3.
When replacing any microcircuits with analogs, carefully study the documentation. PDF files are packed in the RAR archive.

Name	Part Namber	Diler	Marking
AP3105 / V / L / R	AP3105KTR-G1, AP3105VKTR-G1, AP3105LKTR-G1, AP3105RKTR-G1	Diodes Incorporated	GHN GHO GHP GHQ
AP3105NA / NV / NL / NR	AP3105NAKTR-G1, AP3105NVKTR-G1, AP3105NLKTR-G1, AP3105NRKTR-G1	Diodes Incorporated	GKN GKO GKP GKQ
AP3125A / V / L / R	AP3125AKTR-G1, AP3125VKTR-G1, AP3125LKTR-G1, AP3125RKTR-G1	Diodes Incorporated	GLS GLU GNB GNC
AP3125B	AP3125BKTR-G1	Diodes Incorporated	GLV
AP3125HA / HB	AP3125HAKTR-G1, AP3125HBKTR-G1	Diodes Incorporated	GNP GNQ
AP31261	AP31261KTR-G1	Diodes Incorporated	GPE
AP3127 / H	AP3127KTR-G1, AP3127HKTR-G1	Diodes Incorporated	GPH GSH
AP3301	AP3301K6TR-G1	Diodes Incorporated	GTC
FAN6862	FAN6862TY	Fairchild / ON Semi	ABDxx
FAN6863	FAN6863TY, FAN6863LTY, FAN6863RTY	Fairchild / ON Semi	ABRxx
HT2273	HT2273TP	HOT-CHIP	73xxx
LD7510 / J	LD7510GL, LD7510JGL	Leadtrend	xxP10 xxP10J
LD7530 / A	LD7530PL, LD7530GL, LD7530APL, LD7530AGL	Leadtrend	xxP30 xxxP30A
LD7532	LD7532GL	Leadtrend	xxP32
LD7532A	LD7532AGL	Leadtrend	xxP32A
LD7532H	LD7532HGL	Leadtrend	xxP32H
LD7533	LD7533GL	Leadtrend	xxP33
LD7536	LD7536GL	Leadtrend	xxP36
LD7536R	LD7536RGL	Leadtrend	xxP36R
LD7537R	LD7537RGL	Leadtrend	xxP37R
ME8204	ME8204M6G	MicrOne	ME8204xx
NCP1250	NCP1250ASN65T1G, NCP1250BSN65T1G, NCP1250ASN100T1G, NCP1250BSN100T1G	ON Semiconductor	25xxxx
NCP1251	NCP1251ASN65T1G, NCP1251BSN65T1G, NCP1251ASN100T1G, NCP1251BSN100T1G	ON Semiconductor	5xxxxx
OB2273	OB2273MP	On-Bright-Electronics	73xx
R7735	R7735AGE, R7735HGE, R7735GGE, R7735RGE, R7735LGE	Richtek
UC3873 / G	UC3873-AG6-R, UC3873G-AG6-R	Unisonic Technologies	U873 U873G

The table is updated as information becomes available.

How to read LDO LCD 8-pin regulator code 00HC5W

This kind of regulator is often found on the Toshiba LCD motherboard, and the shape is similar to ic eeprom.
The BD writing code is not written on the physical ic regulator. So for example just written 00IC0W, 00IA5W

How to read the specs: For example say 00HC5W

(1) Code "00" This means that the output voltage variable or can diajust by changing the value of the feedback resistor.
(2) The "H" code indicates that the maximum input allowable voltage is 10v.

(3) The code "C5" indicates that the maximum current capability of 1.5A

Example usage: