# Small Signal Schottky Diode, Dual Series, 40 V, 200 mA, 550 mV, 1 A, 150 °C ![Product image](https://novapart.co/image/farnell:2463448RL/) **URL**: https://novapart.co/products/BAT854SW,115/small-signal-schottky-diode-dual-series-40-v-200 **SKU**: BAT854SW,115 **Manufacturer**: NEXPERIA **Price**: €0.1240 **Stock**: 10+ **Lead Time**: 69 days (indicative) ## Description Diode Configuration:Dual Series; Repetitive Reverse Voltage Vrrm Max:40V; Forward Current If(AV):200mA; Forward Voltage VF Max:550mV; Forward Surge Current Ifsm Max:1A; Operating Temperatur ## Specifications | Parameter | Value | |---|---| | Svhc | No SVHC (25-Jun-2025) | | No. Of Pins | 3Pins | | Product Range | BAT854 | | Qualification | - | | Diode Mounting | Surface Mount | | Diode Case Style | SOT-323 | | Diode Configuration | Dual Series | | Forward Voltage Max | 550mV | | Forward Surge Current | 1A | | Reverse Recovery Time | - | | Average Forward Current | 200mA | | Operating Temperature Max | 150°C | | Repetitive Peak Reverse Voltage | 40V | ## Datasheet 📄 [Download PDF](https://novapart.co/datasheet/farnell:2463448RL/) **==> picture [171 x 143] intentionally omitted <==** **----- Start of picture text -----**
APPLICATION NOTE
ECO-Monitor
ANO00057
**----- End of picture text -----**
Pips Semiconductors DH | LI pS Philips Semiconductors Application Note AN00057 ECO-Monitor **==> picture [287 x 62] intentionally omitted <==** **----- Start of picture text -----**
| Purchase of Philips I°C components conveys a
license under the I’C patent to use the components in
the I°C system, provided the system conforms to the
| PC specifications defined by Philips.
**----- End of picture text -----**
© Philips Electronics N.V. 2000 All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights. 2 Philips Semiconductors ECO-Monitor Application Note ANO0057 APPLICATION NOTE ECO-Monitor ANO00057 Author(s): J. Moors, J. Schatorie Philips Semiconductors Systems Laboratory Eindhoven, The Netherlands Keywords Autosync monitor 17" Monitor I2C controlled Electro Magnetic Compatibility Eco/green design Number of pages: 79 Date: 08-11-2000 3 e = Parts list; Philips Semiconductors Application Note AN00057 ## ECO-Monitor CONTENTS 1.1 Specification... see ceeeccscsresessessecseesecseceseescsseesecseesececceesceseeseesessessecaeesessecseesessesaeseseesesesseeseesesteseseesssesseneeee O 1.2 Block diagram 0.0... eeeecesccssesseeseesecseeceeeceseeseesessecseesecececeeeeesessessessecseseeeecesessessessesseseeesseeaesaeeessesssseessestenteee LO LO LL LA LD LT 2.1 Switch mode power SUPPLY ..........ceseeseesecseceeeseceseeseeseesecsecsececeaseseesecsecsessececeaseeseseessesesseseeeeseesesssetterteenteneee 2.2 Microcontroller .........ccecccescescesceeseceseeeseeeneceeesecesecnsecenecseeeseeeseeesecesecesecsaeseecseesaeeeaeceseceseseeeserestesseseesseseesteeee 2.3 Deflection controller .........cccecccescceseesceeseeeeeesecesecececseeeseeeseeeseceaecseeceeeseenseeeseceeeceeeseesseeseeeaeeeseessesssesstestsesteenee 2.4 Horizontal deflection .........ccecccesceeseesseesceeseeeseeesecesecececseesseeeseceseceaecaeceeeeeesaeceaesesecseecseeeeeeaeeesseeseseesessesseeee 2.4.2 Line driver and output stage... eceesecssessecseesecsececesecesesseesecsecseeeceecesesseesessesseesesesesssssesessesssessetseseeesseeeees LO 2.4.3 EW Modullator.......cccccccccccccscesccessceseceseceneceeeeseessecesecnsecceceeeaeeeaeesaeeeseceneceneceesseeeaesesecnseceeeesseessesteseesseseesteeee LO ZAA EHT Section... .cececcscescesessescescseesceecseeseeecseescsecseesesecsecenesseeesesseesenesaeeaeeesseeeeeesaeecesesaeeeeeesseeeeeesaeeesersaseeseteaseeees2 2.5 Vertical deflection output Stage... ec eeceesesececcesesseeseesecsecsececeseesessessessessecseceeceesssesseesessesaeseseessssesesssetenteneDL 2.6 Dynamic focus amplifier... eee eeessessesseesecsececeeeceseeseeseesecsecsecseccessessessesseesecseceaesceseesessessesateseseeesseseeaeensDD 2.7 Rotation ......cceccecccsscesceesccesceeseceseceneceeeseesseessesesecnecseeesecesecesecenecaecseeeseesseceseceseceeeseeeseeeaeseseceseeeeeseesseesseesaessteesesDO 2.8 VIGO Lee eececencesceseseeseeccseesceseseesesccseesesseseesesseseesesseaceseseaeeseeaeaesseeaesessesaeeeeseeaesesaeeaeseeaeeseeeeaeeaeeesaeeaeeeeaesateeeteates23 2.8.1 POWED eee eeecccssceceseeceseeceseecesaecececesaeceseecesaeceeecsaeceseeceaecesaecesaeceeecesaecesaecesaeceeeceaeeesaecesaeceaeeesaeeeeaeeesateesaeens#DO 2.8.2 — PrOCESSING .0... es eeeeeececceseeseeseesecsececcsccsseeseeseesecseesecsccsaeeseesessecseesecseseceeseesecsessessecsesaseseeseeaeesessecatseeeesseseeseeseeeesD4 2.8.4 OUTPUT StaGe eee csceteessecssecssecseeesecesecesecsaecssesecesscessceaeessecsaecsaecseeeseceaeceseseaeseeeessesssesssesssessesssesseeess2O 3.1 Switch Mode Power Supply.........:cccsccsccsscsssssessecseesecsecesesseesessecsecsececeaeesessessecsecseseseceesesseesesaeeaeseeseasesseaeeatete29 3.2 Micro controller ........ceceecesscescesseceseeeseeececsceesecesecnsecnecseesseeeseeeseceseceaeceeeceeeaeesaeeeaeceseseseseeesesesteseeseeseesseesseeesOO 3.3 Deflection controller .........ccccecccecceesceeseesseeeeeeceeseceneceneccecseeeseesseeeaeeeseceaeceeeceeeeseesseeeaeeeseseeesesesissetseetseetetteesteeesOL 3.4 Rotation CU CUI... ceccecceeccescceseeeseceseeseeeseeeseessecsecnecacecseeeseeesecesesaecseeceecseesseceseseaeceecseesseeeseeeseeesesesesseesssesteesssOD 3.5 Horizontal deflection Circuit.........cccecceceesceesececeeseeeseceseceaeceseceneeseeeseenseceseseseceeeseesseeeseseaeceaeessesseeseeeteseesteeseeBO 3.6 Vertical deflection CirCuit.........cccccecccesccsseesseeseeeseceseceneceecseeeseenseceaeesseceaeseecaeesaeeeaecnseceseseeeeaeesstesseeeseesseseessenesD4 3.7 VICO Le 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eeeecccescesscesceeseeeseeeseesceeseeeseenseeesecesecacecseeeseeesecesecesecaeceecseesseceaeceaeceeeceeeeeeeeseeeeesseessessesseenns4D, 8.1 Used equipment... ccc cccsescsccscceseesessessecseesececeaeescssessecsessecseseaessessessesseesesaeseeseessseeseesessesateeseessseesestententeeeOL 8.2 JUMPEer SCHINYS 0... eeesesseeseceeceeceseeseesessecseesecseceaeesceseesecsecsecsesceeseesessesseesecseeeseeseseessesessesteeeseeseseeeseeetenteneOL 5 Philips Semiconductors Application Note ANO00057 ## ECO-Monitor 8.3 First time adjustment..........ccccccesceescesseescceseeesecesecnsecscecseeeseensecesecaecsaeeseecseeeseceaeseseceeseesseeeaeenseeeseessesseeeseesstenssOD 8.4 Geometrical adjustment..........ccecccesceeseesseeseceseeesecesecceeseeeseeeseceseceaeceeceeeseenseceaesaeceeeceeeaeeeseeeseeesessseseseetsesttesssOD 8.5 Colour adjustment...........cccccccesceesceseesseeseeeseeesecnecseeeseceseceaecesecneeseeeseeesecesesececeesseesseeeseseseeeseeeeeseeneensteseeseesesOO 8.6 Focus adjustment.........ccecccccccesceeseesseeseeeseeeseeeseccecseeeseceseceaecesecenecseeeseceseenseceseceeeeeeseeeseseseseaeeeeesieeseeeeeseestessesOO 8.7 Adjusting other video Modes..........ceccceccesseesseeseceseceneeeceeseeeseceseceaeceecseeeseeeseeeaeceaeceneceesaeesaeeeseseseseeseasesiresttenteessOD 8.8 Programming Serial Umber ..........ecceescescesceesceeseeesecesecscecseeeseeeseceaeceaeceeeeeecseenseceaeceseceeesseeeeeessenseeeaeesseesseesseeesD4 10.1 Horizontal Deflection ...........ccccccccscccesssscccessseeccssseeceesseeccessseeceessceccesseeccesseeccssseecesssseccessseecessssecessssesessssesesssseDT 10.2 Vertical deflection .........cccccccccccccccssccccessscccesssecccesseeccessseccesseeccesseeccessseccessseeccesseeccessseecessseeesessseccessssceesssseeessssOD 10.3 Dynamic fOCUS 0.00... cee eeeeseeseeseceececcseeseesessecseesecsecsaeesceaessecsessecsecseeceeseesessessecatcseseeesesseesessessteseeesessesseaesaseateesOO 11.3 Lay-out Hint ..... cece 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MeSSAZES..........eeesccceseceseeceseeeececsseeceseeceeecesceceaeceseecesaeceeeceeaeceeecesaeceeeceaeeeseecesaeeeseeessatessetersareesOA 12.3 User interface and OSD menu Control occ ceecccceeessccceessceecessceccesscccessseeccesseeccessseccesssesecessseceesssseessseeesesssOF 12.3.1 OSD menu layout... eee cscsecsscseceecssessessessecsecsecsecceeacssessessessecsecseeecssessessessecseesesseseseeseaesssssessesateeeeeeeeseeesOO OSD USF MENU[oocccccccccccccccccceccceecnseeeeeeecseeensseeeeeessesesseeeeeesceesssseeeeescsessssesseccesesssssseeeccessessssssteessssssssssssssessssssss] OD OSD S€rViC€ MENU. ....ccccccccccccccccccesseeeeesceeeeeseeeeeecsscenesseeeeesssesssssseesesssesssssseeessseeessssseseesesssssssssesesssssssssssessessesssOO 12.3.2 Menu item descriptions ..0...... cc ceeeeesesscsseeseeseesecsecsececsesseesessecseesecsesasesessessessessecsesessesesesssesessesateesseseesesseeeesO8 User store ANd @Xit oc 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wocccccccccccececceccscccccsesssssssscccesssessssssceceesessssssssscccsessssssssscecsessssssssssecsssesssssssssscesessssssssscssssssssssscsseeDL 12.7 Horizontal linearity Capacitors .........ceccesceseesceesceeseeecececeesceeseeeseeeseensecesecaeceeeeesseseseessesseeesseesreetsesteestsesteesteeesDL 12.8 NVM related items .......00. ccc cccccccccsssccccessceccessceccessseeccenseeccesseeecessseeccesseeccessseccesssseccessseesesssseeesssscessssseesssseeeesDL 12.8.1 Factory pre-programmed video MOdES...........cesecsesscssesseeseeseceeceececceseeseeaessecseeeeeecsseeseesessecteeseeseseesssteseenteeeTL 12.8.2. NVM memory map layout ....... cece ceeeccsseeseeseesecsececccsesseesessecsecsecsecsaseseesessessessecsesseseesesesssesesatssteseeeesessesseatensD2 13. 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INTRODUCTION This monitor is intended as an application proposal for 17” mid-end monitor designs and for the promotion of the following key components. |the following key components.|| |---|---| |Key component|Description| |BU4523AF|Silicon Diffused Power Transistor for horizontal deflection stage| |BYM357X|Power combi diode, flyback diode plusEWmodulator diode in one
package| |AT2097/32B|High voltage transformer| |M41EHN323X160/G341BA|17”High resolution, high contrast colourmonitortube assembly| |P87C380|Monitor micro controller| |PHP18NQ20T|N-channel PowerMOS Transistor for linearity capacitor switching| |TDA4856|I’C-bus controlled auto sync deflection controller forPC Monitors| |TDA4863J|Vertical deflection booster| |TDA4887PS|160MHzI’C-bus controlledvideopreamplifier| || TEA1507|Greenchip II,SMPS controlIC
|| |CU15/50|Base drive transformer| |CU20d3|Mains filter choke| |CUI5|Dynamic focus transformer| |AT4042 32A|Linearity balance corrector coil| |CE423V|SMPS transformer| |CU20|Bridge coil forEW modulator| Note: the TEA 1507 is not in mass production yet, the P87C380 is a discontinued product. 1.1 Specification **==> picture [508 x 158] intentionally omitted <==** **----- Start of picture text -----**
|General
| | Mains voltage | 90 - 264Vae
|__| Mains frequency 50 - 60Hz
| |Powerconsumption
Standby power
| | typical <75W
|__|PtWeight | 0K
|Picturetube Dimensions (W x Hx D) 423 x 426 x 405 mm”
Po |Type
Dot triplet pitch
| | M4 TEHIN323X160/G341BA
Recommended active screen 312 x 234 mm”
area
**----- End of picture text -----**
8 Philips Semiconductors |~~|~~|~~Anodevoltage~~
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Philips Semiconductors ECO-Monitor Application Note ANO0057 |||OSD generator|| |---|---|---|---| ||||Horizontal syne signal processed by 4C| |||~~Horizontaldeflectiondriver|~~|~~|Linedrive pulses(opencollectoroutput)~~| |H_unlock|Output ||~~Horizontal deflection driver |~~
| uC,
Grid1 protection circuit|~~| Line drive pulses (open collector output)~~
Outoflock indication and fastblanking
signal| ||||B+ drive pulses (open collector output)| |V_drive_plus,
~~V_drivemin~~|Output ||| Vertical deflection|Differential sawtooth current output for
~~verticaldeflection~~| |~~V_drive min~~||Dynamic focus amplifier|~~vertical deflection~~
Vertical dynamic focus signal| |||EW modulator|EW-modulation outputto EW-amplifier| |~~EHT_fb~~|||~~EHTinformation~~| |~~EHT_fb~~|||~~EHTinformation~~| |~~EHT_fb~~
CLBL|Output ||| Videoprocessor|~~EHT information~~
Two-level sandcastle pulse.
Upper level is video clamping.
Lower level is vertical blanking pulse.| The TDA4856 is a high performance and efficient solution for auto-sync monitors. All functions are controllable by I’C-bus. The TDA4856 provides synchronisation processing, horizontal and vertical synchronisation with full auto-sync capability and very short settling times after mode changes. External power components are given a great deal of protection. The IC generates the drive waveforms for DC-coupled vertical boosters such as TDA486x and TDA835x. The TDA4856 provides extended functions e.g. as a flexible B+ control, and extensive set of geometry control facilities, and a combined output for horizontal and vertical focus signals. See also application note AN97072 BusControlled Autosync Deflection Controller TDA4853/54. Horizontal frequency range calculation: The horizontal oscillator is synchronised in the frequency range from 30 to 70 kHz (determined by resistors R295 and R296 and capacitor C288). The value of R295 and R296 are calculated in the formulas mentioned in APPENDIX 1 TDA4856 horizontal frequency range. It is best to use components with 2% tolerance for R295, R296 and C288. Capacitor C288 should not be changed (optimal for low jitter). Configuration of the B+ part of the deflection controller: The B+ section of the deflection controller is applied in feedback configuration. The divided EHT voltage is fed back to the deflection controller, which adjusts the B+_drive pulse according to the EHT voltage. Without this feedback loop the EHT and as a result Vg2 (grid 2 voltage) vary too much, resulting in a background colour variation on the screen. The bandwidth of the loop is made that slow that the EHT is varied in one frame; the time constant is a couple of frames. This means that vertical size is not affected in the steady state when going from black screen to white screen. So only horizontal size has to be adjusted because of the compensation of the EHT breathing. This adjustment of the horizontal size is done by applying beam current information to HSMOD, which modulates the size via the EW Modulator. ASCOR is internally connected to PLL2 (control bit ACD=1). 16 Philips Semiconductors Application Note ANO0057 ## ECO-Monitor B+ section design hints: **==> picture [484 x 355] intentionally omitted <==** **----- Start of picture text -----**
The current source needed for the sawtooth generator at pin 5 (Bsense) must be active until the deflection
controller is switched off. See AN00042 Failure Mechanisms of the Line Output Transistor for more
information.
Csense of B+ section (=C287) must have a low temperature coefficient for a stable horizontal size.
Cbop (=C285) must be positioned close to pin 3 and pin 7 of deflection controller. This capacitor is necessary
for stability of the internal OTA (opamp with current output).
2.4 Horizontal deflection
2.4.1 B+ circuit
+16V - Bt+
“1esv—> Circuit
B+_drive
B+ section of
+12V -
TDA4856
Eht_fb
**----- End of picture text -----**
Figure 2-5 B+ section block diagram **==> picture [349 x 184] intentionally omitted <==** **----- Start of picture text -----**
Signal name Type Connected with Explanation
+12V Supply | SMPS, Degauss Stabilised 12V
Video board power
Horizontal deflection output
stage, EW modulator
Beam current measurement
Grid1 protection circuit
+16V Supply | SMPS
Horizontal deflection driver
+185V Supply | SMPS
Dynamic focus amplifier
DC restoration circuit
EHT information
[B+ drive | (Be section | B¥ drive pulses
**----- End of picture text -----**
17 **==> picture [281 x 220] intentionally omitted <==** **----- Start of picture text -----**
+GULYHBPRG
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deflection
o
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+185 output stage
+BGULYH
H_linO to Save State
H_lin2 J340 to J342
HPLL circuit
TDA4856 +BXQORFN
+BV\QFBP
**----- End of picture text -----**
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(:BGULYH
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**==> picture [288 x 130] intentionally omitted <==** **----- Start of picture text -----**
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deflection. 9GHIOBSO
9BGULYHBSOXV 9BGULYHBPLQ
**----- End of picture text -----**
**==> picture [19 x 6] intentionally omitted <==** **----- Start of picture text -----**
G\QIRF
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**==> picture [63 x 14] intentionally omitted <==** **----- Start of picture text -----**
S-cap IRFBGULYH
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Philips Semiconductors **==> picture [493 x 455] intentionally omitted <==** **----- Start of picture text -----**
|||||||||||||| |---|---|---|---|---|---|---|---|---|---|---|---|---| |ECO-Monitor|Application|Note| |AN00057| |RGB|Input|Video|booster|and DC|Amplified,|inverted &|processed|video| |restore|signal|including OSD| |Grid1|Input|Grid|||protection|circuit|Grid|||voltage|and|also used|for|spot| |suppression| |Grid|2|voltage| |Grid3 A|Static|focus|x|voltage| |Grid3B|Input|Line|output transformer|Static|focus|y|and|dynamic|horizontal +| |vertical|focus|voltage| |-9|Supply|voltage| |Picture|tube|M41EHN323X160/G341BA:| |High|resolution;|higher|pixel|density|possible|up|to|-|high|definition|gun| |1280x1024|pixels|(non-interlaced)|displayable|- 0.27 mm|dot triplet pitch| |conforms|to|ISO|9241|with:| |High|brightness|and|contrast:|-|optimised|black matrix process| |Excelllent white|uniformity|and|colour purity|-|invar|shadow mask| |-|axial|3-pin|suspension| |-|inner magnetic|shielding| |Accurate|convergence|and|raster|geometry|-|double|mussel|coil|technology| |-|internal|magnetostatic|beam|alignment| |-|additional|vertical|symmetry|adjustment|for|optional| |and|easy|convergence|touch-up| |Deflection|coil|data|-|horizontal|coil|inductance|=|180|nH| |-|vertical|coil|resistance|=|6.3|O| |-|vertical|coil|inductance|=|6.3|mH| |- maximum|advised|horizontal|frequency|=|66|kHz| **----- End of picture text -----**
27 **==> picture [702 x 486] intentionally omitted <==** **----- Start of picture text -----**
1 2 3 4 5 6 7 8
A A
P210
FASTON_WIRECONTACT
P211
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+9V -9V
B SDA_DDCOSCL_DDCOCsync C_syncSDA_DDCSCL_DDC +5V SDA_I2CSCL_I2CHsync_oVsync_orotation rotation Vsync_oSDA_I2CSCL_I2CHsync_oDeflectioncontroller+12V Vdrive_plEWdriveFocus EWdrivefocus Vdrive_pl+9V+9V -9V-9V +80V+80V rotation rotation+9VRotation-9V To video amplifierP2041234567891011121314 SDA_I2CSCL_I2C+12V+185V+80V-9VCLBLVg1Vsync_oCsyncABLHfb+5V R386100 B
DPMS1 Vdefl_pl
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hunlock Hunlock Vdrive_min Vdrive_min
degauss Vsync_i Vsync_i Vertical deflection
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C H_lin0 P205 C
H_lin1
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Hdrive_mod +12V +16V +185V G SDA_DDCO
degauss DPMS1 B Hsync_i
+185V +185V
SUPPLY +80V+16V +16V+80V CLBL P11_EHT+12V +16V +185V selftest 5 10 15 Vsync_iSCL_DDCO
+12V +12V Bdrive R3961.8k R3971.8k
Hdrive focus
+9V +9V
Horizontal
D -9V -9V BCI deflection D
+5V +5V Hfb
H_lin0
H_lin1
H_lin2
Hdrive_mod
EWdrive EWdrive
EHT
ABL ABL
E -185V -185V E
R280
100
+5V
Hfb R281
100
Engineer: Philips Semiconductors B.V.
F PHILIPS PHILIPS F. Vaneerdewegh Eindhoven The Netherlands F
SEMICONDUCTORS Drawn by:dkamp Sheet Name: Block Schematic Size:A3
PS-SLE CONSUMER 2 Changed by:ilodema
Date Changed: Tuesday, February 15, 2000 Time Changed: 1:39:00 pm Project: PR39872 Drwg: 130 - 1 / 1
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**----- End of picture text -----**
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MONO_PTC_20_276_26K +12V
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C211 10RNTC- R21014 to 550V 9 SMPS_150..250WT200 10 BYV27-600D208 C208100uF200V 33uHL201 +185V
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TL431CZ201 2 3 label2 Z202BZX79C12V C22910nF**
R23647k
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label1
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150 Engineer: Philips Semiconductors B.V.
F PHILIPS PHILIPS J. Kleuskens Eindhoven The Netherlands F
SEMICONDUCTORS dkampDrawn by: Sheet Name: Supply Size:A3
PS-SLE CONSUMER 2 ilodemaChanged by:
Date Changed: Tuesday, February 15, 2000 Time Changed: 1:36:54 pm Project: PR39872 Drwg: 130 - 1 / 1
1 2 3 4 5 6 7 8
1N4148
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1 R219 R220
**----- End of picture text -----**
**==> picture [787 x 499] intentionally omitted <==** **----- Start of picture text -----**
1 2 3 4 5 6
PWM7/P2.71 42 PWM8/CLAMP/P3.0
IC? +5V
+5V PWM6/P2.62 41 PWM9/PATOUT/P3.1
A R240 PWM5/P2.53 40 PWM10/P1.7 R241 R242 A
33k 4.7k 4.7k
4 39 SCL/P1.0 R243
PWM4/P2.4 100 SCL_I2C
selftest R189 PWM3/P2.35 38 SDA/P1.1 R244 SDA_I2C
100 100
R245 PWM2/P2.26 37 SCL1/P1.2 R246
Hunlock SCL_DDC
10k 100
10kR248 PWM1/P2.17 36 SDA1/P1.3 R247 SDA_DDC
100
PWM0/P2.08 35 INT1_/VPP +5V +5V
XTAL1 9 34 ADC1/P3.3 P212
B X240 1 B
12MHz 10 33 ADC0/P3.2 R249 1002 Keyboard
XTAL2
3
+5V R250 ** VDD11 32 VDDA ** R251 +5V
1NFR25 25V C241100uF C247100nFVSS12 31 VSSA C248100nF C242100uF25V 1NFR25 C24022nF ** R2711M
R252 100 HSYNCin/PROG13 30 DAC3 R394
Hsync_i C243 100pF 47 Hdrive_mod
Hsync_o R253 HSYNCout/P1.514 29 DAC2 R254 rotation
100 100 +5V +5V
C_sync C244 100pFR255 100 CSYNCin/P1.615 28 DAC1
C Vsync_i C245 100pFR256 100 VSYNCin/OE_16 27 DAC0 R204 R373 R374 R2584.7k +5V C
R259 VSYNCout/P1.417 26 RESET 33k 33k 33k
Vsync_o
100 R260 C246
R20333k DPMS1 +5V 4.7k R261100 P0.7 18 25 P0.0 R262100 H_lin0 1 IC? 8 100uF25V R2634.7k R2644.7k
P0.6 19 24 P0.1 R265 2 7
J240 R267 100 H_lin1 34 56 R266 100 SCL_I2C
user/service mode degauss +5V 4.7k R269100 P0.5 20 23 P0.2 R270100 H_lin2 PCF8598CP R268 100 SDA_I2C
P0.421 22 P0.3
Engineer: Philips Semiconductors B.V.
D PHILIPS PHILIPS SEMICONDUCTORS F. Vaneerdewegh Eindhoven The Netherlands D
Drawn by:I.lodema Sheet Name: micro Size:A4
Systems Laboratory Eindhoven Changed by:
ilodema
Date/Time Changed: Friday, June 9, 2000 8:33:43 am Project: PR39873 Variant: None Drwg: 130 - 1 / 1
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**----- End of picture text -----**
## **==> picture [673 x 476] intentionally omitted <==** **----- Start of picture text -----**
1 2 3 4 5 6 7 8
A A
Vlocal Hfb
B BZX79C Z2852V4 R2854.3k R28618k R28310k B
C P11_EHTR2911.8k C2872.2nFBC558BTR285** C302R301XR_SFR16TXR_SFR16TR299C28510nFBdriveC28910nF XnF_370C297R29310k 124563 HFLBXRAYBSENSBINBDRVBOP IC? HSMODFOCUSHPLL2HCAPHREFHBUF 29 [28][27][32] 31 [30] R296R288100**** 1.21kC2865.6nFC28810nF R2952.74k FOCUS R30068k R28968k** C29322nFBC558BTR286 C290100nF R29227k BCIR2841.5kZ286BZX79C4V7 C
Vlocal Hdrive 78 PGNDHDRV HPLL1SGND [26] 25 R2983.3k **** C291100nFC2923.3nF
C295 9 XSEL VCAP [24] ** C294100nF
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D 12 VOUT2 VSMOD 21 D
13 VOUT1 ASCOR 20
R305100 14 VSYNC SDA [19] R306100 SDA_I2C HUNLOCK
R307100 15 HSYNC SCL [18] R308100 SCL_I2C
CLBL R309100 16 CLBL HUNLOCK 17 R31210kR310100 D288 R311180k 1N4148D285 R3134.7M MPSA92TR288 Vg1
+12V
E R316 BAV21 C30147uF25V R31533k R317 D286 R282330k E
C298100pF100 Vdrive_pl D287 R318 TR289 10k 1N4148
C299100pFR319100 Vdrive_min BAV21 C300470nF100k R3204.7k BC547 -185V
Engineer: Philips Semiconductors B.V.
F PHILIPS PHILIPS F. Vaneerdewegh Eindhoven The Netherlands F
SEMICONDUCTORS Drawn by:ilodema Sheet Name: deflection_controller Size:A3
PS-SLE CONSUMER 2 ilodemaChanged by:
Date/Time Changed: Tuesday, February 15, 2000 1:42:22 pm Project: PR39872 Variant: None Drwg: 130 - 1 / 1
1 2 3 4 5 6 7 8
Vlocal
XnF_370
TDA4856_V2
Vlocal
**----- End of picture text -----**
**==> picture [672 x 486] intentionally omitted <==** **----- Start of picture text -----**
1 2 3 4 5 6
GG
A A
R195
10
B C274 B
220uF
R272 16V
3.9k
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n.m. TR273
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100k 4.7uF
R276 63V TR274
56k BC547
R277
2.2k
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220uF
rotat EL
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Engineer: Philips Semiconductors B.V.
D PHILIPS PHILIPS F. Vaneerdewegh Eindhoven The Netherlands D
SEMICONDUCTORS ee dkampDrawn by: Sheet Name: Rotation circuit Size:A4
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PS-SLE CONSUMER 2 Changed by:
ilodema
a
Date Changed: Wednesday, December 8, 1999 Time Changed: 9:31:32 am Project: DESIGN Drwg: 130 - 1 / 1
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**----- End of picture text -----**
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1 2 3 4 5 6 7 8
+185V AT2097_SLE
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B R3491k R342100 C34447uF200V C34247nF**R343120 R346470PR02 L3414.7uH C3436.8nF** D340BYV99 47 13 11R5 12Dynamic focusVg2 R39336k R34456k C34122nF** R3451kTR341BC547 n.m. R34733kR348100k C3454.7uF63V BCIABL B
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C 100 TR344 5 1k ** C346220nF T340 R351150k C
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L346 BYM357XD347 BYD73G C358100nF** R36210k BYD73G C359100nF** R36310k BYD73G 100 100nFC360 [**] R36410k
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+16V R375100 100nF 5.6nF R3711k R37615k C38068uF16V H_lin2 TR350BC547 H_lin1 TR351BC547 H_lin0 TR352BC547
Hdrive R383100 C36447uF25V R377470 C3674.7uF35V TR355BC639 C3654.7nF**R385150 EWdrive R3782.2k C36915nF BC558BTR353 BC558BTR354 1.8kR384 n.m.20kR379C3663.3nF C37110uF63VR38810PR02 C3683.3uF** J340 R38010k J341 R38110k J342 R38210k
F D3481N4148 R387560 BD677C3702.2nF TR356 PHILIPS PS-SLESEMICONDUCTORSPHILIPSCONSUMER 2 Engineer:F. VaneerdeweghDrawn by:dkampChanged by:ilodema Sheet Name: Eindhoven The NetherlandsPhilips Semiconductors B.V. hor_defl-EHT Size:A3 F
Date Changed: Tuesday, February 15, 2000 Time Changed: 1:46:15 pm Project: PR39872 Drwg: 130 - 1 / 1
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**----- End of picture text -----**
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Engineer: Philips Semiconductors B.V.
D PHILIPS PHILIPS F. Vaneerdewegh Eindhoven The Netherlands D
SEMICONDUCTORS Drawn by:dkamp Sheet Name: Vertical Deflection Size:A4
& PS-SLE CONSUMER 2 rd Changed by: |
ilodema
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Pf Date Changed: Tuesday, February 15, 2000 Time Changed: 1:43:51 pm Project: PR39872 Drwg: 130 - 1 / 1
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1 2 3 4 5 6 7 8 9 10 11 12
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39 Philips Semiconductors ECO-Monitor Application Note ANO00057 6. BILL OF MATERIALS Bill of materials of SLE ECO monitor design. Date:19 juni 2000 6.1 Main board REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR C200 2222-378-64104 100nF MKP/MKP 378 630V 5% BC C201 2222-370-75334 330nF MKT 370 63V 10% BC C202 2222-655-09221 220pF C655 500V 10% BC C203 2222-336-60222 2.2nF MKP 336_Y2 250V 20% BC C204 2222-336-60222 2.2nF MKP 336_Y2 250V 20% BC C205 2222-336-10474 470nF MKP 336_X1 275V 20% BC C207 2222-336-60222 2.2nF MKP 336_Y2 250V 20% BC C208 2222-151-62101 100uF RLH 151 200V 20% BC C209 2222-136-66471 470uF RVI136 25V 20% BC C211 2222-057-36221 220uF PSM-SI 057 400V 20% BC C212 2222-336-10474 470nF MKP 336_X1 275V 20% BC C213 2222-134-50229 22uF RLP5 134 35V 20% BC C214 2222-037-59479 47uF RSM 037 100V 20% BC C217 2222-370-85223 22nF MKT 370 100V 10% BC C218 2222-375-44102 1nF KP/MKP 375 2000V 5% BC C219 2222-037-56479 n.m. RSM 037 25V 20% BC C220 2222-655-09221 220pF C655 500V 10% BC C222 2222-037-65102 1000uF RSM 037 16V 20% BC C223 2222-097-56479 n.m. RLP7 097 25V 20% BC C224 2222-037-65102 1000uF RSM 037 16V 20% BC C225 2222-037-51109 10uF RSM 037 50V 20% BC C226 2222-370-85104 100nF MKT 370 100V 10% BC C227 2222-370-75683 68nF MKT 370 63V 10% BC C228 2222-370-85473 47nF MKT 370 100V 10% BC C229 2222-370-76103 10nF MKT 370 250V 5% BC C230 2222-630-09102 inF C630 100V 10% BC C231 2222-037-66152 1500uF RSM 037 25V 20% BC C232 2222-037-56479 47uF RSM 037 25V 20% BC C240 2222-370-85223 22nF MKT 370 100V 10% BC C241 2222-037-90047 100uF RSM 037 25V 20% BC C242 2222-037-90047 100uF RSM 037 25V 20% BC C243 2222-681-10101 100pF C631-NPO 100V 2% BC C244 2222-681-10101 100pF C631-NPO 100V 2% BC C245 2222-681-10101 100pF C631-NPO 100V 2% BC C246 2222-037-90047 100uF RSM 037 25V 20% BC C247 2222-370-75104 100nF MKT 370 63V 10% BC C248 2222-370-75104 100nF MKT 370 63V 10% BC C272 2222-037-58478 n.m. RSM 037 63V 20% BC C273 2222-037-65221 220uF RSM 037 16V 20% BC C274 2222-037-65221 220uF RSM 037 16V 20% BC C285 2222-629-09103 10nF C629 63V -20+80% BC C286 2222-370-35562 5.6nF MKT 370 250V 10% BC C287 2222-370-52222 2.2nF MKT 370 400V 5% BC C288 2222-370-76103 10nF MKT 370 250V 5% BC C289 2222-629-09103 10nF C629 63V -20+80% BC C290 2222-370-85104 100nF MKT 370 100V 10% BC C291 2222-370-75104 100nF MKT 370 63V 10% BC C292 2222-370-65332 3.3nF MKT 370 400V 10% BC C293 2222-370-85223 22nF MKT 370 100V 10% BC C294 2222-370-76104 100nF MKT 370 63V 5% BC C295 2222-037-90047 100uF RSM 037 25V 20% BC C296 2222-370-85104 100nF MKT 370 100V 10% BC 40 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR C297 2222-370-75XXX XnF_370 MKT 370 63V 10% BC C298 2222-681-10101 100pF C631-NPO 100V 2% BC C299 2222-681-10101 100pF C631-NPO 100V 2% BC C300 2222-370-75474 470nF MKT 370 63V 10% BC C301 2222-037-56479 47uF RSM 037 25V 20% BC C302 2222-370-75XXX XnF_370 MKT 370 63V 10% BC C321 2222-370-75224 220nF MKT 370 63V 10% BC C322 2222-037-65471 470uF RSM 037 16V 20% BC C323 2222-370-35103 10nF MKT 370 250V 10% BC C324 2222-370-35103 10nF MKT 370 250V 10% BC C325 2222-370-75104 100nF MKT 370 63V 10% BC C326 2222-037-65471 470uF RSM 037 16V 20% BC C327 2222-037-58229 22uF RSM 037 63V 20% BC C340 2222-151-62479 47uF RLH 151 200V 20% BC C341 2222-370-85223 22nF MKT 370 100V 10% BC C342 2222-370-35473 47nF MKT 370 250V 10% BC C343 2222-370-35682 6.8nF MKT 370 250V 10% BC C344 2222-151-62479 47uF RLH 151 200V 20% BC C345 2222-037-58478 4.7uF RSM 037 63V 20% BC C346 2222-379-44224 220nF MKP 379 250V 5% BC C347 2222-655-09102 1nF C655 500V 10% BC C348 2222-044-90015 2.2UF RSH 044 250V 20% BC C349 2222-370-85223 22nF MKT 370 100V 10% BC C350 2222-379-54823 82nF MKP 379 400V 5% BC C351 2222-379-54224 220nF MKP 379 400V 5% BC C352 2222-379-54474 470nF MKP 379 400V 5% BC C353 DE0405-B-101K2K ‘100pF Hi_voltage 2000V 10% muRata C354 2222-655-09102 1nF C655 500V 10% BC C355 2222-376-92472 4.7nF KP/MMKP 376 2000V 5% BC C356 2222-379-54224 220nF MKP 379 400V 5% BC C357 2222-370-65472 4.7nF MKT 370 400V 10% BC C358 2222-370-85104 100nF MKT 370 100V 10% BC C359 2222-370-85104 100nF MKT 370 100V 10% BC C360 2222-370-85104 100nF MKT 370 100V 10% BC C361 2222-376-72562 5.6nF KP/MMKP 376 1000V 5% BC C362 2222-037-58478 4.7uF RSM 037 63V 20% BC C363 2222-370-85104 100nF MKT 370 100V 10% BC C364 2222-097-56479 47uF RLP7 097 25V 20% BC C365 2222-370-35472 4.7nF MKT 370 250V 10% BC C366 2222-630-09332 3.3nF C630 100V 10% BC C367 2222-097-50478 4.7uF RLP7 097 35V 20% BC C368 2222-479-34335 3.3uF MKP 479 160V 5% BC C369 2222-370-85153 15nF MKT 370 100V 10% BC C370 2222-630-09222 2.2nF C630 100V 10% BC C371 2222-037-58109 10uF RSM 037 63V 20% BC C372 2222-037-51109 10uF RSM 037 50V 20% BC C376 2222-370-75105 1uF MKT 370 63V 10% BC C378 2222-370-35223 22nF MKT 370 250V 10% BC C380 2222-037-65689 68uF RSM 037 16V 20% BC C390 2222-037-56479 47uF RSM 037 25V 20% BC D200 9330-839-90153 1N4148 Gen_Purpose 75V - PHILIPS D201 9330-839-90153 1N4148 Gen_Purpose 75V - PHILIPS D202 9333-984-40112 BT149G Thyr_Triac 600G_ - PHILIPS D203 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D204 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D205 9340-418-70113 BYV27-600 Rectifier 600V_ - PHILIPS D206 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D207 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D208 9340-418-70113 BYV27-600 Rectifier 600V_ - PHILIPS 4l Philips Semiconductors ECO-Monitor Application Note AN00057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR D209 9330-839-90153 n.m. Gen_Purpose 75V PHILIPS D210 9340-366-90133 BYV27-400 Rectifier 400V_ - PHILIPS D211 9337-537-40113 BYD73A Rectifier 50VPHILIPS D212 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D213 9337-537-40113 BYD73A Rectifier 50VPHILIPS D214 9336-247-60112 BAT85 Schottky - = PHILIPS D215 9333-636-10113 BYW54 Rectifier 600V_ - PHILIPS D216 9337-537-40113 BYD73A Rectifier 50VPHILIPS D217 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D218 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D219 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D220 9330-839-90153 1N4148 Gen_Purpose 75V - PHILIPS D221 9337-537-40113 BYD73A Rectifier 50VPHILIPS D285 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D286 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D287 9331-892-10153 BAV21 Gen_Purpose - = PHILIPS D288 9331-892-10153 BAV21 Gen_Purpose - = PHILIPS D321 9335-435-00133 BYV27-100 Rectifier 100V_ - PHILIPS D340 9340-215-20113 BYV99 Rectifier - = PHILIPS D341 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS D342 9337-234-10113 BYD33G Rectifier 400V_ - PHILIPS D343 9335-435-00133 BYV27-100 Rectifier 100V_ - PHILIPS D344 9337-538-00113 BYD73G Rectifier 400V_ - PHILIPS D345 9337-538-00113 BYD73G Rectifier 400V_ - PHILIPS D346 9337-538-00113 BYD73G Rectifier 400V_ - PHILIPS D347 9340-560-30127 BYM357X Gen_Purpose - = PHILIPS D348 9330-839-90153 1N4148 Gen_Purpose 75V PHILIPS F200 2412-086-28196 2A FAST - PHILIPS IC1 PN-TEA1507 TEA1507 SMPS controller - = PHILIPS ICc2 9352-674-52112 TDA4856_V3 Deflection contr. - = PHILIPS IC3 9352-637-54112 TDA4863J_V1 Vertical booster - = PHILIPS IC4 PN-P83C380 P83C380 Microprocessor - = PHILIPS IC5 PN-LM7812CT LM7812CT Stab_Pos - = NS IC6 PN-LM7805CT LM7805CT Stab_Pos - NS IC7 9350-646-00112 PCF8598CP EEPROMs - = PHILIPS J240 2422-021-98731 JUMPER_2p print_switch - = PHILIPS J340 2422-021-98731 JUMPER_2p print_switch - = PHILIPS J341 2422-021-98731 JUMPER_2p print_switch - = PHILIPS J342 2422-021-98731 JUMPER_2p print_switch - = PHILIPS L200 3112-338-31902 CU20d3 Chokes - = PHILIPS L201 TSLO709-33K1R9 33uH TSLO709 - 10% TDK L202 TSLO709RA220uH TSLO709 - 20% TDK 221KR44 L203 TSLO709-101KR66 100uUH TSLO709 - 20% TDK L204 TSLO709-101KR66 100uUH TSLO709 - 20% TDK L210 TSLO709-101KR66 100uUH TSLO709 - 20% TDK L211 TSLO709-101KR66 100uUH TSLO709 - 20% TDK L212 4330-030-38741 BDW3.5_6-4S2 BDW - PHILIPS L213 4330-030-38741 BDW3.5_6-4S2 BDW - PHILIPS L340 TSLO709-33K1R9 68uH TSLO709 - 10% TDK L341 TSLO709-4R7M2R6 4.7uH TSLO709 - 20% TDK L342 8228-001-35832 CU20 DC05 - = PHILIPS L343 4330-030-38741 BDW3.5_6-4S2 BDW - PHILIPS L344 3122-138-57081 AT4042_32A Adj_Corr - = PHILIPS L345 B78108-S1824-J 820uH B78108-S - 5% SIEMENS L346 4330-030-38731 BDW3.5_4.5-4S2 BDW - = PHILIPS L347 4330-030-38731 BDW3.5_4.5-4S2 BDW - = PHILIPS OC200 9338-846-80127 CNX82A CNX - = PHILIPS P201 MKS3736-1-0-606 MKS3730_6p MKS3730 - = STOCKO 42 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR P204 MKS3744-1-0-1414 MKS3730_14p MKS3730 - = STOCKO P205 210-535 VGA_BUS_15p_sqr DCONN - = FARNELL P206 MKS3733-1-0-303 MKS3730_3p MKS3730 - = STOCKO P207 MKS3737-1-0-707 MKS3730_7p MKS3730 - = STOCKO P208 MKS3733-1-0-303 MKS3730_3p MKS3730 - = STOCKO P209 MKS3734-1-0-404 MKS3730_4p MKS3730 - = STOCKO P210 2422-015-12986 FASTON_WIRECONTACT - - * P211 2422-015-12986 FASTON_WIRECONTACT - - * P212 MKS3733-1-0-303 MKS3730_3p MKS3730 - = STOCKO P213 MKS3733-1-0-303 MKS3730_3p MKS3730 - = STOCKO P214 PCB-EXP-GEOM Mains_inlet - - = * P215 MKS3733-1-0-303 MKS3730_3p MKS3730 - = STOCKO R189 2322-187-53101 100 SFR16S - 5% BC R190 2322-187-53479 47 SFR16S - 5% BC R191 2322-484-75223 22k EMP10 - 10% BC R192 2322-193-14519 51 PRO1 - 5% BC R193 2322-187-53479 47 SFR16S - 5% BC R194 2322-187-53109 10 SFR16S - 5% BC R195 2322-187-53109 10 SFR16S - 5% BC R200 2322-187-53104 100k SFR16S - 5% BC R201 2322-187-53223 22k SFR16S - 5% BC R202 2322-187-53103 10k SFR16S - 5% BC R203 2322-187-53333 33k SFR16S - 5% BC R204 2322-187-53333 33k SFR16S - 5% BC R205 2322-187-53103 10k SFR16S - 5% BC R206 2322-241-13475 4.7M VR25 - 5% BC R207 2322-241-13475 4.7M VR25 - 5% BC R208 2322-187-53223 22k SFR16S - 5% BC R210 2322-594-XXXXKX 14 to 550V VDR - BC R211 2322-187-53105 n.m. SFR16S - 5% BC R212 2322-156-21501 150 MRS25 - 1% BC R214 2322-193-14478 4.7 PRO1 - 5% BC R215 2322-187-53109 10 SFR16S - 5% BC R216 2322-187-53102 1k SFR16S - 5% BC R217 2322-187-53471 470 SFR16S - 5% BC R218 2322-187-53333 33k SFR16S - 5% BC R219 2322-193-14337 PRO1/0.33 PRO1 - 5% BC R220 2322-193-14337 PRO1/0.33 PRO1 - 5% BC R221 2322-156-21501 150 MRS25 - 1% BC R222 2322-187-53274 270k SFR16S - 5% BC R224 2322-193-14339 33 PRO1 - 5% BC R225 2322-187-53471 470 SFR16S - 5% BC R226 2322-156-21544 154k MRS25 - 1% BC R227 2322-187-53103 10k SFR16S - 5% BC R228 2322-187-53471 470 SFR16S - 5% BC R229 2322-187-53153 15k SFR16S - 5% BC R230 2322-187-53102 1k SFR16S - 5% BC R231 2322-187-53103 10k SFR16S - 5% BC R232 2322-156-22102 2.1k MRS25 - 1% BC R233 2322-187-53104 100k SFR16S - 5% BC R234 2322-187-53222 2.2k SFR16S - 5% BC R235 2322-187-53103 n.m. SFR16S - 5% BC R236 2322-187-53473 47k SFR16S - 5% BC R237 2322-662-96687 MONO_PTC_20_276_26K PTC - 5% BC R240 2322-187-53333 33k SFR16S - 5% BC R241 2322-187-53472 4.7k SFR16S - 5% BC R242 2322-187-53472 4.7k SFR16S - 5% BC R243 2322-187-53101 100 SFR16S - 5% BC R244 2322-187-53101 100 SFR16S - 5% BC 43 Philips Semiconductors Application Note ANO0057 ECO-Monitor REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR R245 2322-187-53103 10k SFR16S - 5% BC R246 2322-187-53101 100 SFR16S - 5% BC R247 2322-187-53101 100 SFR16S - 5% BC R248 2322-187-53103 10k SFR16S - 5% BC R249 2322-187-53101 100 SFR16S - 5% BC R250 2322-205-33108 1 NFR25 - 5% BC R251 2322-205-33108 1 NFR25 - 5% BC R252 2322-187-53101 100 SFR16S - 5% BC R253 2322-187-53101 100 SFR16S - 5% BC R254 2322-187-53101 100 SFR16S - 5% BC R255 2322-187-53101 100 SFR16S - 5% BC R256 2322-187-53101 100 SFR16S - 5% BC R258 2322-187-53472 4.7k SFR16S - 5% BC R259 2322-187-53101 100 SFR16S - 5% BC R260 2322-187-53472 4.7k SFR16S - 5% BC R261 2322-187-53101 100 SFR16S - 5% BC R262 2322-187-53101 100 SFR16S - 5% BC R263 2322-187-53472 4.7k SFR16S - 5% BC R264 2322-187-53472 4.7k SFR16S - 5% BC R265 2322-187-53101 100 SFR16S - 5% BC R266 2322-186-76101 100 SFR25H - 5% BC R267 2322-187-53472 4.7k SFR16S - 5% BC R268 2322-187-53101 100 SFR16S - 5% BC R269 2322-187-53101 100 SFR16S - 5% BC R270 2322-187-53101 100 SFR16S - 5% BC R271 2322-187-53105 1M SFR16S - 5% BC R272 2322-187-53392 3.9k SFR16S - 5% BC R274 2322-187-53104 100k SFR16S - 5% BC R276 2322-187-53563 56k SFR16S - 5% BC R277 2322-187-53222 2.2k SFR16S - 5% BC R280 2322-187-53101 100 SFR16S - 5% BC R281 2322-187-53101 100 SFR16S - 5% BC R282 2322-187-53334 330k SFR16S - 5% BC R283 2322-187-53103 10k SFR16S - 5% BC R284 2322-187-53152 1.5k SFR16S - 5% BC R285 2322-187-53432 4.3k SFR16S - 5% BC R286 2322-187-53183 18k SFR16S - 5% BC R288 2322-187-53101 100 SFR16S - 5% BC R289 2322-187-53683 68k SFR16S - 5% BC R291 2322-187-53182 1.8k SFR16S - 5% BC R292 2322-187-53273 27k SFR16S - 5% BC R293 2322-187-53103 10k SFR16S - 5% BC R295 2322-156-22742 2.74k MRS25 - 1% BC R296 2322-156-21212 1.21k MRS25 - 1% BC R298 2322-187-53332 3.3k SFR16S - 5% BC R299 2322-187-53XXX XR_SFR16S SFR16S - 5% BC R300 2322-187-53683 68k SFR16S - 5% BC R301 2322-187-53XXX XR_SFR16S SFR16S - 5% BC R302 2322-205-33478 4.7 NFR25 - 5% BC R303 2322-187-53223 22k SFR16S - 5% BC R304 2322-187-53101 100 SFR16S - 5% BC R305 2322-187-53101 100 SFR16S - 5% BC R306 2322-187-53101 100 SFR16S - 5% BC R307 2322-187-53101 100 SFR16S - 5% BC R308 2322-187-53101 100 SFR16S - 5% BC R309 2322-187-53101 100 SFR16S - 5% BC R310 2322-187-53101 100 SFR16S - 5% BC R311 2322-187-53184 180k SFR16S - 5% BC R312 2322-187-53103 10k SFR16S - 5% BC 44 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR R313 2322-186-76475 4.7M SFR25H - 5% BC R315 2322-187-53333 33k SFR16S - 5% BC R316 2322-187-53101 100 SFR16S - 5% BC R317 2322-186-76103 10k SFR25H - 5% BC R318 2322-187-53104 100k SFR16S - 5% BC R319 2322-187-53101 100 SFR16S - 5% BC R320 2322-187-53472 4.7k SFR16S - 5% BC R321 2322-187-53121 120 SFR16S - 5% BC R322 2322-187-53101 100 SFR16S - 5% BC R323 2322-187-53101 100 SFR16S - 5% BC R324 2322-187-53221 220 SFR16S - 5% BC R325 2322-187-53568 5.6 SFR16S - 5% BC R326 2322-187-53182 1.8k SFR16S - 5% BC R327 2322-187-53108 1 SFR16S - 5% BC R328 2322-187-53182 1.8k SFR16S - 5% BC R329 2322-187-53108 1 SFR16S - 5% BC R330 2322-187-53188 1.8 SFR16S - 5% BC R340 2322-187-53103 10k SFR16S - 5% BC R341 2322-187-53822 8.2k SFR16S - 5% BC R342 2322-187-53101 100 SFR16S - 5% BC R343 2322-187-53121 120 SFR16S - 5% BC R344 2322-187-53563 56k SFR16S - 5% BC R345 2322-187-53102 1k SFR16S - 5% BC R346 2322-194-14471 470 PRO2 - 5% BC R347 2322-187-53333 33k SFR16S - 5% BC R348 2322-187-53104 100k SFR16S - 5% BC R349 2322-187-53102 1k SFR16S - 5% BC R350 2322-187-53101 100 SFR16S - 5% BC R351 2322-187-53154 150k SFR16S - 5% BC R352 2322-186-76102 1k SFR25H - 5% BC R353 2322-186-76102 1k SFR25H - 5% BC R354 2322-186-76681 680 SFR25H - 5% BC R355 2322-186-76752 7.5k SFR25H - 5% BC R356 2322-187-53151 150 SFR16S - 5% BC R357 2322-187-53479 47 SFR16S - 5% BC R358 2322-187-53154 150k SFR16S - 5% BC R359 2322-187-53154 150k SFR16S - 5% BC R360 2322-187-53101 100 SFR16S - 5% BC R361 2322-187-53154 150k SFR16S - 5% BC R362 2322-187-53103 10k SFR16S - 5% BC R363 2322-187-53103 10k SFR16S - 5% BC R364 2322-187-53103 10k SFR16S - 5% BC R365 2322-187-53689 68 SFR16S - 5% BC R366 2322-187-53109 10 SFR16S - 5% BC R367 2322-187-53472 4.7k SFR16S - 5% BC R368 2322-187-53472 4.7k SFR16S - 5% BC R369 2322-187-53472 4.7k SFR16S - 5% BC R371 2322-187-53102 1k SFR16S - 5% BC R372 2322-187-53188 1.8 SFR16S - 5% BC R373 2322-187-53333 33k SFR16S - 5% BC R374 2322-187-53333 33k SFR16S - 5% BC R375 2322-187-53101 100 SFR16S - 5% BC R376 2322-187-53153 15k SFR16S - 5% BC R377 2322-187-53471 470 SFR16S - 5% BC R378 2322-187-53222 2.2k SFR16S - 5% BC R379 2322-187-53203 20k SFR16S - 5% BC R380 2322-187-53103 10k SFR16S - 5% BC R381 2322-187-53103 10k SFR16S - 5% BC R382 2322-187-53103 10k SFR16S - 5% BC 45 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR R383 2322-187-53101 100 SFR16S - 5% BC R384 2322-187-53182 1.8k SFR16S - 5% BC R385 2322-187-53151 150 SFR16S - 5% BC R386 2322-187-53101 100 SFR16S - 5% BC R387 2322-187-53561 560 SFR16S - 5% BC R388 2322-194-14109 10 PRO2 - 5% BC R389 AB-EB1025 1k EBx - 5% A-BRADLEY R390 2322-187-53479 47 SFR16S - 5% BC R392 2322-187-53104 100k SFR16S - 5% BC R393 2322-187-53363 36k SFR16S - 5% BC R394 2322-187-53479 47 SFR16S - 5% BC R395 2322-187-53392 3.9k SFR16S - 5% BC R396 2322-187-53182 1.8k SFR16S - 5% BC R397 2322-187-53182 1.8k SFR16S - 5% BC RL200 625-589 RTE24 12Vdc 2x ch RTE24 - Farnell T200 8228-001-3565C CE423V Switch_Mode - = PHILIPS T340 3128-138-35672 CU15/50 Line_driver - = PHILIPS T341 3138-138-31951 AT2097_32B Line_Output - = PHILIPS T342 8228-001-38041 CU15 Dyn_foc - PHILIPS TR200 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR201 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR202 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR203 STP/7NB80FP STP7NB80FP fets - = ST TR204 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR205 9332-055-40112 BC556 Gen_Purpose - = PHILIPS TR272 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR273 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR274 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR285 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR286 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR288 9334-311-90116 MPSA92 High_Voltage - = PHILIPS TR289 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR340 PN-IRF9630 IRF9630 fets - = IR TR341 = 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR343 =9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR344 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR345 = 9335-354-70116 MPSA43 High_Voltage - PHILIPS TR346 9340-557-64127 PHP18NQ20T fets - = PHILIPS TR347 9340-557-64127 PHP18NQ20T fets - = PHILIPS TR348 9340-557-64127 PHP18NQ20T fets - = PHILIPS TR349 9340-548-01127 BU4523AF Pow_HV_Switch - = PHILIPS TR350 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR351 =9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR352 = 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR353 = 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR354 9332-026-20112 BC557B Gen_Purpose - = PHILIPS TR355 = 9332-219-40112 BC639 Gen_Purpose - = PHILIPS TR356 BD677 BD677 Pow_Low_Freq - = ST TR390 9331-976-10112 BC547 Gen_Purpose - = PHILIPS X240 9922-520-12MHz 12MHz Crystal - = PHILIPS Z200 9331-177-60153 BZX79C BZX79C 7V5 - PHILIPS 2201 TL431C TL431C Misc - TI 2202 9331-178-10153 BZX79C BZX79C 12V. - PHILIPS 2285 9334-146-80153 BZX79C BZX79C 2Vv4 - PHILIPS Z286 9331-177-10153 BZX79C BZX79C 4AV7_siPHILIPS 2321 9331-179-50153 BZX79C BZX79C 47Vi; PHILIPS Z340 9331-178-10153 BZX79C BZX79C 12V. - PHILIPS 46 Philips Semiconductors ECO-Monitor Application Note AN00057 6.2 Video board REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR C1 2222-044-90501 1uF RSH 044 250V 20% BC C2 2222-370-75104 100nF MKT 370 63V 10% BC C3 2222-044-63109 10uF RSH 044 250V 20% BC C4 2222-370-85334 330nF MKT 370 100V 10% BC C5 2222-629-09102 1nF C629 63V -20 +80% BC C6 2222-370-75104 100nF MKT 370 63V 10% BC C7 2222-370-35103 10nF MKT 370 250V 10% BC C8 2222-370-75104 100nF MKT 370 63V 10% BC cg 2222-370-85104 100nF MKT 370 100V 10% BC C10 2222-370-75334 330nF MKT 370 63V 10% BC C11 2222-037-58339 33uF RSM 037 63V 20% BC C12 2222-370-75104 100nF MKT 370 63V 10% BC C13 2222-370-35103 10nF MKT 370 250V 10% BC C14 2222-044-90501 1uF RSH 044 250V 20% BC C15 2222-370-75104 100nF MKT 370 63V 10% BC C16 2222-370-35103 10nF MKT 370 250V 10% BC C17 DE0807102K 1nF Hi_voltage 2000V 10% muRata C18 2222-044-63109 10uF RSH 044 250V 20% BC C19 DE0807102K 1nF Hi_voltage 2000V 10% muRata C20 2222-044-90501 1uF RSH 044 250V 20% BC C21 2222-681-10101 100pF C638-NPO 100V 2% BC C22 2222-681-10569 5S6pF C638-NPO 100V 2% BC C24 2222-370-75104 100nF MKT 370 63V 10% BC C30 2222-044-63109 10uF RSH 044 250V 20% BC C35 2222-044-32479 47uF RSH 044 200V 20% BC C36 2222-037-51109 10uF RSM 037 50V 20% BC C37 2222-037-54101 100uF RSM 037 10V 20% BC C38 2222-037-56479 47uF RSM 037 25V 20% BC C39 2222-370-75104 100nF MKT 370 63V 10% BC C41 2222-370-35223 22nF MKT 370 250V 10% BC C42 2222-629-09223 22nF C629 63V -20+80% BC C45 2222-370-75224 220nF MKT 370 63V 10% BC C50 2222-370-75104 100nF MKT 370 63V 10% BC C52 2222-681-10479 47pF C638-NPO 100V 2% BC C53 2222-681-10479 47pF C638-NPO 100V 2% BC C54 2222-370-35104 100nF MKT 370 250V 10% BC C55 2222-629-09223 22nF C629 63V -20+80% BC C58 2222-629-09102 1nF C629 63V -20+80% BC C60 2222-629-09102 1nF C629 63V -20+80% BC C62 2222-370-65102 1nF MKT 370 400V 10% BC D1 9330-839-90153 1N4148 Gen_Purpose 75V~ PHILIPS D2 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D3 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D4 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D5 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D6 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D7 9331-892-10153 BAV21 Gen_Purpose - PHILIPS D8 9330-839-90153 1N4148 Gen_Purpose 75V~ PHILIPS 1 CVT3280-2202 CVT3280_CRT - - = SMK IC3 PN-LM7808CT LM7808CT Stab_Pos - = NS IC4 PN-MC141545P2 MC141545P2 OSD generator - MOTOROLA IC6 9352-640-61112 TDA4887PS Video preamp - = PHILIPS IC7 PN-LM2435T LM2435T Video_amp - NS L6 TSLO709-100K1R9 10uUH TSLO709 - 10% TDK L7 LALO3NAR22M 220nH LALO3NA - 10% TAIYO_YUDEN 47 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR L8 LALO3NAR22M 220nH LALO3NA - 10% TAIYO_YUDEN L9 LALO3NAR22M 220nH LALO3NA - 10% TAIYO_YUDEN P2 4022-007-45420 SOLDER-PIN_large - - PHILIPS P3 4022-007-45420 SOLDER-PIN_large - - PHILIPS P4 4022-007-45420 SOLDER-PIN_large - - PHILIPS P5 4022-007-45420 SOLDER-PIN_large - - PHILIPS P101 MKS3744-1-0-1414 MKS3730_14p MKS3730 - = STOCKO P102 MKS3736-1-0-606 MKS3730_6p MKS3730 - = STOCKO R1 2322-187-53109 10 SFR16S - 5% BC R2 2322-187-53105 1M SFR16S - 5% BC R3 ERC12GJ470C 47 ERC12 - 5% MATSUSHITA R4 2322-193-14223 22k PRO1 - 5% BC R5 2322-187-53479 47 SFR16S - 5% BC R6 2322-187-53101 100 SFR16S - 5% BC R7 2322-187-53108 1 SFR16S - 5% BC R8 2322-187-53103 10k SFR16S - 5% BC RQ 2322-187-53683 68k SFR16S - 5% BC R10 2322-187-53101 100 SFR16S - 5% BC R11 2322-187-53101 100 SFR16S - 5% BC R12 2322-187-53101 100 SFR16S - 5% BC R13 2322-187-53109 10 SFR16S - 5% BC R14 2322-187-53101 100 SFR16S - 5% BC R15 2322-187-53109 10 SFR16S - 5% BC R16 2322-187-53101 100 SFR16S - 5% BC R17 2322-187-53181 180 SFR16S - 5% BC R18 2322-187-53332 3.3k SFR16S - 5% BC R19 2322-187-53109 10 SFR16S - 5% BC R20 2322-205-33338 3.3 NFR25 - 5% BC R21 2322-187-53339 33 SFR16S - 5% BC R22 2322-187-53101 100 SFR16S - 5% BC R23 2322-187-53109 10 SFR16S - 5% BC R24 2322-187-53759 75 SFR16S - 5% BC R25 2322-187-53339 33 SFR16S - 5% BC R26 2322-187-53109 10 SFR16S - 5% BC R27 2322-187-53479 47 SFR16S - 5% BC R28 2322-187-53759 75 SFR16S - 5% BC R29 2322-187-53101 100 SFR16S - 5% BC R30 2322-187-53101 100 SFR16S - 5% BC R31 2322-187-53105 1M SFR16S - 5% BC R32 ERC12GJ470C 47 ERC12 - 5% MATSUSHITA R33 2322-187-53103 10k SFR16S - 5% BC R35 2322-187-53339 33 SFR16S - 5% BC R36 2322-187-53101 100 SFR16S - 5% BC R37 2322-193-14223 22k PRO1 - 5% BC R38 2322-187-53101 100 SFR16S - 5% BC R39 2322-187-53109 10 SFR16S - 5% BC R40 2322-187-53759 75 SFR16S - 5% BC R41 2322-187-53103 10k SFR16S - 5% BC R42 2322-187-53683 68k SFR16S - 5% BC R43 2322-187-53109 10 SFR16S - 5% BC R44 2322-187-53101 100 SFR16S - 5% BC R45 2322-187-53221 220 SFR16S - 5% BC R47 ERC12GJ272C 2.7K ERC12 - 5% MATSUSHITA R49 2322-187-53101 100 SFR16S - 5% BC R50 2322-187-53101 100 SFR16S - 5% BC R51 2322-187-53181 180 SFR16S - 5% BC R52 2322-187-53332 3.3k SFR16S - 5% BC R54 2322-187-53105 1M SFR16S - 5% BC R55 ERC12GJ470C 47 ERC12 - 5% MATSUSHITA 48 Philips Semiconductors ECO-Monitor Application Note ANO0057 REF. PART_NO COMPONENT SERIES RATING TOL. VENDOR R56 2322-193-14223 22k PRO1 - 5% BC R58 2322-187-53103 10k SFR16S - 5% BC R59 2322-187-53683 68k SFR16S - 5% BC R61 2322-187-53181 180 SFR16S - 5% BC R62 2322-187-53332 3.3k SFR16S - 5% BC R63 2322-205-33108 1 NFR25 - 5% BC R64 2322-187-53109 10 SFR16S - 5% BC R65 2322-205-33108 1 NFR25 - 5% BC R68 2322-187-53109 10 SFR16S - 5% BC R69 2322-187-53101 100 SFR16S - 5% BC R71 2322-187-53102 1k SFR16S - 5% BC R73 2322-187-53562 5.6k SFR16S - 5% BC R76 2322-187-53182 1.8k SFR16S - 5% BC R78 2322-187-53561 560 SFR16S - 5% BC R79 2322-187-53101 100 SFR16S - 5% BC R82 2322-187-53224 220k SFR16S - 5% BC R83 2322-187-53102 1k SFR16S - 5% BC R85 2322-187-53105 1M SFR16S - 5% BC R88 2322-187-53101 100 SFR16S - 5% BC R92 2322-187-53103 10k SFR16S - 5% BC R93 2322-187-53103 10k SFR16S - 5% BC R95 2322-187-53101 100 SFR16S - 5% BC R96 2322-187-53101 100 SFR16S - 5% BC R98 2322-187-53101 100 SFR16S - 5% BC R99 2322-187-53109 10 SFR16S - 5% BC R103 2322-187-53479 47 SFR16S - 5% BC R107 2322-187-53479 47 SFR16S - 5% BC R110 2322-205-33101 100 NFR25 - 5% BC R112 2322-187-53479 47 SFR16S - 5% BC R114 2322-187-53101 100 SFR16S - 5% BC R115 ERC12GJ272C 2.7k ERC12 - 5% MATSUSHITA R116 2322-194-14828 8.2 PRO2 - 5% BC TR1 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR2 9335-354-70116 MPSA43 High_Voltage - = PHILIPS TR3 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR4 9335-354-70116 MPSA43 High_Voltage - = PHILIPS TR5 9331-976-10112 BC547 Gen_Purpose - = PHILIPS TR6 9335-354-70116 MPSA43 High_Voltage - = PHILIPS TR8 9331-677-30112 BF324 High_Freq - = PHILIPS TR9 9332-377-90112 BC547C Gen_Purpose - PHILIPS Z1 9331-177-40153 BZX79C BZX79C 6V2 - PHILIPS NS: National Semiconductor TI: Texas Instruments IR: International Rectifier BC: Beyschlag ST: SGS-Thomson 49 **==> picture [442 x 98] intentionally omitted <==** **----- Start of picture text -----**
|||||||||||||| |---|---|---|---|---|---|---|---|---|---|---|---|---| |16.|||R384|1.8kQ|Change|value|to|1.5|kQ| |R379|20 kQ|Change|value|to 24 kQ| |8.||C352|470|nF|Change|value|to|560|nF| |19.||C350|Change|value|to|150|nF| |fl.||C351|220|nF|Change|value|to|270|nF| |112,|=|||Place|SFR16S|resistor|of|22|Ohm|parallel|to|L34|67| **----- End of picture text -----**
Philips Semiconductors Application Note ANO0057 ## ECO-Monitor **==> picture [379 x 211] intentionally omitted <==** **----- Start of picture text -----**
8 ALIGNMENT
8.1 Used equipment
Video generator _| With VESA modes
DMM Fluke PM2421
EHT meter Brandenburg
Oscilloscope Tektronix TDS420
Colour analyser Philips PM5639
PC Minimum '486' with I2C interface card
Software I2C menu software version 3.50.xx for TDA4856 and TDA4887
8.2 Jumper settings
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**==> picture [462 x 367] intentionally omitted <==** **----- Start of picture text -----**
Make sure that the jumpers are in the positions as shown in Figure 8-1 PCB overview ofjumper settings.
7 : 8 DW »* 7
o EA fe
J240: SERV. MODE * Ss Pe
i sf , GE oe
J340 to J342: SAFE STATE
H DEFLECTION HEATSINK
**----- End of picture text -----**
Figure 8-1 PCB overview ofjumper settings 51 Philips Semiconductors ECO-Monitor Application Note ANO0057 8.3 First time adjustment 1. Put in the jumpers on the main board according Figure 8-1 PCB overview ofjumper settings. 2. Connect the video generator and apply a signal with 1024x768 pixels at 60Hz refresh rate (Fh=48kHz) 3. Choose SMPTE test pattern 4. Connect the EHT voltmeter between anode and aqua deck of the CRT 5. Load EEPROM file “ECO.epr” into EEPROM with I’C software and switch monitor off and on 6. If possible make use of a separate degaussing device to demagnetise the CRT 7. Connect the mains supply and switch the monitor on with the functional switch 8. Check that the monitor displays a picture after 8 seconds. If not refer to the debug section. 9. Adjust the EHT voltage to 26.0 kV (+ 0.2kV) with potentiometer R191 10. Display a crosshatch pattern 11. Set dynamic V_focus to max with I2C software. The dynamic focus adjustment is done after the colour adjustment. 12. Adjust the static focus with the focus potentiometer on the line output transformer. Set the static focus while looking at screen area shown in Figure 8-2 On screen checking area. The white circle is the area you should adjust for perfect focus. 13. Test a mode change. If the OSD menu displays the correct frequencies turn off monitor and set SAFE STATE off Gumpers J340 to J342). 14. Test the keypad Figure 8-2 On screen checking area of static focus 8.4 Geometrical adjustment Notes e The raster is the area scanned by the deflection and is visible at high setting of brightness. e The picture is the area with active video, e.g. a crosshatch pattern. 1. Press the menu button once: check that the OSD shows the mode information and the user control menu is displayed 2. Linearity adjustments 52 Philips Semiconductors ECO-Monitor Application Note ANO0057 2.1 Set VSIZE=127 and VPOS=63 2.2 Adjust VOFFS and VGAIN for edge-to-edge phosphor area raster scanning. 2.3 Adjust VLIN and VLINBAL for equal height of all blocks of a crosshatch. 2.4 Adjust VPOS and VSIZE for correct vertical position and height of the picture. 2.5 Adjust HPOS and HSIZE for correct horizontal position and width of the picture. 2.6 Adjust trapezium (HTRAP) and parallelogram (HPARAL) until the middle sections of the vertical borders are vertical. 2.7 Adjust pincushion HPIN and pinbalance HPINBAL until the centre sections of the left and right vertical borders become straight. 2.8 Adjust the top HCORT and bottom HCORB corners until the whole vertical borders become straight. 8.5 Colour adjustment (Please contact SLEfor factory alignment. The second black level adjustment can be avoided by means ofa compensation method in the alignment control software.) 1. Display SMPTE test pattern. 2. If video booster saturates adjust the “Reference voltage” in the I2C software. Default value is 0.75V. 3. Set brightness to 64. 4. Set contrast to 235. 5. Turn black levels (reference levels) to 48 in I2C software. 6. Turn vg2 to minimum with the screen potentiometer on the line output transformer (counter clockwise). 7. Display test pattern with a 1-nit square. 8. Turn up vg2 until the 1-nit square becomes visible. 9. Tune black levels Rb, Bb and Gb to | nit (+ 0.1). Choose colour temperature 6500K on colour analyser and on I2C software. 10. Display test pattern with a 100-nit square. 11. Tune gain levels Rg, Bg and Gg to 100nit (+ 5) with correct balance to colour temperature. 12. Go back to black level adjustment until the black and white levels are according specification. 13. Do the gain level adjustments also for colour temperatures 5500K and 9300K. 14. Save the settings 8.6 Focus adjustment 1. Display a focus pattern (e.g. random text). 2. Adjust static focus 3. Adjust the dynamic focus potentiometer on line output transformer for optimum sharpness on the centre and the edges of the screen. 4. Re-adjust static focus and repeat step 3 if necessary. 8.7 Adjusting other video modes (Do not change other settings, as they are validfor all modes.) 1. Set video generator to new factory mode. 2. Adjust HPOS, HSIZE, VPOS and VSIZE. 53 Fill in **==> picture [275 x 218] intentionally omitted <==** **----- Start of picture text -----**
e = Fuse F200 is not blown
e §=©Output rectifier D208 is not blown
e Horizontal deflection transistors TR340, TR349 are not broken
e Supply voltage on pin 1 of SMPS controller (IC200) is about
e Output drive signal pin 6 of SMPS controller (IC200) 13V pulse
e SMPS switching device TR203 is not broken
e Over-current protection level on pin 5 of IC200 is a sawtooth
e Output rectifiers D210, D211, D213, D216 are not broken
e +12V voltage stabiliser IC201 is not broken
e +5V voltage stabiliser IC202 is not broken
e =©Alignment is ok
e Linearity correction switches are not in safe state (jumpers J340
e Linearity balance corrector has the right value
e = Vertical flyback signal Tfb=300us (+50us); Vpeak = 47V (+3V)
**----- End of picture text -----**
**==> picture [198 x 105] intentionally omitted <==** **----- Start of picture text -----**
|||||||||| |---|---|---|---|---|---|---|---|---| |e|= Vertical|deflection|output|stage|is|not broken| |e|Protection|signals|"Vdefl_pl"|pulsed|high,| |e|DAF|input|on|line|output|transformer pin|12| |e|Focus|signal|on|pin|32|of TDA4856|is|present| |e|Dynamic|focus|transistor|TR345|is OK| |e|=|resistors|R194, R195|are|not broken| **----- End of picture text -----**
Philips Semiconductors ECO-Monitor Application Note ANO0057 10. OSCILLOGRAMS Measurements were done at two video modes: 640x480 at 60 Hz refresh rate, horizontal frequency is 31 kHz, 1024x768 at 85 Hz refresh rate, horizontal frequency is 68 kHz. Both modes are depicted in one oscillogram, except for Figure 10-6 and Figure 10-9. 10.1 Horizontal Deflection Line output transistor = TR349 **==> picture [489 x 206] intentionally omitted <==** **----- Start of picture text -----**
Line driver transistor = TR355
ek Run: TO.0NIS/6 Sample ; ek Run: Tomé Sample i
ons Tomy MS00s ChE FTOamV 8 Sep 2000 “the 20.0mV M5.00ns Ch2 F —44.0mV g sep 2000
Ret 1oomv _5. 00s 09:52:53 Rerl 20.0mV—s«S.00us 09:56:58
Figure 10-1: Collector voltage of TR355 Figure 10-2: Base voltage of TR349
**----- End of picture text -----**
**==> picture [493 x 195] intentionally omitted <==** **----- Start of picture text -----**
ek Run: meine Sample ; ek Run: aad Average i
L Ar
Ch 1.00VQ M5.00Ns Ch2# =1.28V 13 sep 2000 CHS TOOVG Moons ths FT 13 Sep 2000
Ret 1.00V__5.00us 10:51:15 Rel 1.00V_ 2.005 10:59:40
Figure 10-3: Base current of TR349 Figure 10-4: Collector current of TR349
**----- End of picture text -----**
57 Philips Semiconductors Application Note ## ECO-Monitor **==> picture [223 x 179] intentionally omitted <==** **----- Start of picture text -----**
ek Run: 10.0MS7s Sample
[ ]
Rett 2.00V___5.00us 10:00:53
**----- End of picture text -----**
Figure 10-5: Collector voltage of TR349 (=flyback voltage) **==> picture [491 x 178] intentionally omitted <==** **----- Start of picture text -----**
@K Run: 12.5KS7s__ Pk Detect @K Run: 12.5KS7s__ Pk Detect
bt ] bt ]
!
y
!
!
| |
|
i
—_— ee
iyi 500mvV M2.00ms Axl # 840MV 13 Sep 2000 iyi 500mvV M2.00ms Axl # 840MV 13 Sep 2000
11:41:23 11:41:49
**----- End of picture text -----**
Figure 10-6: EW modulator diode voltage 58 Philips Semiconductors ECO-Monitor Application Note 10.2 Vertical deflection **==> picture [223 x 179] intentionally omitted <==** **----- Start of picture text -----**
ek Run: 25.0 sr Average ;
Rett 200mvV__2.00ms 10:43:29
**----- End of picture text -----**
Figure 10-7: Vertical deflection current **==> picture [489 x 196] intentionally omitted <==** **----- Start of picture text -----**
ek Run: 25.0kS/s Sample ek Run: 1.00MS/s Sample
chs ToomV —M2-00ms “ANT FTV 8 Sep 2000 mie ToomY —WSO-Ons ART FTO 8 Sep 2000
al 1oomv —-2.00ms 10:55:46 10:57:25
Figure 10-8: Vertical deflection output voltage Figure 10-9: Vertical flyback voltage
**----- End of picture text -----**
59 Philips Semiconductors ECO-Monitor Application Note AN00057 10.3 Dynamic focus **==> picture [493 x 423] intentionally omitted <==** **----- Start of picture text -----**
ek Run: 5.00MS/7s _ Sample @K Run: 5.00KS7s__ Pk Detect
[--¥- ] [--¥- ]
|
@iry 1.00V M10.0us Axl# 1.10V 13 Sep 2000 AAA.@iry 1.00V M5.00ms Axl [#] 1.10V 13 Sep 2000
10:34:42 10:35:43
Figure 10-10: Horizontal dynamic focus at 31 kHz Figure 10-11: Vertical (+ horizontal) dynamic focus at 60 Hz
ek Run: 10.0MS7s__ Sample @K Run: 12.5KS7s__ Pk Detect
[--¥- ] [--¥- ]
|
y
y
|
i
!
KY la Lan. |
Wie 1.00V = M5.00us Axl F 1.10V 13 Sep 2000 ch2 VV. M2.00ms Axl Ff 1.10V 13 Sep 2000
10:36:23 10:36:50
Figure 10-12: Horizontal dynamic focus at 68 kHz Figure 10-13: Vertical (+ horizontal) dynamic focus at 85 Hz
**----- End of picture text -----**
60 Philips Semiconductors Application Note ANO0057 ## ECO-Monitor Il. DESIGN & EMC CONSIDERATIONS 11.1 EMC The ECO Monitor has passed the EN55022 as mentioned in AN00038 EMC ofMonitors. e The heatsinks are mounted on the PCB with special mounting studs. Some of these studs are connected to the ground plane of the circuit. This grounding provides also EMI shielding. e ©The ferrite core provides HF decoupling in the video cable. e The aquadag is directly connected to the groundplane of the video board by means of a thick wire. In this way the HF video currents are kept local. e An extra grounding wire from the LOT to the video board groundplane provides a low ohmic path to the EHT source, which is also crucial for flashes. 11.2 TCO'99 The ECO is not prepared for TCO’99. Alternating electrical field: 30cm in front of screen: |The RMS value of the alternating electrical field 30cm in front of screen is < ??? V/m. 50cm around monitor: Without extra effort the left side of monitor does not comply with TCO requirements. All other sides comply with TCO. No extra effort was taken in order to keep good serviceability of the deflection parts. Advice for cancelling alternating electrical field around the monitor: e place the horizontal output transistor and the flyback diode (parts that carry the flyback pulse) of the deflection circuit behind the grounded heatsink; e keep all tracks that carry the flyback voltage short in order to lower capacity to the environment; No magnetic field investigations were done. 11.3 Lay-out hints 11.3.1 Ground track The common ground track should be kept as clean as possible. This means that only DC currents should be flowing through this track indicating that the AC currents are short-circuited at their source! Therefore you will find resistor capacitor filters at every stage. For more information see the application note AN00038 EMC ofMonitors. 6l Philips Semiconductors ECO-Monitor Application Note AN00057 11.3.2 Vertical deflection Keep vertical drive signals of the TDA4856 close to each other at all places to avoid magnetic coupling in the loop and to avoid differential stray signals. Apply a separate ground track from the vertical output stage to the SMPS and don’t let other circuits make use of this ground track. 11.3.3 Horizontal deflection output stage Keep flyback capacitor and diode of the horizontal deflection stage located close together to minimise the forward recovery ringing of the flyback diode. To damp the ringing even further a bead-on-wire can be placed in series with the flyback capacitors. Keep current loops that carry the switched horizontal deflection current as small as possible. 11.3.4 Video Make the ground return path as short, but as wide as possible (a ground plane underneath the picture tube socket is recommended because of the low impedance). Advantages ground plane: e Current loops are created if only ground tracks (instead of a ground plane) are used and this can easily cause oscillations; e Shielding against EMI. Disadvantage ground plane: e The ground plane creates parasitic capacitance to the large signal paths. So be aware when you apply a ground plane close to the copper tracks carrying video signals with large amplitude. Too much parasitic capacitance will reduce the video bandwidth. 62 e —_External monitor control by means of the DDC bus interface; e —_ Horizontal sync frequencies from 30 kHz up to 70 kHz; e ~—- Vertical sync frequencies from 50 Hz up to 160 Hz; e = Full VESA DPMS switching, supporting the modes: on, standby, suspend and off; e = Storage of: e ~—-Vertical position and size; e ~—— Horizontal pincushion and pincushion-balance; e —_ Horizontal top corner and bottom corner correction; e = Service mode: **==> picture [397 x 166] intentionally omitted <==** **----- Start of picture text -----**
Select next menu
‘| Mode information or Menu name
------------------»> Selecting menu item
Cr],
Item name _
HIITVTVAVVIVVUVIVTTVITVAVTITATT UT Item value “
User store &
4------------------> Adjusting menu item menu exit
**----- End of picture text -----**
Philips Semiconductors Application Note ANO00057 ## ECO-Monitor ||~~S100~~|~~S100~~|~~S100~~|~~fe~~|~~fe~~| |---|---|---|---|---|---| ||||||| ||||||| ||||||| ||||||| ||||||| ||~~Ea~~
~~[6~~
~~(8~~
~~9~~||~~| ~~||~~OSD~~
~~contrast(minimumvalue=4)~~
~~OSD Vposition~~
~~Userrecall~~| ||||||| |OSD|service menu||||| ||||||| |||Main menu:|||| ||||||| ||||||| ||||||| ||||||| ||||||| ||~~6~~
~~[8~~
~~(9~~||~~size~~
~~| Htopcormer~~
~~|Hbottomeomer~~||| 66 Philips Semiconductors Application Note ANO0057 ## ECO-Monitor ||| |---|---| ||| ||| |~~Ee~~|~~Fe~~| |~~Ee~~
~~6__|~~|~~Fe~~
~~__|BlacklevelforACcoupling(Note:onlyfortheTDA4887)___|~~| |~~Ee~~
~~6__|~~|~~Fe~~
~~__|BlacklevelforACcoupling(Note:onlyfortheTDA4887)___|~~| |~~6 __|~~
~~[8~~
~~|~~|~~__| Black level for AC coupling (Note: only for the TDA4887)___|~~
~~|Redbias~~| |~~[8~~
~~|~~
~~9~~
~~|~~|~~|Redbias~~
~~|Greenbias~~| |~~[8~~
~~|~~
~~9~~
~~|~~|~~| Redbias~~
~~|Greenbias~~| |~~9~~
~~|~~|~~| Greenbias~~| ||| ||| ||| ||| ||| ||| ||| |~~[6~~
~~|~~|~~OSDcontrast(minimalvalue=4)~~| |~~[6~~
~~|~~|~~OSDcontrast(minimalvalue=4)~~| |~~[6~~
~~| ~~
~~8~~
~~|~~|~~OSD contrast(minimal value=4)~~
~~OSDVposition~~| |~~8~~
~~|~~
~~9~~|~~OSDVposition~~
~~Userrecall~~| |~~8~~
~~| ~~
~~9~~|~~OSDVposition~~
~~Userrecall~~| |~~9~~|~~Userrecall~~| ||| ||| ||| ||| ||| ||| |~~5.6~~|| |~~5.6~~|| |~~5.6~~
~~[8~~
~~|~~|~~|Htopcomer~~| |~~[8~~
~~|~~
~~[9~~
~~|~~|~~|Htopcomer~~
~~Hbottomeorner~~| |~~[8~~
~~|~~
~~[9~~
~~|~~|~~| Htopcomer~~
~~Hbottomeorner~~| |~~[9~~
~~| ~~|~~Hbottomeorner~~| ||| ||| ||| ||| ||| ||| |~~EA~~|~~ee~~| |~~EA~~|~~ee~~| 67 Philips Semiconductors Application Note ANO0057 ## ECO-Monitor **==> picture [54 x 28] intentionally omitted <==** **----- Start of picture text -----**
ER
a
**----- End of picture text -----**
12.3.2 Menu item descriptions The sections below describe some OSD menu items in more detail. User store and exit The modified controls are stored into the NVM and the OSD menu is cancelled. This function will also be executed: e automatically in user mode after the OSD menu timeout; e when pressing the menu key on a main menu item which is intended to be adjusted, e.g. pressing the menu key while brightness is selected or adjusted; User recall A user recall fetches, (and updates the IC’s), the previous stored user settings from the NVM. Factory recall A factory recall fetches, (and updates the IC’s), the settings from the NVM which are stored during preprogramming the NVM. They are never changeable by the user. Colour Temperature (CT) selection A selection can be made out of 4 settings: e Fixed settings: 5500K, 6500K and 9300K; e User modifiable setting; It is advisable to store & exit the menu in during adjusting the R-/G-/B-gain and/or R-/G-/B-bias for each CT setting. This due to the fact that only one set of these settings, (R-/G-/B-gain, R-/G-/B-bias), is stored into the micro-controller, and selection of an other CT setting will override the just modified settings. 12.4 External interface control External monitor control is possible by means of the DDC interface. 12.4.1 DDC e ~—- Full support of level DDC1; e = Support of level DDC2 including DDC2B and DDC2Bi; e — EDID version-1 support and prepared for EDID version-2; (Note: EDID version-2 is disabled in the current software version) 68 Philips Semiconductors Application Note ANO0057 ECO-Monitor e Controlling monitor functions according the VESA monitor command set, (see 12.5), in DDC2Bi mode only. (The ACCESS.bus commands must be used, see the table below. Note: see the ACCESS.bus specification for more information) |~~Bese~~
~~foesPee~~|~~Bese~~
~~foesPee~~|~~Bese~~
~~foesPee~~| |---|---|---| |Function:
~~Bese~~
~~foes~~|Op-code |
~~foes~~|| Description:
~~Pee~~| |~~Bese~~
~~foes~~|~~foes~~|~~Pee~~| |||| |||| |~~Sebi Aarltonon~~|~~PP~~|~~Staion ps~~
~~Ome~~
~~ene~~| |EnableApplication Report |
~~Sebi Aarltonon~~|| F5
~~PP~~|Instructs the monitor to start(enable) orto stop (disable) sending
~~Staion ps~~
~~Ome~~
~~ene~~| |~~Sebi Aarlton on ~~|~~PP~~|~~Staion ps~~
~~Ome~~
~~ene~~| |||| |||| ||(hex)|| |GETVCP FEATURE|01|Command instructs the monitor to send information about the
selected control feature backto the host in a replay message. The
VCP op-code informs the monitorwhich feature to return| |||| |||code| |~~[ENABLEVCPFEATURE|0B~~|~~|0B|~~|~~EnablespecificVCPfeature~~| |~~[ENABLEVCPFEATURE|0B~~|~~|0B|~~|~~EnablespecificVCPfeature~~| |~~[ENABLE VCP FEATURE |0B~~|~~|0B | ~~|~~Enable specific VCP feature~~
frequencies to the host| |||| (VCP = Virtual Control Panel) 12.5 List of supported VESA commands The table below shows the supported VESA commands by the OSD menu and the external DDC interfaces. **==> picture [468 x 105] intentionally omitted <==** **----- Start of picture text -----**
code menu service supported dependent
VESA command | VESA(hex) | R/W | OSD user | OSDmenu | DDC | Mode
[Redgain 1G RW XX Xe
[Greengain BR XXX
Began TA RW XXX
**----- End of picture text -----**
69 Philips Semiconductors ECO-Monitor Application Note ANO0057 ||code
hex||menu|service
menu|supported|dependent| |---|---|---|---|---|---|---| |||||||| |||||||| |~~[Viinearity~~
~~BAR~~|~~BAR~~|~~BAR XX~~|~~XX~~|~~XX~~|~~XX~~|~~XX~~| |~~[Viinearity~~
~~BAR~~
~~|Vlinearitybalance~~
~~|~~|~~BAR~~
~~|3C_~~
~~|~~|~~BAR XX~~
~~|RWT-~~|~~XX~~
~~T-~~
~~TX~~|~~XX~~
~~TX~~|~~XX~~
|~~XX~~
| |~~[Viinearity~~
~~BAR~~
~~|Vlinearitybalance~~
~~|~~
~~|Hparallelogram~~
~~[40~~
~~|Htrapezoid~~|~~BAR~~
~~|3C_~~
~~|~~
~~[40~~|~~BAR XX~~
~~|RWT-~~
~~RW TX~~|~~XX~~
~~T-~~
~~TXTX~~
~~TX~~|~~XX~~
~~TXTX~~
~~TXTX~~|~~XX~~
~~TX~~
~~TX~~|~~XX~~
~~TX~~
~~TX~~| |~~|Vlinearity balance~~
~~|~~
~~|Hparallelogram~~
~~[40~~
~~|Htrapezoid~~
~~42~~
~~Tit~~|~~| 3C_~~
~~|~~
~~[40~~
~~42~~|~~| RW T-~~
~~RW TX~~
~~RW TX~~|~~T-~~
~~TXTX~~
~~TX~~
~~TX~~|~~TXTX~~
~~TXTX~~
~~TX~~|~~TX~~
~~TX~~
~~XT~~|~~TX~~
~~TX~~
~~XT~~| |~~|Hparallelogram~~
~~[40~~
~~|Htrapezoid~~
~~42~~
~~Tit~~|~~[40~~
~~42~~|~~RW TX~~
~~RW TX~~|~~TX~~
~~TX~~
~~TX~~|~~TX~~
~~TXTX~~
~~TX~~|~~TX~~
~~TX~~
~~XT~~|~~TX~~
~~TX~~
~~XT~~| |~~[40~~
~~|Htrapezoid~~
~~42~~
~~Tit~~
~~RW~~|~~[40~~
~~42~~
~~RW~~|~~RW TX~~
~~RW TX~~
~~RW TKK~~|~~TX~~
~~TX~~
~~TKK~~|~~TX TX~~
~~TX~~
~~TKK~~|~~TX~~
~~XT~~
~~TKK~~|~~TX~~
~~XT~~
~~TKK~~| |~~42~~
~~Tit~~
~~RW~~|~~42 ~~
~~RW~~|~~RW TX~~
~~RW TKK~~|~~TX~~
~~TKK~~|~~TX ~~
~~TKK~~|~~XT~~
~~TKK~~|~~XT~~
~~TKK~~| |||||||| |||||||| |~~|Redbias~~
~~OC~~|~~OC~~
~~TRW~~|~~TRW~~|~~XX~~|~~XX~~|~~XX~~|~~XX~~| |~~|Redbias~~
~~OC~~
~~[Greenbias~~
~~OE~~|~~OC~~
~~TRW~~
~~OE~~
~~(RW~~|~~TRW~~
~~(RW eX~~|~~XX~~
~~eX~~|~~XX~~
~~eX~~|~~XX~~
~~XT~~|~~XX~~
~~XT~~| |~~|Redbias~~
~~OC~~
~~[Greenbias~~
~~OE~~
~~|Buebias~~
~~0~~|~~OC~~
~~TRW~~
~~OE~~
~~(RW~~
~~0~~|~~TRW~~
~~(RW eX~~
~~RW TX~~|~~XX~~
~~eX~~
~~TX~~|~~XX~~
~~eX~~
~~TX~~|~~XX~~
~~XT~~
~~XK~~|~~XX~~
~~XT~~
~~XK~~| |~~[Greenbias~~
~~OE~~
~~|Buebias~~
~~0~~
~~fosp_~~
~~CA~~|~~OE~~
~~(RW~~
~~0~~
~~CA RW~~|~~(RW eX~~
~~RW TX~~
~~RW~~|~~eX~~
~~TX~~
~~RW~~|~~eX ~~
~~TX~~
~~RW~~|~~XT~~
~~XK~~
~~RW~~|~~XT~~
~~XK~~
~~RW~~| |~~|Buebias~~
~~0~~
~~fosp_~~
~~CA~~
~~[DPMS~~|~~0~~
~~CA RW~~|~~RW TX~~
~~RW~~
~~RW eX~~|~~TX~~
~~RW~~
~~eX~~|~~TX ~~
~~RW~~
~~eX~~|~~XK~~
~~RW~~
~~eX~~|~~XK~~
~~RW~~
~~eX~~| |~~fosp_~~
~~CA~~
~~[DPMS~~
~~|ColourTemperature(CT)[D8~~|~~CA RW~~
~~[D8~~|~~RW~~
~~RW eX~~
~~|RW|X~~|~~RW~~
~~eX~~
~~|X~~
~~[xX~~|~~RW~~
~~eX~~
~~[xX~~|~~RW~~
~~eX~~
|~~RW~~
~~eX~~
| |~~[DPMS~~
~~|ColourTemperature(CT)[D8~~
~~|Hpolarity~~
~~AA~~|~~[D8~~
~~AA~~
~~TRU~~|~~RW eX~~
~~|RW|X~~
~~TRUT-~~|~~eX~~
~~|X~~
~~[xXTX~~
~~T-~~|~~eX~~
~~[xXTX~~
|~~eX~~
~~TX~~
|~~eX~~
~~TX~~
| |~~| Colour Temperature(CT) [D8~~
~~|Hpolarity~~
~~AA~~
~~|Vpolarity~~
~~AG~~|~~[D8~~
~~AA~~
~~TRU~~
~~AG~~
~~TRU~~|~~|RW |X~~
~~TRUT-~~
~~TRU|-~~|~~|X~~
~~[xXTX~~
~~T-K~~
~~|-~~|~~[xXTX~~
~~K~~
|~~TX~~
~~K~~
|~~TX~~
~~K~~
| |~~|Hpolarity~~
~~AA~~
~~|Vpolarity~~
~~AG~~
~~[Synctype~~|~~AA~~
~~TRU~~
~~AG~~
~~TRU~~|~~TRU T-~~
~~TRU|-~~|~~TX~~
~~T-K~~
~~|-KT~~|~~TX~~
~~K~~
~~KT~~|~~TX~~
~~K~~
~~KT~~|~~TX~~
~~K~~
~~KT~~| |~~|Vpolarity~~
~~AG~~
~~[Synctype~~
~~ABORT~~
~~|Hfrequency~~
~~FAC~~|~~AG~~
~~TRU~~
~~ABORT~~
~~FACORT~~|~~TRU |-~~
~~ABORT~~
~~ORT XXX~~|~~K~~
~~|-KT~~
~~ABORT~~
~~XXX~~|~~K~~
~~KT~~
~~ABORT~~
~~XXX~~|~~K~~
~~KT~~
~~ABORT~~
~~XXX~~|~~K~~
~~KT~~
~~ABORT~~
~~XXX~~| |~~[Synctype~~
~~|Hfrequency~~
~~FAC~~
~~[Virequency~~
~~JAE~~|~~FACORT~~
~~JAE~~
~~[RU~~|~~ORT XXX~~
~~[RU~~|~~KT~~
~~XXX~~
~~X~~|~~KT~~
~~XXX~~
|~~KT~~
~~XXX~~
|~~KT~~
~~XXX~~
| |~~|Hfrequency~~
~~FAC~~
~~[Virequency~~
~~JAE~~
~~[Degauss~~
~~ft~~|~~FAC ORT~~
~~JAE~~
~~[RU~~
~~ft~~
~~wT~~|~~ORT XXX~~
~~[RU~~
~~wT~~|~~XXX~~
~~XXX~~
~~wT X~~|~~XXX~~
~~XX~~
|~~XXX~~
~~XX~~
|~~XXX~~
~~XX~~
| |~~[Virequency~~
~~JAE~~
~~[Degauss~~
~~ft~~
~~[Settings~~
~~BO~~|~~JAE~~
~~[RU~~
~~ft~~
~~wT~~
~~BOCTW~~|~~[RU ~~
~~wT~~
~~CTWOT~~|~~XXX~~
~~wT X~~~~**X**~~
~~OT~~|~~XX~~
~~**X**~~|~~XX~~
~~**X**X~~|~~XX~~
~~X~~| |~~[Degauss~~
~~ft~~
~~[Settings~~
~~BO~~
~~|VESA~~|~~ft~~
~~wT~~
~~BOCTW~~
|~~wT~~
~~CTWOT~~|~~XX~~
~~wT X~~~~**X**~~
~~OT~~|~~XX~~
~~**X**~~
~~GG~~|~~XX~~
~~**X**X~~
~~T~~
~~GG~~|~~XX~~
~~X~~
~~T~~| |~~[Settings~~
~~BO~~
~~GQ~~
~~|VESA testtoolcommands:|~~
~~[Set~~|~~BO CTW~~
~~GQ~~
~~||~~|~~CTW OT~~
~~GQ~~
~~**|**~~|~~**X**~~
~~OT~~
~~GQ~~|~~**X**~~
~~GQ~~
~~GG~~|~~**X**X~~
~~T~~
~~GQ~~
~~GG~~|~~X~~
~~T~~
~~GQ~~| |~~GQ~~
~~|VESA testtoolcommands:|~~
~~[SetNVMaddress~~
~~[DC~~|~~GQ~~
~~||~~
~~[DC~~
~~[RW~~|~~GQ~~
~~**|**~~
~~[RWT-~~|~~GQ~~
~~T-~~
~~T-~~|~~GQ~~
~~GG~~
~~T-~~|~~GQ~~
~~GG~~
|~~GQ~~
| |~~|VESA testtoolcommands:|~~
~~[SetNVMaddress~~
~~[DC~~
~~|AccessNVMdata_~~
~~[DBD~~|~~||~~
~~[DC~~
~~[RW~~
~~[DBD[RW~~|~~**|**~~
~~[RWT-~~
~~[RW [~~~~|~~T-~~
~~T-X~~
~~[~~~~|~~GG~~
~~T-X~~
~~[~~~~|~~GG~~
~~X~~
|~~X~~
| |~~testtoolcommands: |~~
~~[Set NVMaddress~~
~~[DC~~
~~|AccessNVMdata_~~
~~[DBD~~
~~|Currentmode number[D9~~
~~|Factorymode~~|~~| |~~
~~[DC~~
~~[RW~~
~~[DBD[RW~~
~~[D9~~|~~**|**~~
~~[RW T-~~
~~[RW [~~~~
~~[RU|-~~|~~T-~~
~~T-X~~
~~[~~XT~~
~~|-~~
~~>XT~~|~~T-X~~
~~[~~XT~~
~~XT~~|~~X~~
~~XT~~
~~XT~~|~~X~~
~~XT~~
~~XT~~| |~~|AccessNVMdata_~~
~~[DBD~~
~~|Currentmode number[D9~~
~~|Factorymode~~
~~[EA~~
~~po~~|~~[DBD [RW~~
~~[D9~~
~~[EA[RW~~|~~[RW [~~~~
~~[RU|-~~
~~[RW~~|~~X~~
~~[~~XT~~
~~|-~~
~~>XT~~
~~eX~~|~~X~~
~~[~~XT~~
~~XT~~
~~eX~~|~~X~~
~~XT~~
~~XT~~
~~eX~~|~~X~~
~~XT~~
~~XT~~
~~eX~~| |~~|Currentmode number[D9~~
~~|Factorymode~~
~~[EA~~
~~po~~|~~[D9~~
~~[EA[RW~~|~~[RU|-~~
~~[RW~~|~~XT~~
~~|-~~
~~>XT~~
~~eX~~|~~XT~~
~~XT~~
~~eX~~|~~XT~~
~~XT~~
~~eX~~|~~XT~~
~~XT~~
~~eX~~| |~~number [D9~~
~~|Factorymode~~
~~[EA~~
~~po~~
~~|~~
~~[OSD~~|~~[D9 ~~
~~[EA[RW~~
~~||~~|~~[RU |-~~
~~[RW~~
~~||~~|~~|-~~
~~>XT~~
~~eX~~
~~||~~|~~XT~~
~~eX~~
~~|~~|~~XT~~
~~eX~~|~~XT~~
~~eX~~| |~~[EA~~
~~po~~
~~|Userdefinedcommands:~~
~~|~~
~~[OSD contra~~~~**t**~~
~~ET~~
~~LOSD~~|~~[EA [RW~~
~~|Userdefinedcommands:~~
~~||~~
~~ET~~
|~~[RW~~
~~|Userdefinedcommands:~~
~~||~~
~~RW~~|~~eX~~
~~|Userdefinedcommands:~~
~~||~~
~~XXX~~|~~eX~~
~~|Userdefinedcommands:~~
~~|~~
~~XXX~~|~~eX~~
~~|Userdefinedcommands:~~
~~XXX~~|~~eX~~
~~|Userdefinedcommands:~~
~~XXX~~| |~~|~~
~~[OSD contra~~~~**t**~~
~~ET~~
~~LOSDhorizonalposition[CB~~|~~||~~
~~ET~~
~~[CB~~
~~|RW~~|~~||~~
~~RW~~
~~|RW|X~~|~~||~~
~~XXX~~
~~|X~~
~~[xX~~|~~|~~
~~XXX~~
~~[xX~~|~~XXX~~
|~~XXX~~
| |~~|~~
~~[OSD contra~~~~**t**~~
~~ET~~
~~LOSDhorizonalposition[CB~~
~~|OSDverticalposition~~
~~|CC_~~|~~| |~~
~~ET~~
~~[CB~~
~~|RW~~
~~|CC_[RW~~|~~| |~~
~~RW~~
~~|RW|X~~
~~[RW|X~~|~~| |~~
~~XXX~~
~~|X~~
~~[xX[Xf~~
~~|X~~|~~|~~
~~XXX~~
~~[xX[Xf~~
|~~XXX~~
~~[Xf~~
|~~XXX~~
~~[Xf~~
| |~~contra~~~~**t**~~
~~ET~~
~~LOSD horizon al position [CB~~
~~|OSDverticalposition~~
~~|CC_~~
~~Vfocus~~
~~BO~~
~~Vein~~|~~ET~~
~~[CB~~
~~|RW~~
~~|CC_[RW~~
~~BOTRW~~|~~RW~~
~~|RW |X~~
~~[RW|X~~
~~TRW~~|~~XXX~~
~~|X~~
~~[xX[Xf~~
~~|X{XTX~~
~~XX~~|~~XXX~~
~~[xX[Xf~~
~~{XTX~~
~~XX~~|~~XXX~~
~~[Xf~~
~~{XTX~~
~~XX~~|~~XXX~~
~~[Xf~~
~~{XTX~~
~~XX~~| |~~|OSD vertical position~~
~~|CC_~~
~~Vfocus~~
~~BO~~
~~Vein~~|~~|CC_ [RW~~
~~BOTRW~~|~~[RW |X~~
~~TRW~~|~~[Xf~~
~~|X{XTX~~
~~XX~~|~~[Xf~~
~~{XTX~~
~~XX~~|~~[Xf~~
~~{XTX~~
~~XX~~|~~[Xf~~
~~{XTX~~
~~XX~~| |~~Vfocus~~
~~BO~~
~~Vein~~
~~RW~~
~~[Voffset~~|~~BOTRW~~
~~RW~~|~~TRW~~
~~RW~~|~~{XTX~~
~~XX~~
~~XK~~|~~{XTX~~
~~XX~~
~~XK~~|~~{XTX~~
~~XX~~
~~XK~~|~~{XTX~~
~~XX~~
~~XK~~| |~~BO~~
~~Vein~~
~~RW~~
~~[Voffset~~
~~RW~~
~~|BasedriveSJ~~|~~BO TRW~~
~~RW~~
~~RW~~
~~SJEB~~
~~OT~~|~~TRW~~
~~RW~~
~~RW~~
~~OTR/W Te~~|~~XX~~
~~XK~~
~~XX~~
~~Te XT~~|~~XX~~
~~XK~~
~~XX~~
~~XT~~|~~XX~~
~~XK~~
~~XX~~
~~XT~~|~~XX~~
~~XK~~
~~XX~~
~~XT~~| |~~RW~~
~~[Voffset~~
~~RW~~
~~|BasedriveSJ~~
~~Ef~~|~~RW~~
~~RW~~
~~SJEB~~
~~OT~~
~~a~~|~~RW~~
~~RW~~
~~OTR/W Te~~
~~a~~|~~XK~~
~~XX~~
~~Te XT~~
~~a~~|~~XK~~
~~XX~~
~~XT~~
~~a~~|~~XK~~
~~XX~~
~~XT~~
~~a~~|~~XK~~
~~XX~~
~~XT~~
~~a~~| |~~RW~~
~~|Basedrive SJ~~
~~Ef~~
only)~~ecco few~~|~~RW~~
~~SJ EB~~
~~OT~~
~~a~~
~~few~~|~~RW~~
~~OTR/W Te~~
~~a~~
~~few~~|~~XX~~
~~Te XT~~
~~a~~
~~few~~|~~XX~~
~~XT~~
~~a~~
~~few~~|~~XX~~
~~XT~~
~~a~~
~~few~~|~~XX~~
~~XT~~
~~a~~
~~few~~| |~~Ef ~~
~~ecco few~~
only)|~~a~~
~~few~~|~~a~~
~~few~~|~~a~~
~~few~~|~~a~~
~~few~~|~~a~~
~~few~~|~~a~~
~~few~~| 70 Philips Semiconductors Application Note AN00057 ## ECO-Monitor Note: X means supported; - means not supported; 12.6 DPMS control Depending upon the status of the incoming sync signals the proper power management mode will be chosen according the next table: **==> picture [479 x 88] intentionally omitted <==** **----- Start of picture text -----**
Present Not present Stand-by Low Video will be blanked & deflection
controller in stand-by state
Not present Present Suspend Low Video will be blanked & deflection
controller in stand-by state
Not present | Not present Off High Video will be blanked, deflection controller
in stand-by state & the SMPS is set into
burst mode
**----- End of picture text -----**
12.7 Horizontal linearity capacitors The switching characteristics of the horizontal linearity capacitors, H_lin0, H_lin1 and H_lin2, are given in the table below. (The output level of the micro-controller pins H_lin0/1/2 is given) **==> picture [342 x 130] intentionally omitted <==** **----- Start of picture text -----**
<= 33 kHz Low Low Low
(also the safe setting)
<= 34 kHz
<= 37 kHz
<= 41 kHz
<= 46 kHz
<= 53 kHz
<= 63 kHz
<= 70 kHz (= max High High High
horizontal frequency)
**----- End of picture text -----**
12.8 NVM related items 12.8.1 Factory pre-programmed video modes The pre-programmed video modes are listed in the table below: **==> picture [299 x 61] intentionally omitted <==** **----- Start of picture text -----**
Factorymode | VESA mode | frequencVertical | Horizontalfrequenc
| [OL] 640x480 31.5 kHz
640 x 480 37.9 kHz
640 x 480 43.3 kHz
**----- End of picture text -----**
7I Philips Semiconductors ECO-Monitor Application Note ANO0057 **==> picture [484 x 190] intentionally omitted <==** **----- Start of picture text -----**
||||||||||||||||||| |---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---| |Factory|VESA|mode|Vertical|Horizontal| |mode|frequenc|frequenc| |800|x|600|37.9|kHz| |800|x|600|46.9|kHz| |800|x|600|53.7|kHz| |||6|||1024x768|48.4|kHz| |1024|x|768|60.0|kHz| |p88| |[x 480]|37.5|kHz| |||[9640]|||1024x768|68.7|kHz| |12.8.2|NVM memory map|layout| |The NVM|mapping|layout|is|given|in|the|table|below|and must|be|used|to|pre-program|the NVM.|The|size|of| |the NVM|is|1024|bytes,|divided|into|4|banks|of 256|byes.| **----- End of picture text -----**
SubContents Remarks address (decimal) 0..39 H- and V-sync The horizontal and vertical frequencies of the factory pre-defined frequencies of the factory | video modes are used during the mode adaptation sequence to pre-defined video modes __| check if the new mode is already stored into the NVM. This data 0 to9 must be pre-programmed into the NVM. The frequencies are stored in groups of 4 bytes: e index 0: horizontal-high; e index 1: horizontal-low; e index 2: vertical-high; e index 3: vertical-low; Example of the frequency coding: 31.50 kHz: 3150 (dec) = OC4E (hex), H-high=0C; H-low=4E 120.5 Hz: 12050 (dec) = 2F12 (hex), V-high=2F; V-low=12 Sub-address mapping: e sub-address 0: factory mode 0; e sub-address 4: factory mode 1; e _sub-address 36: factory mode 9; 72 Philips Semiconductors Application Note ANO0057 ## ECO-Monitor **==> picture [490 x 613] intentionally omitted <==** **----- Start of picture text -----**
Sub- Contents Remarks
address
(decimal)
40... 79 H- and V-sync The horizontal and vertical frequencies of the user programmable
frequencies of the user video modes are used during the mode adaptation sequence to
programmable video check if the new mode is already stored into the NVM.
modes 0 to 9
For the coding see: “H- and V-sync frequencies of the factory pre-
defined video modes 0 to 9”.
Sub-address mapping:
e sub-address 40: user mode 0;
e sub-address 44: user mode 1;
e sub-address 76: user mode 9;
80 .. 89 Sync polarity for the The horizontal and vertical sync polarities of the factory pre-
factory pre-defined video | defined and user programmable video modes are used during the
modes 0 to 9 and user mode adaptation sequence to check if the new mode is already
programmable video stored into the NVM. The data belonging to the factory pre-
modes 0 to 9 programmed video modes must be pre-programmed into the
NVM.
Bit: 7 |6 |5 | 4 | Even modes (0,2,4..)
3 |2 | 1 | 0 | Odd modes (1,3,5..)
value 0 |}0 |0 |0 |H& V negative polarity
0 |0 |0 | 1 | Hnegative; V positive
0 |0 |1 | 0 | Hpositive; V negative
0 ;0 |1 | 1 |H& V positive polarity
O {1 |x |x |H& V polarity is don’t care
Sub-address mapping:
e sub-address 80: factory mode 0 & 1;
e sub-address 84: factory mode 8 & 9;
e sub-address 85: user mode 0 & 1;
e sub-address 89: user mode 8 & 9;
[90 spare | Tobe filled with 0
91 ..210 Mode dependent settings | The following 12 controls are stored for each video mode:
for the factory pre-defined | e index 0: H position; (max value: 255)
video modes 0 to 9 e index 1: H size; (max value: 255)
e index 2: V position; (max value: 127)
e index 3: V size; (max value: 127)
e index 4: H moire; (max value: 63)
e index 5: V moire; (max value: 63)
e index 6: H pincushion (max value: 63)
e index 7: H pincushion balance (max value: 63)
**----- End of picture text -----**
73 Philips Semiconductors Application Note ANO00057 ## ECO-Monitor |address
(decimal)||| |---|---|---| |||e
index 8: Htop corner(max value: 63)
e
index 9: H bottom corner(max: value: 63)
e
index 10: Brightness (max value: 63)
e
index 11: Contrast (max value: 63)
Sub-address mapping:
e
sub-address 91: factorymode 0;
e
sub-address 103: factorymode 1;
e
_sub-address 199: factorymode 9;| |||| |221 .. 340|Mode dependent settings |
forthe user
programmable video
modes 0 to 9|| The 12 controls are stored foreach videomode. Forthe coding
see: “Mode dependent settings forthe factory pre-defined video
modes 0 to 9”.
Sub-address mapping:
e
sub-address 221: usermode 0;
e
sub-address 233: usermode 1;
e
sub-address 329: usermode 9;| |||| |352 ..362 |
~~PO~~
~~[ewer~~||Mode independent
settings
~~[ewer Crocus~~
~~[omvehe~~|The following 11 controls are stored independent for eachvideo
mode:
e
index 0: Htrapezium; (max value: 63)
e
index 1: H parallelogram; (max value: 63)
e
index 2: tilt; (max value: 255)
e
index 3:V linearity; (max value: 15)
e
index 4:V linearity balance; (max value: 15)
e
index 5:V focus; (max value: 15)
e
index 6:V gain; (max value: 63)
e
index 7:V offset; (max value: 15)
e
index 8: OSD contrast; (max value: 15)
e
index 9: OSDH position; (max value: 100)
~~e~~
~~index10:OSD Vposition;(maxvalue:100)~~
~~[omveheforam)~~| |363 ..365
|
~~PO~~
~~[ewer~~|| R-/G-/B-gain settings for
|
~~[ewer Crocus~~
~~[omvehe~~|~~e~~
~~index 10: OSD V position; (max value: 100)~~
| sub-address 363, 364& 365: R-/G-/B-gain foruser setting
~~[omveheforam)~~| |~~PO~~
~~[ewer~~|~~[ewer Crocus~~
~~[omvehe~~|~~[omveheforam)~~| |369|Current mode number|The mode number ofthe current video mode:
e
0 to 9 for factorymode 0 to 9;
e
10 to 19 forusermode0 to 9;| |||indexwraps around from 9 to 0. This means that anew one will
overwrite the oldest mode, in case the 10 usermodes are used.| |||| 74 **==> picture [495 x 74] intentionally omitted <==** Philips Semiconductors Application Note ANO0057 ## ECO-Monitor 13. WINDOWS ?’C-CONTROL SOFTWARE FOR MONITOR IC'S Philips developed a simple bi-directional 2-wire bus for efficient inter-IC control. This bus is called the Inter IC or ’C-bus. All the IC's equipped with this feature incorporate an on-chip interface, which allows them to communicate with each other via the ’C-bus. Here are some features of the I°C -bus: e Only two bus lines are required; a serial data line (SDA) anda serial clock line (SCL) e ach device connected to the bus is software addressable by a unique (Device) address e Serial, 8-bit oriented, bi-directional data transfers can be made at up to 100 kbits/s in the standard mode or up to 400 kbits/s in the fast mode e The number of IC's that can be connected to the same bus is limited only by a maximum bus capacitance of 400pF In most applications the I’C-bus control is performed by a micro-controller. To be able to control all IC's, also those that are not included within a (complete) system, the ’C-control software was developed. The Monitor ’C-Control software is used to control all monitor IC's in co-operation with one of the hardware interface boards mentioned below. 13.1 Hard- and Software Requirements. To be able to run the program you need: 1. An IBM-PC or compatible personal computer; 2. Windows-3.11, Windows-95 , Windows-98 or Windows-NT operating system; 3. Atleast 512 Kbytes of RAM memory; 4. A CENTRONICS to I’C-bus interface board: e Multi-Master; e Hardwareless; e Single-Master; e Dual Single Master Port 1 (Windows NT only); e Dual Single Master Port 2 (Windows NT only). 13.2 Monitor IC's that can be controlled The version 3.60.xx can control the following IC's: 1. Deflection Controllers TDA48xx; 2. Video Controllers TDA488x; 3. Octuple 8-bit DA controller TDA8447; 4. Autosize IC TDA4821. 76 Philips Semiconductors ECO-Monitor Application Note AN00057 13.3 I2C control modes From version 3.60.00 on the I2C software can operate in two control modes: 1) Direct-I2C mode using the internal I2C-bus of the monitor, 2) DDC2Bi mode using the external I2C-bus of the microprocessor. Note: In the ECO-monitor the base-drive current is modulated by the horizontal size information when you regulate Hsize via the OSD-menu or via the PC I2C-software in DDC2Bi mode. Using the PC I2Csoftware in Direct-I2C mode this base-drive current is not modulated, which may cause a high power dissipation in the horizontal deflection transistor. Using the PC I2C-software for controlling the Hsize we advise to use the DDC2Bi mode only. To use Direct-I2c mode connect I2C cable to the lower connector on the mainboard (on the solder side of the PCB), to use DDC2Bi mode connect the I2C cable to the upper connector on the mainboard (on the component side of the PCB). See AN00032 User Manual of the Monitor I2C-Control Software V3.50.xx for more detailed information. This application note can be found in "c:\i2c\common\mon350xx.pdf" after installation of the software. 77 Philips Semiconductors Application Note AN00057 ## ECO-Monitor 14. ACKNOWLEDGEMENTS & REFERENCES 14.1 Application notes 1. ANO00042 Failure Mechanisms of the Line Output Transistor 2. AN00040 Vertical booster TDA48631/TDA4863AJ 3. AN00032 User Manual of the Monitor I2C-Control Software V3.50.xx 4. AN00047 75W SMPS with TEA1507 5. AN97072 BusControlled Autosync Deflection Controller TDA4853/54 6. ETV/AN97002 Low power and low cost horizontal drive circuits with UI5 core 7. ETV/AN97001 Horizontal and Vertical Dynamic Focus Circuit 8. AN96052 B+Converter Topologies for Horizontal Deflection and EHT with TDA4855/58 9. AN00038 EMC ofMonitors 14.2 Datasheets 1. TDA4856 /’C-bus autosync deflection controller for PC monitors, 1998 Oct 02 2. TDA4863 Vertical deflection booster, 1998 Dec 17 3. TDA4887PS 160 MHz bus controlled monitor video pre-amplifier, 1999 Nov 19 4. PCF8598 °C controlled EEPROM 78 **==> picture [94 x 67] intentionally omitted <==** **----- Start of picture text -----**
f PLQ +0.0012x f PLQ
78
f PD[ +0.0012x f PD[
**----- End of picture text -----**
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