TA1360ANG 2003-01-21 1 toshiba bipolar linear integrated circuit silicon monolithic TA1360ANG ycbcr/ypbpr signal and sync processor for digital tv, progressive scan tv and double scan tv the TA1360ANG integrates an analog component signal (ycbcr/ypbpr) processor and sync processor in a 56-pin shrink dip plastic package. the ic is ideal for digital tvs, progressive tvs, and double scan tvs. the luminance block and the color difference block incorporate the high performance signal processing circuits. the sync processor block supports 525i/60, 625i/50, 525p/60, 625p/50, 1125i/50, 1125i/60, 750p/60, (750p/50), pal100 hz, ntsc120 hz, and svga/60(vesa). the TA1360ANG incorporates the i 2 c bus. the device can control various functions via the bus line. features luminance block ? black stretch circuit and dc restoration rate correction circuit ? dynamic correction circuit (gray scale correction) ? srt (lti) ? y group delay correction (shoot balance correction) ? high-bright color circuit ? color detail enhancer (cde) ? white pulse limiter (wpl) ? vsm output color difference block ? fresh color correction ? dynamic y/c correction circuit ? color srt (cti) ? color circuit ? green stretch ? blue stretch text block ? osd blending sw ? acb (only black level) ? two analog rgb inputs synchronization block ? horizontal sync (15.75 k, 28.125 k, 31.5 k, 33.75 k, 37.9 k, 45 khz) ? vertical sync (525i/p, 625i/p, 750p, 1125i/p, pal 100 hz/ntsc 120 hz ? 2- and 3-level sync separator circuit ? hd/vd input (positive and negative polarities) ? copy guard ? vertical blanking weight: 5.55 g (typ.)
TA1360ANG 2003-01-21 2 block diagram dac2 (acb pluse) h-freq sw2 afc filter h curve correction def/dac v cc sw horizontal phase i 2 cbus decoder h frequency sw clamp h duty i 2 l v dd i 2 l gnd y1 in c b1 /p b1 in c r1 /p r1 in def/dac gnd vp out y hd pbpr/ycbcr �: yuv convert sw h curve correction sync sepa hd in sw v integral vd in sw rgb out h c/d hvco h-afc fbp/blk h-ramp 2 f h v c/d v frequency sw acb pulse hd polarity clamp pulse ext v-blk h-blk v-blk v-clp drive clamp blk sw i k cut off rgb brightness clamp rgb contrast mixer sw/ blue back rgb matrix clamp wp blue half tone /c mute color g-y matrix relative phase/ amplitude h-bpp v-bpp uni-color color clamp pulse cp sw ext cp cp/bpp sync out bpp sw ext bpp green stretch tint y/c level comp sw iq �: uv converter uv �: iq converter fresh color clamp y2 in c b2 /p b2 in c r2 /p r2 in black stretch black peak detect dark det black level corection dynamic dc rest sharpness delay line apl detect group delay correction srt wpl clamp uni- color sub- contrast wps half tone /y mute hi-bright color yout- color peak detect sharpness control y detail control cde brightness abcl amp vsm mute vsm amp hpf osd amp clamp osd acl sw y m sw dark area det filter bph filter apl filter abcl in color limiter analog osd g in analog osd r in vsm out analog osd b in y s 1 ( analog osd ) y s 2 (analog osd) i k in analog r in r s/h g s/h b s/h analog gin analog b in y s 3 (analog rgb) y m /p- mute/bl k y/c v cc rgb gnd y/c gnd rgb v cc scl sda cp out scp in hvco h-out fbp in vp out sync in vd in hd in r out g out b out cp2 cp2 cp1 dac2 dac1 cp2 or s/h cp1 sw 19 25 29 32 3 4 5 8 9 10 6 55 44 40 31 30 28 36 18 26 17 22 21 20 23 24 27 14 16 15 43 42 41 38 37 51 50 54 39 11 53 56 1 2 45 48 47 46 35 34 33 49 52 + + + + y b-y g-y r-y y v u light det 7 dl/ color srt vsm filter 12 blue stretch cp2 cp2 cp2 dac1 (sync out) h-freq sw1 13 light area det filter
TA1360ANG 2003-01-21 3 pin assignment apl filter 56 y/c v cc vsm out abcl in y m /p-mute/blk y s 1 (analog osd) 55 54 53 52 51 50 dark area det filter 1 2 3 4 5 6 7 bph filter y1 in c b1 /p b1 in c r1 /p r1 in y/c gnd light area det filter y s 2 (analog osd) y2 in 8 9 10 11 12 13 14 c b2 /p b2 in c r2 /p r2 in color limiter vsm filter h-freq sw1 sync in vd in 15 16 17 18 19 20 21 hd in scp in cp out def/dac v cc afc filter hvco h-freq sw2 22 23 24 25 26 27 28 h curve correction fbp in def/dac gnd h-out vp out y s 3 (analog rgb) 49 r s/h g s/h 48 47 b s/h 46 i k in rgb gnd r out g out b out 45 44 43 42 41 40 rgb v cc analog osd r in 39 analog osd g in analog osd b in 38 37 dac2 (acb pluse) 36 analog r in analog g in analog b in i 2 l gnd sda 35 34 33 32 31 30 scl i 2 l v dd 29 TA1360ANG dac1 (sync out)
TA1360ANG 2003-01-21 4 pin functions pin no. pin name function interface circuit input signal/output signal 1 dark area det filter connects filter for detecting dark area. voltage of this pin controls dynamic circuit gain for dark area. dc 2 bph filter connects filter for detecting black peak. voltage of this pin controls black stretch gain. leaving y open and setting the test circuit sw 2 = c enable to monitor h/v-bpp (black-stretch-stop pulse) width. dc 3 y1 in inputs y1 signal via clamp capacitor. 1 vp-p (including sync) at 100% color bar or 4 c b1 /p b1 in inputs c b1 /p b1 signal via clamp capacitor. 700 mvp-p at 100% color bar for c b1 /p b1 5 c r1 /p r1 in inputs c r1 /p r1 signal via clamp capacitor. 700 mvp-p700 mvp-p at 100% color bar for c r1 /p r1 6 y/c gnd gnd pin for y/c block ? ? 7 light area det filter connects filter for detecting light area. voltage of this pin controls dynamic circuit gain for light area. dc 55 1 6 100 k ? 5 k ? 1 k ? 1 k ? 40 6 1 k ? 1 k ? 5 k ? 3 4 5 55 7 6 100 k ? 5 k ? 1 k ? 1 k ? 55 2 6 1 k ? 200 ? 4 k ? 1 k ? 1 k ? 5 v
TA1360ANG 2003-01-21 5 pin no. pin name function interface circuit input signal/output signal 8 y2 in inputs y2 signal via clamp capacitor. 1 vp-p (including sync) at 100% color bar or 9 c b2 /p b2 in inputs c b2 /p b2 signal via clamp capacitor. 700 mvp-p at 100% color bar for c b1 /p b1 10 c r2 /p r2 in inputs c r2 /p r2 signal via clamp capacitor. 700 mvp-p700 mvp-p at 100% color bar for c r1 /p r1 11 color limiter connects filter for detecting color limit. dc 12 vsm filter connects vsm output filter. connect 0.01- f capacitor between this pin and gnd. dc 13 h-freq sw1 switches horizontal frequency (switch 1). leave this pin open when horizontal frequency is switched by bus controlling. controlling this pin prevails over bus control. (refer to table 1: bus control function.) when this ic is used for crt, connect this pin to def v cc (pin 19) or def gnd (pin 25). if it is not necessary to control this pin on crt, connect this pin directly to def vcc or def gnd on the pcb. def v cc or def gnd 14 sync in inputs y signal with sync signal via clamp capacitor. white 100%: 1 v p-p or 40 6 1 k ? 1 k ? 5 k ? 8 9 10 40 11 6 5 k ? 7 a 1.6 ma 40 12 6 1 k ? 200 ? 200 ? 54 1 k ? 19 13 25 1 k ? 50 a 50 k ? 30 k ? 19 14 25 1 k ? 1 k ? 60 k ? 1 k ?
TA1360ANG 2003-01-21 6 pin no. pin name function interface circuit input signal/output signal 15 vd in inputs vertical sync vd signal. inputs positive- or negative-polarity signals. or 16 hd in inputs horizontal sync hd signal. inputs positive- or negative-polarity signals. or 17 scp in inputs scp from up converter. input signals are clamp pulse (cp) and black peak detection stop pulse (bpp). 2.2 v to 2.8 v : bpp 4.2 v to 9 v : cp 18 cp out outputs internal clamp pulse (cp). 19 def/dac v cc v cc pin for def/dac block. see maximum ratings about the voltage. ? ? 20 afc filter connects filter for detecting afc. dc 21 hvco connects ceramic oscillator for horizontal oscillation. use murata csbla503keczf30. ? 19 15 25 1 k ? 45 k ? threshold : 0.75 v 0 v threshold : 0.75 v 0 v 19 16 25 1 k ? 50 k ? threshold : 0.75 v 0 v threshold : 0.75 v 0 v 5 v 0 v 19 21 25 2 k ? 10 k ? 1 k ? 1 k ? 19 18 25 2.5 k ? 200 ? 19 20 25 300 ? 30 k ? 7.5 k ? 6.3 v vco 19 17 25 5 k ? 50 k ?
TA1360ANG 2003-01-21 7 pin no. pin name function interface circuit input signal/output signal 22 h-freq sw2 switches horizontal frequency (switch 2). leave this pin open when horizontal frequency is switched by bus controlling. controlling this pin prevails over bus control. (refer to table 1: bus control function.) when this ic is used for crt, frequency of horizontal output (pin 26) is controlled according to voltage of this pin. dc voltage that is generated by dividing resistor of def v cc (pin 19) should be used to control this pin. at bus control (horizontal frequency) : output voltage value 28 k/15 khz : dc 9 v 31 khz : dc 6 v 33 khz : dc 3 v 37 k/45 khz : dc 0 v at pin 22 control, horizontal frequency and input voltage value 0 to 1.0 v : 37 k/45 khz 2.0 v to 4.0 v : 33 khz 5.0 v to 7.0 v : 31 khz 8.0 v to 9.0 v : 28 k/15 khz 23 h curve correction adjusts screen curve at high voltage fluctuation. input ac component of high voltage fluctuation. when not used, connect 0.01- f capacitor between this pin and gnd. dc 24 fbp in inputs fbp for horizontal afc. sets h-blk width. 25 def/dac gnd gnd pin for def/dac block ? ? 26 h-out horizontal output pin. open-collector output. 27 vp out outputs vertical pulse. applying current to this pin, performs external blanking by or-ing with internal blanking. note: changing h-position varies vp output width. use the start phase only for vp output. vp output: v-blk input current: 780 a to 1 ma 23 1 k ? 65 k ? 19 25 25 k ? 50 k ? 130 k ? 6.5 v 24 19 25 500 ? 20 k ? 5 v 2.25 v 30 k ? 19 26 25 5 k ? 19 25 27 200 ? 200 a 32 5 v 0 v start phase 19 25 22 1 k ? 30 k ? 1 k ? 20 pf 60 k ? 60 k ? 60 k ? 16 k ? 15 k ? 4.5 v 7.5 v 1.5 v max: 9 v h-afc threshold : 5.3 v blk threshold : 2.3 v
TA1360ANG 2003-01-21 8 pin no. pin name function interface circuit input signal/output signal 28 dac1 (sync out) outputs 1-bit dac or separated sync. open-collector output. dc or sync out 29 i 2 l v dd v dd pin for i 2 l block. connects 2 v (typ.). supply power via zener diode through resistor from pin 19. (see application circuit.) ? ? 30 scl scl pin for i 2 c bus ? 31 sda sda pin for i 2 c bus ? 32 i 2 l gnd gnd pin for i 2 l block ? ? 33 34 35 analog b in analog g in analog r in inputs analog r/g/b signal via clamp capacitor. 100 ire: 0.7 vp-p (not including sync) 36 dac2 (acb pulse) outputs 1-bit dac or pulse over acb period. open-collector output. dc or acb pulse 19 30 5 k ? 25 scl 2.25 v 32 19 31 32 5 k ? 25 sda 2.25 v 50 ? ack 40 36 44 500 ? 19 25 28 500 ? 32 40 44 1 k ? 33 34 35 1 k ? 1 k ?
TA1360ANG 2003-01-21 9 pin no. pin name function interface circuit input signal/output signal 37 38 39 analog osd b in analog osd g in analog osd r in inputs analog osd signal via clamp capacitor. 100 ire: 0.7 vp-p (not including sync) 40 rgb v cc v cc pin for text/rgb block. see maximum ratings about the supply voltage. ? ? 41 42 43 b out g out r out outputs r/g/b signal. recommended output amplitude: 100 ire = 2.3 vp-p 100 ire: 2.3 vp-p conditions: uni-color = max sub-cont = cent y in = 0.7 vp-p 44 rgb gnd gnd pin for text/rgb block �u ? ? 45 i k in inputs feedback signal from crt. (blk level should be 0 to 3 v.) when acb function is not used, connect this pin to rgb v cc pin. or rgb v cc 46 47 48 b s/h g s/h r s/h s/h (sample-and-hold) pin. in acb mode, connect 2.2- f capacitor. in cut-off mode, connect 0.01- f capacitor. dc 49 y s 3 (analog rgb) switches internal rgb and external analog rgb input. vsm output is muted when analog rgb is selected. 0 to 0.5 v : internal 1.5 v to 9 v : analog rgb, vsm mute 40 44 1 k ? 37 38 39 1 k ? 1 k ? 40 44 46 47 48 500 ? 1 k ? 5 k ? 3 pf 3 v 40 49 44 300 ? 300 ? 50 k ? 40 44 41 42 43 200 ? 100 ? 2.5 ma 40 45 44 1 k ? 1 vp-p (typ.) r g b 0 to 3 v
TA1360ANG 2003-01-21 10 pin no. pin name function interface circuit input signal/output signal 50 51 y s 2 (analog osd) y s 1 (analog osd) switches internal rgb and osd input signals. the blend ratio of internal rgb and osd signals can be adjusted according to applying voltage to pins y s 1 and y s 2. vsm output is muted when y s 1 or y s 2 pin is set to high. y s 2 y s 1 blend ratio int rgb: osd rgb l l 10:0 h l 7:3 l h 5:5 h h 0:10 0 to 0.5 v : internal 1.1 v to 1.7 v : vsm mute 2.9 v to 9 v : osd, vsm mute 52 y m /p-mute/blk high-speed halftone switch for internal rgb signal. enables picture mute and blanking. 0 to 0.5 v : internal 1.2 v to 1.8 v : half tone 2 v.7 to 4.0 v : p-mute 7 v to 9 v : blanking 53 abcl in inputs abl and acl signals. sets gain and start point of abl and dynamic abl signal according to bus controlling. dc 54 vsm out outputs y signal for vsm that passed through hpf circuit (first differential circuit). output signals are muted according to pins 49, 50, and 51. see pin 12. ? 55 y/c v cc v cc pin for y/c block. see maximum ratings about the supply voltage. ? ? 56 apl filter connects filter for correcting dc restoration rate. leaving this pin open enables to monitor y signal after black stretch and dynamic . ? 40 44 50 51 300 ? 50 k ? 40 52 44 300 ? 80 k ? 10 k ? 53 44 40 30 k ? 5 k ? 7.05 v 55 56 6 1 k ? 40 k ? 1 k ?
TA1360ANG 2003-01-21 11 bus control map write data slave address: 88h sub-add d7 d6 d5 d4 d3 d2 d1 d0 preset 00 h-freq1 h-duty yuv-sw dac1 dac2 sync-sw h-freq2 1000 0000 01 horizontal position clp-phs 1000 0000 02 acb-mode scp-sw hbp-phs1 sync sep-level test 1000 0000 03 v-blk phase vertical frequency 1000 0000 04 compression-blk phase-1 compression-blk phase-2 1000 0000 05 p-mode1 uni-color 1000 0000 06 brightness 1000 0000 07 osd-acl color 1000 0000 08 tint hbp-phs2 1000 0000 09 picture sharpness bls 1000 0000 0a rgb brightness dcrr-sw 1000 0000 0b hi brt rgb contrast 1000 0000 0c sub contrast wps yuv mode y-out 1000 0000 0d drive gain1 dr-r 1000 0000 0e drive gain2 dr-b/g 1000 0000 0f r cut off 1000 0000 10 g cut off 1000 0000 11 b cut off 1000 0000 12 r-y/b-y gain r-y/b-y phase 1000 0000 13 g-y/b-y gain g-y/b-y phase 1000 0000 14 color srt tran c freq green stretch color clt 1000 0000 15 c.d.e. y/c gain comp bl stretch gain flesh h-shift 1000 0000 16 vsm phase vsm gain apacon peak freq 1000 0000 17 dc rest point dc rest rate dc rest limit 1000 0000 18 black stretch point apl vs bsp b.l.c. b.d.l bs-area 1000 0000 19 srt-gain wpl-level 1000 0000 1a d-abl point d-abl gain bl stretch point p-mode2 1000 0000 1b abl point abl gain rgb out mode 1000 0000 1c dync gain bs-char1 static gain-1 static gain-2 1000 0000 1d osd bright osd contrast y/c-dl1 dync area 1000 0000 1e y detail control bs-char2 wp blue point 1000 0000 1f y group delay correction y/c-dl2 wp blue gain 1000 0000 read data slave address: 89h d7 d6 d5 d4 d3 d2 d1 d0 0 por ik-in rgb-out yuv-in h-out vp-out rgb-in sync-in
TA1360ANG 2003-01-21 12 bus control features write mode resister name description preset value h-freq1/2 switches horizontal oscillation frequency. (see the appendix 1) 33.75 khz h-duty switches horizontal output duty. 0: 41% 1: 47% 41% yuv-sw switches yuv input. 0: input-1 (y1/c b1 /c r1 ) 1: input-2 (y2/c b2 /c r2 ) input-1 dac 1 switches dac controlling output. 0: open (high) 1: on (low) controls 1-bit dac of open-collector when test is 00. outputs h/c-sync from pin 28 when test is 01. open dac 2 switches dac controlling output. 0: on (low), 1: open (high) controls 1-bit dac of open-collector when test is 00. outputs acb reference pulse from pin 36 when test is 01. on sync-sw switches sync input. 0: selects hd/vd input. 1: selects sync input. hd/vd horizontal position adjusts horizontal picture position (phase). 0000000: ? 12.5% 1111111: + 12.5% note: vp output width (pin 27) varies with a change of horizontal position. center clp-phs switches clamp pulse phase. 0: 0.7- s (2.5%) width, 1.1- s (3.8%) delay from hd stop phase. 1: 0.7- s (2.4%) width, 0.2- s (0.7%) delay from hd stop phase when no signal, 0.8- s (2.7%) width that is 1.2- s (4.2%) delay from fbp start phase. also switches cp phase of cp-out (pin 18). 1.1- s delay acb mode sets acb mode; sets converged reference level. 00: acb off (cutoff bus control), 01: acb on (5 ire), 10: acb on (10 ire) 11: acb on (20 ire) acb on (10 ire) scp-sw scp (sand castle pulse) switches modes. 0: internal mode 1: external input mode internal mode hbp-phs1/2 switches phase of black-stretch-detection stop pulse. hbp-phs1 = 0 and hbp-phs2 = 0: fbp 3% hbp-phs1 = 0 and hbp-phs2 = 1: fbp 8% hbp-phs1 = 1 and hbp-phs2 = 0: fbp 13% hbp-phs1 = 1 and hbp-phs2 = 1: fbp 18% leaving y open and setting the test circuit sw 2 to c enable to monitor h/v-bpp (black-stretch-detection stop pulse) width through pin 2. 3% sync sep-level switches sync sep-level. 00: 16% 01: 24% 10: 32% 11: 40% (at 1125i/60) 16% test test mode: controls 1-bit dac of open-collector when test is 00. outputs h/c-sync from pin 28, and acb reference pulse from pin 36 when test is 01. do not set test to 10/11 for that is shipment test mode. 00
TA1360ANG 2003-01-21 13 resister name description preset value v-blk phase switches vertical blk stop phase. 00000: 16 h~ 11110: 46 h (1 h/step) 11111: internal h/v-blk off please set acb mode to off when internal h/v-blk is off (11111). 32 h v-frequency vertical free-run frequency: sets v pull-in range. (see appendix 2.) 1281 h compression-blk phase-1/2 compression blk phase: sets blk for upper and lower parts of screen. (see appendix 3.) center, off p-mode1/2 picture mode: sets picture mute, halftone, blue background, and y mute. (see appendix 4.) p-mute 1 uni-color unicolor adjustment: 0000000: ? 16db~ 1111111: 0db min brightness brightness adjustment: 00000000: ? 40 ire 11111111: + 40 ire center osd-acl osd-acl; 0: off 1: on on color color adjustment: 0000000: color mute, 0000001: ? 20db or more 1111111: + 4db c-mute tint tint adjustment: 0000000: ? 32 deg~ 1111111: + 32 deg 0 deg picture-sharpness sharpness adjustment: 0000000: ? 10db or more 1000000: + 10db 1111111: + 17.5db (at peak freq) center bls blue stretch correction: b-axis correction 0: off 1: on off rgb-brightness rgb brightness: 0000000; ? 20 ire~ 1111111; + 20 ire center dcrr-sw switches dc restoration rate. 0: 100% or higher 1: 100%or lower 100% or higher hi brt high-bright color: 0: off 1: on on rgb-contrast rgb contrast: 0000000: ? 16.5db 1111111: 0db min sub-contrast sub-contrast: 00000: ? 3.3db 11111: + 2.5db center wps wps level: 0: 110 ire 1: 130 ire 110 ire yuv mode y/color-difference input mode: 0: y/cb/cr, 1: y/pb/pr (remarks) y/cb/cr: itu-r bt 601 y/pb/pr: itu-r bt 709 (1125/60/2:1) y/cb/cr y-out �. -out gamma control: 0: off 1: on off drive gain1/2 drive gain 1/2; 0000000: ? 5db 1111111: + 3db center dr-r dr-b/g switches rgb drive gain base. (see appendix 5.) r
TA1360ANG 2003-01-21 14 resister name description preset value r/g/b cut off r/g/b cutoff: 1) at acb-off rgb-out 00000000: 1.9 v 11111111: 2.9 v 2) at acb-on sens-in 00000000: 0.5 vp-p 11111111: 1.5 vp-p center r-y/b-y gain switches r-y/b-y relative amplitude: 0000: min (0.45) 1111: max (0.9) center r-y/b-y phase switches r-y/b-y relative phase: 0000: min (90 deg) 1111: max (111.5 deg) min g-y/b-y gain switches g-y/b-y relative amplitude: 0000: min (0.25) 1111: max (0.48) center g-y/b-y phase switches g-y/b-y relative phase: 0000: min (232 deg) 1111: max (254 deg) min color srt tran color srt transient: color-difference transient improvement 00: c-srt off~ 11: max center c freq color srt peak frequency: 0: 4.5 mhz 1: 5.8 mhz 4.5 mhz green stretch green stretch: 00: off~ 11: max ( + 3db) off color color correction point 00: off, 01: 0.23 vp-p, 10: 0.40 vp-p, 11: 0.58 vp-p off clt color limiter level: 0: 1.65 vp-p, 1: 2 vp-p 1.65 vp-p cde color detail enhancer: 00: min 11: max center y/c gain comp dynamic y/c compensation: operated when luminance level is made up according to dynamic y . 00: off~ 11: max off bl stretch gain blue stretch gain: b-axis correction 00: off 11: max ( + 6.4db) off flesh flesh color: skin tone correction 0: off 1: on (lead-in angle: 33.7 deg) off h-shift shifts a center of horizontal picture position (phase): 0: off 1: on � fbp shifts 6.7% against hd � off vsm-phase vsm phase: 000: ? 37.5 ns 101: normal 111: + 15 ns center vsm gain vsm gain: 000: off 001: 0 db~ 111: + 16db (vsm gain is limitted 1.4 vp-p) off apacon peak f 0 apacon peak frequency: 00: 13.5 mhz 01: 9.5 mhz 10: 7.2 mhz 11: 4.5 mhz 13.5 mhz dc rest point dc restoration rate correction point: 000: 0% 111: 49% center dc rest rate dc restoration correction rate: 000: 100% 111: 135% (70%) min dc rest limit dc restoration rate correction limit point: 00: 67% 01: 77 �? 10: 80% 11: 80% min
TA1360ANG 2003-01-21 15 resister name description preset value black stretch point black stretch start point 1: 000: off 001: 25 ire~ 111: 55 ire center apl vs bsp black stretch start point 2: 00: 0 ire 11: 46 ire up (at apl 100%) 0 ire b.l.c black level automatic correction: up to 6.5 ire. (black stretch takes priority.) 0: off 1: on off b.d.l. switches black detection level: 0: 3 ire 1: 0 ire 3 ire bs-area black stretch area reinforcement: 0: on 1: off on srt-gain srt gain; y transient improvement (lti) 00000: min 11111: max center wpl-level white letters improvement amplitude; 000: min (21 ire) ~ 110: max (102 ire) 111: off min d-abl point dynamic abl detection voltage 00: min 11: max center d-abl gain dynamic abl sensitivity 00: min 11: max min bl stretch point blue stretch point; b-axis correction 00: min (28 ire) 11: max (60 ire) min abl point abl detection voltage 000: min 111: max center abl gain abl sensitivity 000: min 111: max min rgb-out mode rgb output mode; rgb output mode sw for test and adjustment 00: normal 01: r only 10: g only 11: b only normal dync gain dynamic y gain vs dark area; dynamic -correction according to dark area. 00:min~ 11: max (maximum gain is + 6db included static y gain for dark area.) center bs-char1/2 black stretch characteristic swich bs-char1 = 0 and bs-char2 = 0: off bs-char1 = 0 and bs-char2 = 1: min bs-char1 = 1 and bs-char2 = 0: mid bs-char1 = 1 and bs-char2 = 1: max off static gain-1 static y dark area gain; correction for dark area 000: off 001: min ( ? 5db) ~ 11: max ( + 2.4db) note: when static gain-1 is 000(off), set dync gain to min (00), static gain-2 to off (11), and dync area to min (000). off static gain-2 static y light area gain; correction for light area 00: max ( ? 8.8db)~ 11: off when 00~10 is set, light area static y and light dynamic y according to light area is operated. max osd bright osd brightness: 00: 5 ire 01: 0 ire 10: ? 5 ire 11: ? 10 ire ? 5 ire osd-contrast osd contrast: 00: min (1.7db) 11: max (0db) min
TA1360ANG 2003-01-21 16 resister name description preset value y/c dl1/2 adjusts y/c phase; adjusts the phase y before passing through matrix circuit. y/c dl2 = 0 and y/c dl1 = 0: ? 10 ns, y/c dl2 = 0 and y/c dl1 = 1: ? 5 ns y/c dl2 = 1 and y/c dl1 = 0: 0 ns, y/c dl2 = 1 and y/c dl1 = 1: + 5 ns ? 10 ns dync area dynamic dark area detection sensitivity; switches detection sensitivity of dynamic y of dark area. 000: min~ 111: max min y detail control controls y detail; corrects sharpness of 5.0-mhz peak frequency. 0000:min (trap) 1111: max � + 6db � center wp blue point white peak blue point; 000: off 001: min (42 ire) ~ 111: max (106 ire) off y-group delay correction y group delay correction; shoot balance correction. 0000: pre-shoot gain is lowered. (overshoot gain is raised.) 1111: overshoot gain is lowered. (pre-shoot gain is raised.) center wp blue gain white peak blue gain. 000: min ( + 3db) 111: max ( + 10db) min
TA1360ANG 2003-01-21 17 appendix 1: horizontal frequency pin voltages (v) bus data pin 13 pin 22 00-d0 00-d7 00-d6 h-frequency (khz) def v cc (8.0~9.0) 0 0 0 28.125 6.0 (5.0~7.0) 0 0 1 31.5 3.0 (2.0~4.0) 0 1 0 33.75 def gnd (0~1.0) def gnd (0~1.0) 0 1 1 37.9 def v cc (8.0~9.0) 1 0 0 15.75 6.0 (5.0~7.0) 1 0 1 31.5 3.0 (2.0~4.0) 1 1 0 33.75 def v cc (8.0~9.0) def gnd (0~1.0) 1 1 1 45 note 1: controlling pins prevails over bus control. when the ta1360n is used for crt, control horizontal oscillation frequency by pins 13 and 22. (see the pin descriptions for details.) note 2: horizontal output frequency may not be switched at once but may takes two steps if switching pins 13 and 22 is controlled at the same time. switching horizontal output frequency may cause deterioration of the horizontal transistor. thus, be sure to take account of applications, included software. appendix 2; vertical frequency v-bpp data v pull-in range start phase stop phase example of format/v (h)-frequency 000 48~1281 h 1100 h 1125p/30 hz (33.75 khz) 001 48~849 h 730 h 750p/60 hz (45 khz) (750p/50hz(37.5 khz)) 010 48~725 h 600 h 625p/50 hz (31.5 khz) svga/60 hz(37.9 khz) 011 48~660 h 545 h 1125i/50 hz (28.125 khz) 1125i/60 hz (33.75 khz) 100 48~613 h 500 h 525p/60 hz (31.5 khz) 101 48~363 h 290 h pal/secam/50 hz (15.625 khz), 100 hz (31.5 khz) 110 48~307 h 240 h v-blk p. (c.blk p.) + 20 h ntsc/60 hz (15.734 khz), 120 hz (31.5 khz) 111 vp-out hi ? ? ?
TA1360ANG 2003-01-21 18 appendix 3; compression-blk phase v-frequency phase-1 (start phase) * phase-2 (stop phase) 000 1088 h~1116 h 001 720 h~748 h 010 592 h~620 h 011 528 h~556 h 100 488 h~516 h 101 280 h~308 h 110 224 h~252 h 50~78 h (0000: c-blk2 off) 111 c-blk off * : c-blk1 = 1111: c-blk1 off appendix 4; p-mode 05-d7 1a-d1 1a-d0 mode description 0 0 0 normal 1 p-mute and halftone the main signal by pin y m . insert analog rgb-in by ys3, and osd-in by ys1/ys2. analog rgb-in > p-mute 0 0 1 y-mute full-screen-mute process is executed on y of main signal by bus. insert analog rgb-in by ys3, and osd-in by ys1/ys2. analog rgb-in > p-mute 0 1 0 y m 1 full-screen-halftone process is executed on main signal by bus. insert p-mute by pin y m , and analog rgb-in by ys3. ys1/ys2 blends osd-in and main halftone signal. analog rgb-in > p-mute 0 1 1 bb blue background process is executed on main signal by bus. insert p-mute by pin y m , analog rgb-in by ys3, and osd-in by ys1/ys2 analog rgb-in > p-mute 1 0 0 p-mute 1 full-screen-mute process is executed on main signal by bus. insert analog rgb-in by ys3, and osd-in by ys1/ys2. analog rgb-in > p-mute 1 0 1 y m 2 full-screen-halftone process is executed on main signal by bus. insert p-mute by pin y m , and analog rgb-in by ys3. ys1/ys2 blends osd-in and main halftone signal p-mute > analog rgb-in 1 1 0 p-mute 2 full-screen-mute process is executed on main signal and analog rgb-in by bus. insert osd-in by ys1/ys2. p-mute > analog rgb-in 1 1 1 normal 2 p-mute and halftone process is executed on the main signal by pin y m . analog rgb-in is inserted by ys3, and osd-in by ys1/ys2. p-mute > analog rgb-in output priority; (000)~(100): main signal < bb < p-mute < rgb-in < osd-in (101)~(111): main signal < bb < rgb-in < p-mute < osd-in
TA1360ANG 2003-01-21 19 appendix 5; dr-r, dr-b/g dr-r dr-b/g reference axis drive gain1 drive gain2 0 0 r g b 0 1 r g b 1 0 g r b 1 1 b g r read function signal function por power-on reset: 0: resister preset 1: normal after power on, 0 is returned at first read; 1, at second and subsequent reads. ik-in detects ik input; detects input through pin 45. 0: ng (no signal) 1: ok (signal detected) rgb-out detects rgb-out self-check; detects output of pins 41, 42, 43. 0: ng (no signal) 1: ok (signal detected) detects signal when all three outputs hsve signals. small signals are not detected. yuv-in detects yuv-in self-check; detects input of pins 3, 4, 5 or pins 8, 9, 10. 0: ng (no signal) 1: ok (signal detected) detects signal when all three inputs are ac signals. small signals or signals like dc voltage are not detected. h-out detects h-out self-check; detects output of pin 26. 0: ng (no signal) 1: ok (signal detected) vp-out detects vp-out self-check; detects output of pin 27. 0: ng (no signal) 1: ok (signal detected) rgb-in detects rgb-in self-check; detects input of pins 33, 34, 35. 0: ng (no signal) 1: ok (signal detected) detects signal when all three inputs are ac signals. small signals or signals like dc voltage are not detected. sync-in detects sync-in self-check; detects input of pin 14. 0: ng (no signal), 1: ok (signal detected)
TA1360ANG 2003-01-21 20 how to transmit/receive via i 2 c bus slave address: 88h a6 a5 a4 a3 a2 a1 a0 w/r 1 0 0 0 1 0 0 0/1 start and stop conditions bit transfer acknowledgement sda scl s start condition p stop condition sda scl sda must not be changed sda may be changed sda from transmitter low impedance only at bit 9 clock pulse for acknowledgement s high impedance at bit 9 1 8 9 sda from receiver scl from master
TA1360ANG 2003-01-21 21 data transmit format 1 data transmit format 2 data receive format to receive data, the master transmitter changes to the receiver immediately after the first acknowledgement. the slave receiver changes to the transmitter. the stop condition is always created by the master. details are provided in the philips i 2 c specifications. optional data transmit format in this way, sub addresses are automatically incremented from the specified sub address and data are set. purchase of toshiba i 2 c components conveys a license under the philips i 2 c patent rights to use these components in an i 2 c system, provided that the system conforms to the i 2 c standard specification as defined by philips. s slave address 0 a transmit data 1 a sub address a transmit data n a sub address a p �k�k�k�k�k�k �? �k�k�k�k�k�k s slave address 1 a receive data 2 a transmit data 1 a p 7 bit msb 8 bit msb s slave address a transmit data n �k�k�k�k transmit data 1 a p 7 bit msb 8 bit msb 0 sub address 7 bit msb a 1 8 bit msb s slave address 0 a transmit data a sub address a p 7 bit msb s: start condition 8 bit msb a: acknowledgement 9 bit msb p: stop condition
TA1360ANG 2003-01-21 22 maximum ratings (ta = = = = 25c) rating characteristics symbol pcb a pcb b pcb c unit supply voltage v ccmax 12 12 12 v input pin signal voltage e inmax 9 9 9 vp-p power dissipation p d (note 3) 2551 2717 3378 mw power dissipation reduction rate depending on temperature 1/ ja 20.4 21.7 27.0 mw/ c operating temperature t opr ? 20 to 65 ? 20 to 65 ? 20 to 65 c storage temperature t stg ? 55 to 150 ? 55 to 150 ? 55 to 150 c min 8.5 8.7 8.7 typ. 8.8 9.0 9.0 supply voltage (pins 19, 40, and 55) max 9.1 9.3 9.3 v note 3: see the following figure a. note, however, that the conditions apply only to the case where the device is mounted on board a (180 mm 125 mm 1.6 mm, one-sided); board b (329 mm 249 mm 1.6 mm, two-sided); or board c (276 mm 192 mm 1.6 mm, six-layered). when mounting the ic, select boards no smaller than these. when using under the conditions of board a, set the ic?s power supply voltage (pins 19, 40, 55) to 8.8 v ( 0.3 v). because the ic?s thermal capacity margin is narrow, when designing a set, incorporate heat discharge features into the design. note that the power dissipation varies widely depending on the board mounting conditions. figure a power dissipation reduction curve ambient temperature ta (c) power dissipation p d (mw) 2717 0 150 25 65 1848 0 2297 3378 printed circuit board b printed circuit board a 2551 1735 printed circuit board c
TA1360ANG 2003-01-21 23 note 4: power supply sequence at power-on, power should be supplied to the power supply pins according to the following sequence: 1. pin 29 (i 2 l vdd) 2. pin 19 (def/dac v cc ) 3. pins 40 and 55 (rgb v cc /yc v cc ) supply power to pin 29 via zener diode through resistor from pin 19. (see ?application circuit?.) bus preset value is become undefined and caused malfunction of the ic unless supplying power to all supply pins or follow the power supply sequence described above. when the frequency of horizontal output (pin 26) became undefined, horizontal transistor may be damaged. when the ta1360n is used for crt, control horizontal oscillation frequency by pins 13 and 22. figure b timing chart that indicates the timing from power-on till horizontal output. (at ta = = = = 25 c ) t i 2 l v dd logic operation 1.3 v (typ.) por release voltage (bus operation) 4.6 v (typ.) horizontal output 6.0 v (typ.) v def/dac v cc
TA1360ANG 2003-01-21 24 operating conditions characteristics description min typ. max unit board a (note 5) 8.5 8.8 9.1 pins 19, 40, 55 boards b and c (note 5) 8.7 9.0 9.3 supply voltage (v cc ) pin 29 1.8 2.0 2.2 v y input level pins 3, 8: 100% color bar, including sync (picture period amplitude, 0.7 vp-p) ? 1.0 ? color-difference input level pins 4, 5 9, 10: 100% color bar, not including sync ? 0.7 ? vp-p hd/vd input level pins 15, 16 2.0 5.0 v cc v sync input level pin 14: 100% color bar, including sync 0.9 1.0 1.1 vp-p cp 4.2 5.0 v cc scp input level pin 17 bpp 2.2 2.5 2.8 at 28 k/31 k/33 k/37 khz 0 0 1.0 pin 13 at 15 k/31 k/33 k/45 khz 8.0 v cc v cc 28.125 khz or 15.75 khz 8.0 v cc v cc 31.5 khz 5.0 6.0 7.0 33.75 khz 2.0 3.0 4.0 horizontal frequency switching voltage pin 22 37.9 khz or 45 khz 0 0 1.0 h-afc 6.5 7.0 v cc fbp input level pin 24 h-blk 3.0 3.5 4.0 v fbp input width pin 24 0.16 ? 0.3 h h-out input current pin 26 ? 9.0 15.0 dac input current pins 28, 36 ? 0.3 1.0 ma scl/sda pull-up voltage pins 30, 31 3.3 5.0 v cc v sda input current pin 31 ? ? 2 ma analog rgb input level pins 33, 34, 35: white 100% ? 0.7 ? analog osd input level pins 37, 38, 39: white 100% ? 0.7 ? vp-p y s 3 switching voltage pin 49 1.5 5.0 v cc osd 2.9 5.0 v cc y s 1/2 switching voltage pins 51, 50 vsm mute 1.1 1.5 1.7 blk 7.0 v cc v cc p-mute 2.7 3.5 4.0 y m switching voltage pin 52 half tone 1.2 1.5 1.8 v external v-blk input current pin 27 0.78 ? 1 ma note 5: see ?maximum ratings? about the boards a, b, and c. electrical characteristics ( unless otherwise specified, v cc = = = = 9 v/2 v, ta = = = = 25c) current dissipation pin name symbol test circuit min typ. max unit def/dac v cc (9 v) i cc1 ? 19.2 24.0 28.2 rgb v cc (9 v) i cc2 ? 48.8 61.0 67.8 i 2 l v dd (2 v) i cc3 ? 21.3 25.0 29.4 y/c v cc (9 v) i cc4 ? 36.8 46.0 51.1 ma
TA1360ANG 2003-01-21 25 pin voltage test condition (1) bus = preset (2) sw1 = b, sw2 = b, sw3 = c, sw4 = b, sw5 = b, sw7 = b, sw8~10 = b, sw14 = b, sw20 = on, sw23 = b, sw24 = a, sw26 = a, sw33~35 = a, sw37 to 39 = a, sw54 = off, sw56 = on pin no. pin name symbol test circuit min typ. max unit 1 dark area det filter v 1 ? ? 0.09 0.15 2 bph filter v 2 ? 5.5 5.8 6.1 3 y1 in v 3 ? 4.7 5.0 5.3 4 cb/pb1 in v 4 ? 4.7 5.0 5.3 5 cr/pr1 in v 5 ? 4.7 5.0 5.3 7 light area det filter v 7 ? ? 0.09 0.15 8 y2 in v 8 ? 4.7 5.0 5.3 9 cb/pb2 in v 9 ? 4.7 5.0 5.3 10 cr/pr2 in v 10 ? 4.7 5.0 5.3 11 color limiter v 11 ? 6.65 6.9 7.15 12 vsm filter v 12 ? 7.5 7.7 7.9 14 sync in v 14 ? 1.8 2.1 2.4 15 vd in v 15 ? ? 0 0.3 16 hd in v 16 ? ? 0 0.3 17 cp in v 17 ? ? 0 0.3 20 afc filter v 20 ? 5.4 6.2 7.0 21 hvco v 21 ? 4.4 5.0 5.6 23 h curve correction v 23 ? 2.2 2.5 2.8 33 analog b in v 33 ? 3.65 3.95 4.25 34 analog g in v 34 ? 3.65 3.95 4.25 35 analog r in v 35 ? 3.65 3.95 4.25 37 analog osd b in v 37 ? 3.65 3.95 4.25 38 analog osd g in v 38 ? 3.65 3.95 4.25 39 analog osd r in v 39 ? 3.65 3.95 4.25 46 b s/h v 46 ? 4.2 5.2 6.2 47 g s/h v 47 ? 4.2 5.2 6.2 48 r s/h v 48 ? 4.2 5.2 6.2 49 y s 3 v 49 ? ? 0.1 0.2 50 y s 2 v 50 ? ? 0.1 0.2 51 y s 1 v 51 ? ? 0.1 0.2 52 y m v 52 ? ? 0.1 0.2 53 abcl in v 53 ? 6.1 6.35 6.6 54 vsm out v 54 ? 4.1 4.3 4.5 56 apl filter v 56 ? 4.8 5.0 5.2 v
TA1360ANG 2003-01-21 26 picture quality (sharpness) block characteristics symbol test circuit test condition min typ. max unit y input dynamic range d ry ? ? 0.7 1.0 1.5 vp-p v b ? ? 15 10 15 black detection level shift v b3 ? (note p01) 35 45 55 mv black stretch amp maximum gain g bs ? (note p02) 2.4 2.8 3.2 db p bst1 ? 20 25 35 black stretch start point 1 p bst2 ? (note p03) 50 55 60 ire p bs1 ? 0 5 10 black stretch start point 2 p bs2 ? (note p04) 14 21 30 ire p bsc1 ? 26 28 30 p bsc2 ? ? 8 ? 6 ? 4 p bsc3 ? 26 28 30 p bsc4 ? ? 5.5 ? 3 ? 1 p bsc5 ? 26 28 30 black stretch characteristic switch p bsc6 ? (note p05) ? 3.5 ? 2 ? 0.5 ire black stretch area reinforcement current ibsa ? (note p06) 13 18 23 a dv 01 ? 80 120 160 dv 10 ? 240 280 320 d.abl detection voltage dv 11 ? (note p07) 380 420 460 mv s damin ? ? 0.01 0.02 d.abl sensitivity s damax ? (note p08) 0.25 0.28 0.31 v/v black level correction blc ? (note p09) 4.5 6.5 8.5 ire dark area y correction point p dgp ? (note p10) 25 28 33 ire dark area dynamic y gain g ddgmax ? (note p11) 5.5 6 6.5 db g dsgmin ? ? 6.5 ? 5 ? 4 dark area static y gain g dsgmax ? (note p12) 2 2.4 2.6 db light area y correction point lpg ? (note p13) 64 74 80 ire light area dynamic y gain gldg ? (note p14) 1.1 1.7 2.3 db g lsgmin ? 0.3 0.6 0.9 light area static y gain g lsgmax ? (note p15) 1.4 1.7 2.3 db damin ? 0.25 0.3 0.37 dacen ? 0.88 0.98 1.08 dark area detection sensitivity damax ? (note p16) 0.95 1.05 1.15 v adt 100 ? 0.9 1.1 1.2 adt 135 ? 1.2 1.35 1.5 dc restoration rate adt 65 ? (note p17) 0.55 0.70 0.85 times v dt0 ? ? 5 0 5 dc restoration point v dt1 ? (note p18) 47 49 55 % p dtl60 ? 64 67 70 p dtl75 ? 74 77 80 p dtl87 ? 74 80 82 dc restoration limit p dtl100 ? (note p19) 74 80 82 %
TA1360ANG 2003-01-21 27 characteristics symbol test circuit test condition min typ. max unit f ap00 ? 10.5 13.5 17 f ap01 ? 7 9.5 12 f ap10 ? 5 7.2 7.8 sharpness control peak frequency f ap11 ? ? 3.5 4.5 6.3 mhz dc fluctuation at switching sharpness control peak frequency vrdc ? (note p20) ? 0.01 0.02 v g max00 ? 15 17.5 19 g min00 ? ? 4 ? 0.6 2.5 g max01 ? 15 17.5 19 g min01 ? ? 5 ? 0.3 2.5 g max10 ? 15 17.5 19 g min10 ? ? 7 ? 2.5 1.5 g max11 ? 15 17.5 19 sharpness control range g min11 ? (note p21) ? 12 ? 5 0 db g cen00 ? 7 10 13 g cen01 ? 7 10 13 g cen10 ? 7 10 13 sharpness control center characteristic g cen11 ? (note p22) 7 10 13 db t srt00 ? 0.9 1.6 2.7 t srt01 ? 3.5 4.8 7.1 t srt10 ? 6.7 8.5 11.3 2t pulse response srt control t srt11 ? (note p23) 11.5 12.5 15.5 db vsm peak frequency f vsm ? ? 19 19.5 25.5 mhz g v000 ? ? ? 40 ? 35 g v001 ? ? 2 ? 1.2 ? 0.4 g v010 ? 3.7 4.6 5.5 g v011 ? 7.1 8.2 9.3 g v100 ? 8.9 10.5 12.1 g v101 ? 11.4 12.6 13.8 g v110 ? 13.5 14.4 15.3 vsm gain g v111 ? (note p24) 14.8 15.7 16.6 db v sr49 ? 0.62 0.78 0.85 v sr50 ? 0.62 0.78 0.85 vsm mute threshold voltage v sr51 ? pins 49, 50, 51 0.62 0.78 0.85 v v lu ? 0.55 0.66 0.75 vsm limit v ld ? (note p25) 0.55 0.66 0.75 vp-p y input to r output delay time t yr ? ? 110 125 145 ns ydla ? 3 5 10 ydlb ? 7 10 15 y delay time switch ydlc ? (note p26) 10 15 25 ns g amin ? ? 4 ? 2.5 ? 1 g bmin ? 2.5 3 3.5 g amax ? 1 1.7 2.4 y group delay correction g bmax ? (note p27) ? 5 ? 4 ? 2 db
TA1360ANG 2003-01-21 28 characteristics symbol test circuit test condition min typ. max unit g cde00 ? 9 10 11 g cde01 ? 9 10 11 g cde10 ? 9 10 11 color detail enhancer g cde11 ? (note p28) 9 10 11 db y detail frequency f yd ? ? 4 5 6 mhz g ydmax ? 11 13 15 g ydcen ? 8 10 12 y detail control range g ydmin ? (note p29) 3 5 7 db
TA1360ANG 2003-01-21 29 color difference block 1: yuv input and matrix characteristics symbol test circuit test condition min typ. max unit d rb ? 0.7 0.9 1.0 color difference input dynamic range d rr ? ? �? 0.7 0.9 1.0 vp-p t rmax ? 25 29 33 t rmin ? ? 37 ? 33 ? 29 t bmax ? 27 31 35 color difference tint control characteristic t bmin ? ? �? ? 36 ? 32 ? 28 �? f b00 ? 3.6 4.5 5.4 f b01 ? 4.6 5.8 7.0 f r00 ? 3.6 4.5 5.4 color srt peak frequency f r01 ? ? �? 4.6 5.8 7.0 mhz gs b00cen ? 1.5 2.8 4.1 gs b00max ? 2.9 4.2 5.5 gs b01cen ? 2.0 3.3 4.6 gs b01max ? 3.5 4.8 6.1 gs r00cen ? 3.4 4.7 6.0 gs r00max ? 5.4 6.7 7.0 gs r01cen ? 3.1 4.4 5.7 color srt gain gs r01max ? (note s01) �? 5.2 6.5 7.8 db cb1 input to b output delay time t b ? ? �? 130 155 185 ns cr1 input to r output delay time t r ? ? �? 130 155 185 ns gc bdy1 �? ? �? 1.8 2.25 2.7 gc bdy2 �? ? ? 1.65 ? 1.2 ? 0.75 gc rdy1 �? ? 1.8 2.25 2.7 dynamic y/c compensation �? gc rdy2 �? ? (note s02) �? ? 1.65 ? 1.2 ? 0.75 db �? g y00 ? 2.4 3.4 4.4 g y01 ? 2.4 3.4 4.4 g cbb ? 9.5 11.0 12.5 g pbb ? 9.9 11.4 12.9 g pbr ? ? 18.0 ? 16.0 ? 14.0 g crr ? 9.5 11.0 12.5 g prb ? ? 15.0 ? 13.5 ? 12.0 yuv gain �? g prr ? (note s03) �? 10.0 11.5 13.0 db �?
TA1360ANG 2003-01-21 30 characteristics symbol test circuit test condition min typ. max unit gra01 ? 0.98 1 1.02 gra10 ? 0.95 1 1.05 gra11 ? 0.93 1 1.07 grb01 ? 1.01 1.05 1.10 grb10 ? 1.05 1.1 1.15 grb11 ? 1.12 1.19 1.26 grc01 ? 1.10 1.14 1.18 grc10 ? 1.23 1.27 1.31 grc11 ? 1.35 1.42 1.49 grd01 ? 1.09 1.13 1.17 grd10 ? 1.21 1.25 1.29 grd11 ? 1.32 1.39 1.46 gre01 ? 0.98 1 1.02 gre10 ? 0.95 1 1.05 green stretch gre11 ? (note s04) �? 0.93 1 1.07 times
TA1360ANG 2003-01-21 31 color difference block 2 characteristics symbol test circuit test condition min typ. max unit color difference contrast adjustment characteristic ? v ucy ? (note a01) �? 14.5 16.0 17.5 db ? v ccy + ? 3.0 4.0 5.0 color adjustment characteristic ? vccy ? ? (note a02) �? ? 35 ? 22 ? 17 db �? rmax ? 109 111.5 114 rcnt ? 98.5 101 103.5 rmin ? 88 90 92 �? v r /v bmax ? 0.86 0.90 0.94 v r /v bcnt ? 0.65 0.69 0.73 r-y relative phase and amplitude v r /v bmin ? ? �? 0.42 0.45 0.49 times gmax ? 251 254 257 gcnt ? 244 247 250 gmin ? 229 232 235 �? v g /v bmax ? 0.43 0.48 0.53 v g /v bcnt ? 0.33 0.37 0.41 g-y relative phase and amplitude v g /v bmin ? ? �? 0.22 0.25 0.28 times �? ght ry ? 0.47 0.50 0.53 ght gy ? 0.47 0.50 0.53 color difference halftone characteristic ght by ? (note a03) �? 0.47 0.50 0.53 times �? v 1 ? 0.09 0.23 0.37 v 2 ? 0.26 0.40 0.54 v 3 ? 0.44 0.58 0.72 vp-p �? color characteristic ? ? (note a04) �? 0.60 0.70 0.80 ? �? clt 0 ? 1.45 1.65 1.85 color limiter characteristic clt 1 ? (note a05) �? 1.80 2.00 2.20 vp-p �? high-bright color gain hbc 1 ? (note a06) �? 0.02 0.04 0.06 times �?
TA1360ANG 2003-01-21 32 text block characteristics symbol test circuit test condition min typ. max unit g r �? ? �? 3.08 3.45 3.90 g g �? ? 3.08 3.45 3.90 ac gain (y1in~r/g/b out) �? g b �? ? (note t01) �? 3.08 3.45 3.90 times �? g g/r �? ? 0.94 �? 1.00 �? 1.06 �? ac gain axis difference �? g b/r �? ? ? �? 0.94 �? 1.00 �? 1.06 �? �? g fr �? ? 30 60 ? g fg �? ? 30 60 ? frequency characteristic (y1in~r/g/b out) �? g fb �? ? at ? 3db, sharpness characteristic is flat �? 30 60 ? mhz g fcb �? ? 10 12.5 ? frequency characteristic (cb1/cr1in~r/g/b out) g fcr �? ? ? 10 12.5 ? mhz unicolor adjustment characteristic �? ? v u �? ? (note t02) �? 15.0 �? 16.0 �? 17.0 �? db �? v brmax �? ? 4.10 4.45 4.80 v brcnt �? ? 3.05 3.40 3.75 brightness adjustment characteristic �? v brmin �? ? (note t03) �? 1.95 2.30 2.65 v �? v wps1 �? ? 2.20 2.32 2.44 white peak slice level �? v wps2 �? ? (note t04) �? 2.59 2.74 2.89 vp-p �? black peak slice level �? v bps �? ? (note t05) �? 1.15 1.35 1.45 v �? n 41 �? ? ? �? ? 52 �? ? 46 �? n 42 ? ? ? 52 �? ? 46 �? rgb output s/n �? n 43 �? ? (note t06) �? ? �? ? 52 �? ? 46 �? db �? g ht1 �? ? 0.45 �? 0.50 �? 0.55 �? halftone characteristic �? g ht2 �? ? (note t07) �? 0.45 �? 0.50 �? 0.55 �? times �? halftone on voltage �? v ht �? ? pin 52 0.65 �? 0.85 �? 1.05 �? v �? v vr �? ? 0.30 �? 0.80 �? 1.30 �? v vg �? ? 0.30 �? 0.80 �? 1.30 �? v-blk pulse output level �? v vb �? ? ? 0.30 �? 0.80 �? 1.30 �? v �? v hr �? ? 0.30 �? 0.80 �? 1.30 �? v hg �? ? 0.30 �? 0.80 �? 1.30 �? h-blk pulse output level �? v hb �? ? ? 0.30 �? 0.80 �? 1.30 �? v �? td on �? ? ? �? 0.00 �? 0.30 �? blk pulse delay time �? td off �? ? (note t08) �? ? �? 0.08 �? 0.30 �? s �? ? v su + �? ? 1.95 �? 2.45 �? 2.95 �? sub-contrast variable range �? ? vsu ? �? ? ? ? 3.8 �? ? 3.3 �? ? 2.8 �? db �? cut + �? ? 0.42 �? 0.47 �? 0.52 �? cut-off voltage variable range �? cut ? �? ? �? ? 0.42 �? 0.47 �? 0.52 �? v ? v #41 ? 2.05 2.30 2.55 ? v #42 ? 2.05 2.30 2.55 rgb output voltage ? v #43 ? ? �? 2.05 2.30 2.55 v rgb output voltage 3-axis difference ? v out ? ? �? ? 0 150 mv
TA1360ANG 2003-01-21 33 characteristics symbol test circuit test condition min typ. max unit dr r1 + �? ? 2.5 �? 3.0 �? 3.5 �? dr r1 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr r2 + �? ? 2.5 �? 3.0 �? 3.5 �? dr r2 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr g1 + �? ? 2.5 �? 3.0 �? 3.5 �? dr g1 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr g2 + �? ? 2.5 �? 3.0 �? 3.5 �? dr g2 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr g3 + �? ? 2.5 �? 3.0 �? 3.5 �? dr g3 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr b1 + �? ? 2.5 �? 3.0 �? 3.5 �? dr b1 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr b2 + �? ? 2.5 �? 3.0 �? 3.5 �? dr b2 ? �? ? ? 5.5 �? ? 5.0 �? ? 4.5 �? dr b3 + �? ? 2.5 �? 3.0 �? 3.5 �? drive adjustment variable range �? dr b3 ? �? ? (note t09) �? ? 5.5 �? ? 5.0 �? ? 4.5 �? db �? mu rd �? ? 1.7 �? 1.85 �? 2.0 �? mu gd �? ? 1.7 �? 1.85 �? 2.0 �? output voltage at p-mute �? mu bd �? ? ? 1.7 �? 1.85 �? 2.0 �? v �? p-mute on voltage �? v mute �? ? pin 52 �? 1.90 �? 2.15 �? 2.40 �? v �? bb r �? ? 1.0 1.2 �? 1.4 �? bb g �? ? 1.0 1.2 �? 1.4 �? v �? output voltage at blue background �? bb b �? ? ? 1.1 1.25 �? 1.4 �? vp-p �? input impedance of #53 �? zin �? ? (note t10) �? 24 �? 30 �? 36 �? k ? �? acl 1 �? ? ? 6.5 �? ? 4.5 �? ? 2.5 �? acl characteristic �? acl 2 �? ? (note t11) �? ? 15.0 �? ? 13.5 �? ? 11.0 �? db �? abl p1 �? ? ? 0.21 �? ? 0.16 �? ? 0.11 �? abl p2 �? ? ? 0.28 �? ? 0.23 �? ? 0.18 �? abl p3 �? ? ? 0.37 �? ? 0.32 �? ? 0.27 �? abl p4 �? ? ? 0.45 �? ? 0.40 �? ? 0.35 �? abl p5 �? ? ? 0.54 �? ? 0.49 �? ? 0.44 �? abl p6 �? ? ? 0.62 �? ? 0.57 �? ? 0.52 �? abl p7 �? ? ? 0.70 �? ? 0.65 �? ? 0.60 �? abl point �? abl p8 �? ? (note t12) �? ? 0.75 �? ? 0.70 �? ? 0.65 �? v �? abl g1 �? ? ? 0.06 �? ? 0.02 �? 0.00 �? abl g2 �? ? ? 0.17 �? ? 0.12 �? ? 0.07 �? abl g3 �? ? ? 0.34 �? ? 0.29 �? ? 0.24 �? abl g4 �? ? ? 0.52 �? ? 0.47 �? ? 0.42 �? abl g5 �? ? ? 0.68 �? ? 0.63 �? ? 0.59 �? abl g6 �? ? ? 0.85 �? ? 0.80 �? ? 0.75 �? abl g7 �? ? ? 1.01 �? ? 0.96 �? ? 0.91 �? abl gain �? abl g8 �? ? (note t13) �? ? 1.09 �? ? 1.04 �? ? 0.99 �? v �?
TA1360ANG 2003-01-21 34 characteristics symbol test circuit test condition min typ. max unit v 43r �? ? 2.15 �? 2.40 �? 2.65 �? v 42r �? ? 0.30 �? 0.80 �? 1.30 �? v 41r �? ? 0.30 �? 0.80 �? 1.30 �? v 43g �? ? 0.30 �? 0.80 �? 1.30 �? v 42g �? ? 2.15 �? 2.40 �? 2.65 �? v 41g �? ? 0.30 �? 0.80 �? 1.30 �? v 43b �? ? 0.30 �? 0.80 �? 1.30 �? v 42b �? ? 0.30 �? 0.80 �? 1.30 �? rgb output mode �? v 41b �? ? (note t14) �? 2.15 �? 2.40 �? 2.65 �? v �? 1 �? ? 56 66 �? 76 �? 2 �? ? 72 �? 82 �? 92 �? ire �? ? 1 �? ? 0.49 �? 1.24 �? 1.99 �? ? 2 �? ? ? 1.67 �? ? 0.92 �? ? 0.17 �? y-out characteristic �? ? 3 �? ? (note t15) �? ? 4.59 �? ? 3.84 �? ? 3.09 �? db �? bs pmin �? ? 37 42 47 bs pcnt �? ? 72 77 82 bs pmax �? ? 101 106 111 ire �? bs gmin �? ? 2.1 3.1 4.1 bs gcnt �? ? 6.4 7.4 8.4 white-peak blue characteristic �? bs gmax �? ? (note t16) �? 9 �? 10 �? 11 �? db �? forced blk input threshold voltage �? v blkin �? ? pin 52 �? 5.1 5.6 6.1 v �? acbr �? ? ? �? 1 �? ? �? acbg �? ? ? �? 2 �? ? �? acbb �? ? ? �? 3 �? ? �? h �? v acb1r �? ? 0.15 0.20 0.25 v acb1g �? ? 0.15 0.20 0.25 v acb1b �? ? 0.15 0.20 0.25 v acb2r �? ? 0.27 0.32 0.37 v acb2g �? ? 0.27 0.32 0.37 v acb2b �? ? 0.27 0.32 0.37 v acb3r �? ? 0.52 0.57 0.62 v acb3g �? ? 0.52 0.57 0.62 acb insertion pulse phase and amplitude �? v acb3b �? ? (note t17) �? 0.52 0.57 0.62 vp-p �? ik r �? ? 0.73 �? 0.93 �? 1.13 �? ik g �? ? 0.73 �? 0.93 �? 1.13 �? ik input amplitude �? ik b �? ? (note t18) �? 0.73 �? 0.93 �? 1.13 �? vp-p �? dik in + �? ? 3.00 3.30 3.60 ik input cover range �? dik in ? �? ? (note t19) �? ? 0.50 ? 0.30 ? 0.10 v �?
TA1360ANG 2003-01-21 35 characteristics symbol test circuit test condition min typ. max unit g txr �? ? 3.03 �? 3.40 �? 3.83 �? g txg �? ? 3.03 �? 3.40 �? 3.83 �? analog rgb gain �? g txb �? ? (note t20) �? 3.03 �? 3.40 �? 3.83 �? times �? g txg/r �? ? 0.94 �? 1.00 �? 1.06 �? analog rgb gain 3-axis difference �? g txb/r �? ? ? �? 0.94 �? 1.00 �? 1.06 �? ? �? gf txr �? ? 30 35 ? �? gf txg �? ? 30 35 ? �? analog rgb frequency characteristic �? gf txb �? ? at ? 3db 30 35 ? �? mhz dr 35 �? ? 0.80 �? 1.20 �? 1.50 �? dr 34 �? ? 0.80 �? 1.20 �? 1.50 �? analog rgb input dynamic range �? dr 33 �? ? ? �? 0.80 �? 1.20 �? 1.50 �? vp-p �? txv wpsr �? ? 2.45 2.70 2.95 txv wpsg �? ? 2.45 2.70 2.95 analog rgb white peak slice level �? txv wpsb �? ? (note t21) �? 2.45 2.70 2.95 vp-p �? v bpsr �? ? 1.15 1.30 1.45 v bpsg �? ? 1.15 1.30 1.45 analog rgb black peak limit level �? v bpsb �? ? (note t22) �? 1.15 1.30 1.45 v �? ? v utxr �? ? 15.5 16.5 18.5 ? v utxg �? ? 15.5 16.5 18.5 rgb contrast adjustment characteristic ? v utxb �? ? (note t23) �? 15.5 16.5 18.5 db �? v brtxmax �? ? 3.0 3.2 3.4 v brtxcnt �? ? 2.6 2.8 3.0 analog rgb bright adjustment characteristic �? v brtxmin �? ? (note t24) �? 2.1 2.3 2.5 v �? analog rgb mode switching voltage v txon ? pin 49 0.65 0.85 1.05 v rys �? ? ? �? 15 �? 50 �? tp rys �? ? ? �? 20 �? 50 �? ? t rys �? ? ? �? 0 �? 10 �? fys �? ? ? �? 10 �? 50 �? tp rys �? ? ? �? 30 �? 50 �? analog rgb mode switching transfer characteristic �? ? t rys �? ? (note t25) �? ? �? 0 �? 10 �? ns �? txacl 1 �? ? ? 6.7 �? ? 4.7 �? ? 2.7 �? text acl characteristic �? txacl 2 �? ? (note t26) �? ? 16.5 �? ? 14.5 �? ? 12.5 �? db �? g osdr �? ? 2.95 3.30 3.70 g osdg �? ? 2.95 3.30 3.70 analog osd gain �? g osdb �? ? (note t27) �? 2.95 3.30 3.70 times �? g osdg/r �? ? 0.94 �? 1.00 �? 1.06 �? analog osd gain 3-axis difference �? g osdb/r �? ? ? �? 0.94 �? 1.00 �? 1.06 �? ? �? gf osdr �? ? 35 �? 40 ? �? gf osdg �? ? 35 �? 40 ? �? analog osd frequency characteristic �? gf osdb �? ? at ? 3db 35 �? 40 ? �? mhz �? dr 39 �? ? 0.80 �? 1.20 �? 1.50 �? dr 38 �? ? 0.80 �? 1.20 �? 1.50 �? analog osd input dynamic range �? dr 37 �? ? ? �? 0.80 �? 1.20 �? 1.50 �? vp-p �?
TA1360ANG 2003-01-21 36 characteristics symbol test circuit test condition min typ. max unit osdv wpsr �? ? 2.45 2.70 2.95 osdv wpsg �? ? 2.45 2.70 2.95 analog osd input white peak slice level �? osdv wpsb �? ? (note t28) �? 2.45 2.70 2.95 vp-p �? osdv bpsr �? ? 1.30 1.45 1.60 osdv bpsg �? ? 1.30 1.45 1.60 analog osd black peak limit level �? osdv bpsb �? ? (note t29) �? 1.30 1.45 1.60 v �? v uosdr11 �? ? 0.58 0.64 0.71 v uosdg11 �? ? 0.58 0.64 0.71 v uosdb11 �? ? 0.58 0.64 0.71 v uosdr10 �? ? 0.47 0.53 0.59 v uosdg10 �? ? 0.47 0.53 0.59 v uosdb10 �? ? 0.47 0.53 0.59 v uosdr01 �? ? 0.31 0.37 0.45 v uosdg01 �? ? 0.31 0.37 0.45 v uosdb01 �? ? 0.31 0.37 0.45 v uosdr00 �? ? 0.19 0.22 0.24 v uosdg00 �? ? 0.19 0.22 0.24 osd contrast adjustment characteristic �? v uosdb00 �? ? (note t30) �? 0.19 0.22 0.24 vp-p �? v brosd0 �? ? 2.20 2.40 2.60 v brosd1 �? ? 2.05 2.25 2.45 v brosd2 �? ? 1.95 2.15 2.35 analog osd bright adjustment characteristic �? v brosd3 �? ? (note t31) �? 1.80 2.00 2.20 v �? v osdon1 ? pin 51 2.05 2.30 2.55 analog osd mode switching voltage v osdon2 ? pin 50 2.05 2.30 2.55 v rys1 �? ? ? 15 �? 50 �? tp rys1 �? ? ? 20 �? 50 �? ? tp rys1 �? ? ? 0 �? 10 �? fys1 �? ? ? 10 �? 50 �? tp rys1 �? ? ? 30 �? 50 �? ? tp rys1 �? ? ? 0 �? 10 �? rys2 �? ? ? 15 �? 50 �? tp rys2 �? ? ? 20 �? 50 �? ? tp rys2 �? ? ? 0 �? 10 �? fys2 �? ? ? 10 �? 50 �? tp rys2 �? ? ? 30 �? 50 �? analog osd mode switching transfer characteristic �? ? tp rys2 �? ? (note t32) �? ? 0 �? 10 �? ns �? osdacl 1 �? ? ? 0.00 �? ? osdacl 2 �? ? ? 0.00 �? ? osdacl 3 �? ? ? 6.7 �? ? 4.7 �? ? 2.7 �? osd acl characteristic �? osdacl 4 �? ? (note t33) �? ? 16.5 �? ? 14.5 �? ? 12.5 �? db �?
TA1360ANG 2003-01-21 37 characteristics symbol test circuit test condition min typ. max unit 41tv 1 �? ? ? 7 �? ? 6 �? ? 5 �? 42tv 1 �? ? ? 7 �? ? 6 �? ? 5 �? 43tv 1 �? ? ? 7 �? ? 6 �? ? 5 �? 41tv 2 �? ? ? 4 �? ? 3 �? ? 2 �? 42tv 2 �? ? ? 4 �? ? 3 �? ? 2 �? 43tv 2 �? ? ? 4 �? ? 3 �? ? 2 �? 41tv 3 �? ? ? ? 55 �? ? 50 �? 42tv 3 �? ? ? ? 55 �? ? 50 �? 43tv 3 �? ? ? ? 55 �? ? 50 �? 41osd 1 �? ? ? 6.5 �? ? 5.5 �? ? 4.5 �? 42osd 1 �? ? ? 6.5 �? ? 5.5 �? ? 4.5 �? 43osd 1 �? ? ? 6.5 �? ? 5.5 �? ? 4.5 �? 41osd 2 �? ? ? 12.0 �? ? 10.5 �? ? 9.0 �? 42osd 2 �? ? ? 12.0 �? ? 10.5 �? ? 9.0 �? 43osd 2 �? ? ? 12.0 �? ? 10.5 �? ? 9.0 �? 41osd 3 �? ? ? ? 40 �? ? 30 �? 42osd 3 �? ? ? ? 40 �? ? 30 �? osd blending characteristic �? 43osd 3 �? ? (note t34) �? ? ? 40 �? ? 30 �? db �? y rgb input v v a ? ? ? 50 ? 45 y osd input v v o ? ? ? 55 ? 45 rgb input y v a v ? ? ? 50 ? 45 rgb input osd input v a o ? ? ? 50 ? 45 osd input y v o v ? ? ? 45 ? 40 osd input rgb input v o a ? input: signal 1 (f o = 4 mhz, amplitude 0.7 vp-p) �? ? ? 50 ? 45 rgb input in three axes ? ? ? ? 50 ? 40 input crosstalk �? osd input in three axes ? ? input: signal 1 (f o = 1 mhz, amplitude 0.7 vp-p) �? ? ? 50 ? 40 db �? blp min ? 23 28 33 blp max ? 55 60 65 ire blg min ? 2.4 2.9 3.4 blue stretch point/gain blg max ? (note t35) 5.4 6.4 7.4 db bl 1 ? 84 89 94 bl 2 ? 89 94 99 bl 3 ? 93 98 103 blue stretch correction bl 4 ? (note t36) 98 103 108 ire wpl1 ? 16 21 25 wpl2 ? 51 56 61 white letters improvement wpl3 ? (note t37) 97 102 107 vp-p
TA1360ANG 2003-01-21 38 sync block characteristics symbol test circuit test condition min typ. max unit sync input horizontal sync phase s ph ? (note ha01) �? 0.55 0.65 0.75 s hd input horizontal sync phase hd ph ? (note ha02) �? 0.58 0.68 0.78 s �? hd duty1 ? ? 0.5 2.0 hd duty2 ? 62 67 72 hd duty3 ? ? 99.5 98 polarity detecting rage hd duty4 ? (note ha03) �? 47.5 52.5 57.5 % v ths00 ? 10 16 22 v ths01 ? 18 24 30 v ths10 ? 26 32 38 sync input threshold amplitude v ths11 ? (note ha04) �? 34 40 46 % hd input threshold voltage v thhd ? (note ha05) �? 0.65 0.75 0.85 vp-p ? h sft ? ? 11 12.5 14 horizontal picture position (phase) adjustment variable range ? h sft + ? (note ha06) �? 11 12.5 14 % horizontal picture position (phase) shift switching amount h sft ? ? 5.2 6.7 9.2 % curve correction variable amount ? h #23 ? (note ha07) �? 2.9 3.4 3.9 % cp s0 ? 3.1 3.8 4.5 cp w0 ? 2.0 2.5 3.0 % cp v0 ? 4.7 5.0 5.3 v cp s1 ? 0 0.7 1.5 cp w1 ? 1.9 2.4 2.9 % cp v1 ? 4.7 5.0 5.3 v cp s2 ? 3.2 4.2 5.2 cp w2 ? 2.2 2.7 3.2 % clamp pulse phase/width/level cp v2 ? (note ha08) �? 4.7 5.0 5.3 v hbp s00a ? 1.2 3.0 5.9 hbp s00b ? 1.2 3.0 5.9 hbp s01a ? 6.0 8.0 11.0 hbp s01b ? 6.0 8.0 11.0 hbp s10a ? 10.0 13.0 15.0 hbp s10b ? 10.0 13.0 15.0 hbp s11a ? 16.0 18.0 21.0 black peak detection pulse phase hbp s11b ? (note ha09) �? 16.0 18.0 21.0 % fbp threshold v thfbp ? (note ha10) �? 4.8 5.3 5.8 v hvco oscillation start voltage v vco ? pin 21: monitor, v cc voltage �? 3.0 4.0 5.0 v h-out start voltage v hon ? pin 26: monitor, v cc voltage �? 5.0 6.0 7.0 v h-out stop voltage v hoff ? pin 26: monitor, v cc voltage 4.3 5.3 6.3 v th a ? 38 41 43 h-out pulse duty th b ? (note hb01) �? 44 47 49 %
TA1360ANG 2003-01-21 39 characteristics symbol test circuit test condition min typ. max unit f15k ? 15.59 15.75 15.91 f28k ? 27.90 28.125 28.35 f31k ? 31.19 31.5 31.82 f33k ? 33.41 33.75 34.09 f37k ? 37.60 37.9 38.40 horizontal free-run frequency f45k ? (note hb02) �? 44.52 45.0 45.48 khz f15k min ? 14.78 15.08 15.38 f15k max ? 16.37 16.70 17.03 f28k min ? 26.00 26.90 27.80 f28k max ? 28.90 29.70 30.60 f31k min ? 29.47 30.06 30.65 f31k max ? 32.72 33.39 34.06 f33k min ? 31.41 31.94 32.57 f33k max ? 34.91 35.62 36.33 f37k min ? 36.50 37.30 38.20 f37k max ? 40.20 41.10 42.10 f45k min ? 43.20 44.00 44.80 horizontal oscillation frequency variable range f45k max ? (note hb03) �? 47.85 48.65 49.45 khz bh15k ? 176 220 264 bh28k ? 320 400 480 bh31k ? 352 440 528 bh33k ? 376 470 564 bh37k ? 390 480 570 horizontal oscillation control sensitivity bh45k ? hz/0.1 v (note hb04) �? 520 650 780 ? v hoh ? 4.8 5.1 5.2 h-out output voltage v hol ? (note hb05) �? ? 0.1 0.3 v pin 13 v fhsw1 ? 1.7 2.0 2.3 v fhsw2l ? 1.3 1.5 1.7 v fhsw2m ? 4.3 4.5 4.7 horizontal oscillation frequency control voltage threshold pin 22 v fhsw2h ? ? �? 7.3 7.5 7.7 v vdac 1h ? test = (00), dac1 = (0) 8.5 9.0 ? dac1 vdac 1l ? test = (00), dac1 = (1) ? 0.3 0.7 vdac 2h ? test = (00), dac2 = (1) 8.5 9.0 ? dac switch voltage dac2 vdac 2l ? test = (00), dac2 = (0) ? 0.3 0.7 v vp output pulse width vp w ? (note v01) �? 4 4.5 5 h 000 vpt0 ? 1278 1281 1284 001 vpt1 ? 846 849 852 010 vpt2 ? 722 725 728 011 vpt3 ? 657 660 663 100 vpt4 ? 610 613 616 101 vpt5 ? 360 363 366 vertical free-run (maximum pull-in range) 110 vpt6 ? ? �? 304 307 310 h vertical minimum pull-in range t vpull ? (note v02) �? 47 48 49 h
TA1360ANG 2003-01-21 40 characteristics symbol test circuit test condition min typ. max unit vbpp 0e ? 51 52 53 000 vbpp 0s ? 1099.5 1100.5 1101.5 vbpp 1e ? 51 52 53 001 vbpp 1s ? 729.5 730.5 731.5 vbpp 2e ? 49.5 50.5 51.5 010 vbpp 2s ? 599.5 600.5 601.5 vbpp 3e ? 49.5 50.5 51.5 011 vbpp 3s ? 544.5 545.5 546.5 vbpp 4e ? 51 52 53 100 vbpp 4s ? 499.5 500.5 501.5 vbpp 5e ? 51 52 53 101 vbpp 5s ? 289.5 290.5 291.5 vbpp 6e ? (note v03) �? 51 52 53 h vertical black peak detection pulse 110 vbpp 6s ? �? 239.5 240.5 241.5 v blkmin ? 15 16 17 vertical blanking end phase v blkmax ? (note v04) �? 45 46 47 h high v vph ? 4.6 5.0 5.4 vp output voltage low v vpl ? pin 27 voltage �? ? 0.1 0.5 v 15.75 khz ? 10.0 11.6 13.4 28.125 khz ? 5.4 6.4 8.8 31.5 khz ? 4.8 5.8 7.6 33.75 khz ? 4.4 5.4 7.2 37.9 khz ? 3.9 4.8 6.6 sync input to vp output delay time 45 khz ? ? 3.1 4.1 5.9 s cblk1 000min ? 1087 1088 1089 000 cblk1 000max ? 1117 1118 1119 cblk1 001min ? 719 720 721 001 cblk1 001max ? 749 750 751 cblk1 010min ? 591 592 593 010 cblk1 010max ? 621 622 623 cblk1 011min ? 527 528 529 011 cblk1 011max ? 557 558 559 cblk1 100min ? 487 488 489 100 cblk1 100max ? 517 518 519 cblk1 101min ? 279 280 281 101 cblk1 101max ? 309 310 311 cblk1 110min ? 223 224 225 compression blk 1 (start phase) 110 cblk1 110max ? ? 253 254 255 h
TA1360ANG 2003-01-21 41 characteristics symbol test circuit test condition min typ. max unit cblk2 000min ? 49 50 51 000 cblk2 000max ? 77 78 79 cblk2 001min ? 49 50 51 001 cblk2 001max ? 77 78 79 cblk2 010min ? 49 50 51 010 cblk2 010max ? 77 78 79 cblk2 011min ? 49 50 51 011 cblk2 011max ? 77 78 79 cblk2 100min ? 49 50 51 100 cblk2 100max ? 77 78 79 cblk2 101min ? 49 50 51 101 cblk2 101max ? 77 78 79 cblk2 110min ? 49 50 51 compression blk 2 (end phase) 110 cblk2 110max ? ? 77 78 79 h external v-blk input current i extblk ? pin 27 input current 520 625 780 a
TA1360ANG 2003-01-21 42 test condition for picture quality (sharpness) block common test condition for picture quality (sharpness) block 1. sw4 = sw5 = b, sw8~sw10 = b, sw20 = on, sw23 = b, sw33 sw39 = a, sw54 = open 2. send bus control data as preset values, turn acb operation switching to acb off (00), select sync input (1), turn p-mode to normal 1(000), wpl-level to max (111), and change subaddress (1c) to (03). 3. input sync signal, which is in sync with input signal for testing except ?sweep?, to #14 (sync input). ?h-freq.? should be t he same frequency as the one of #14. 4. set y/color difference input mode to (0), sync separator level to 20 % (01), and vertical free-running frequency to 307h (11 0). test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p01 black detection level shift b c c b open 1. connect external power supply ps to #3, and monitor #2 and #56. 2. set black stretch point 1 to off (000), and black detection level to 0 ire (1). 3. increase ps voltage from 4.95 v in steps of 1 mv. at the moment when #2 picture period (high) drops to low level, monitor dc difference on #56 v b . 4. set black detection level to 3 ire (0). 5. repeat the step 3 above and monitor dc difference, v b3 on #56. p02 black stretch amp maximum gain b a a b open 1. set sw2 to a (maximum gain), and input 500-khz sine wave to tpa. 2. adjust signal amplitude to 0.1 vp-p on #3. 3. set black stretch point 1 to off (000), and measure #56 amplitude v a . 4. set black stretch point 1 to 001 (black stretch on), and measure #56 amplitude v b . 5. calculate gbs using a following equation. gbs = 20 og l (v b v a ) [db] v b , v b3 #56 waveform #2 waveform
TA1360ANG 2003-01-21 43 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p03 black stretch start point 1 a a c b open 1. set sw2 to a (maximum gain), and black stretch point 1 to off (000). apply 0 v to #1. 2. connect external power supply ps to #3, increase voltage from v 3 , and plot #56 voltage change s1. the #56 voltage is set as v 0 when v 3 is applied, and as v 100 when v 3 + 0.7 v is applied. 3. set black stretch point 1 to minimum (001), increase ps voltage from v 3 , and then plot #56 voltage change s2. 4. set black stretch point to maximum (111), repeat 3 above, then plot #56 voltage change s3. 5. determine intersection points of s1, s2 (v bst1 ), and s3 (v bst2 ) as shown in the figure below. also calculate p bst1 and p bst2 using following equations. v z [v] = v 100 [v] ? v 0 [v] p bst1 [(ire)] = [(v bst1 [v] ? v 56 [v]) v z ] 100 (ire) p bst2 [(ire)] = [(v bst2 [v] ? v 56 [v]) v z ] 100 (ire) #56 #3 v 56 v bst1 v bst2 s3 s2 s1
TA1360ANG 2003-01-21 44 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p04 black stretch start point 2 a a a b on 1. set black stretch point 1 to off (000), apply 0 v to #1, input tg7 linearity to t pa, adjust amplitude on #3 as shown in the figure below, set unicolor to center (1000000), and measure amplitude of #43 (r out), v p43 . 2. set black stretch point 1 to 001 (black stretch on), connect external power supply ps to #56, and monitor #43 (r out). 3. set black stretch start point 2 data to minimum (00). when ps is v 56 (apl 0%), and v 56 + 1.0 v (apl 100%), determine black stretch start point difference ? v 00 as shown in the figure below. (monitor input waveform and output waveform with an oscilloscope, adjust the both waveforms to have the same amplitude (gradient), and compare them to determine the bend point of the output.) 4. set black stretchstart point 2 data to maximum (11), determine black stretch start point difference ? v1 1 . 5. calculate following equations. p bs1 = ( ? v 00 /v p43 ) 100 p bs2 = ( ? v 11 /v p43 ) 100 apl 0% #3 waveform (linearity) 0.7 v p-p 0.3 v p-p ? v *** #43 (r out) apl 100% linearity
TA1360ANG 2003-01-21 45 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p05 black stretch characteristic switch a a c b open 1. set sw2 to a (maximum gain), black stretch point 1 (18) to maximum (e0), subaddress (1c) data to (00) and (1e) data to (08). 2. apply 0 v to #1 and connect external power supply ps to #3. set ps to v 3 + 0.7 v, and adjust unicolor so that dc level of #43 is + 1.0 v. plot voltage change s4 of #43 (voltage in picture period). 3. determine intersection points (v bsc1 and v bsc2 ) of s2 and s4 obtained from the plot in black stretch start point 1. then calculate p bsc1 and p bsc2 using following equation. 4. set black stretch characteristic switch subaddress data (1c)/(1e) to (20)/(00) and (20)/(08) respectively. as described in steps 2 and 3, determine intersection points (v bsc3 , v bsc4 , v bsc5 and v bsc6 ) and calculate p bsc3 , p bsc4 , p bsc5 and p bsc6. p bsc * = (v bsc * [v] ? v 43 [v]) 1.0 100 [(ire)] v 43 v3 s4 black stretch characteristic switch on v bsc2 v bsc1 #43 s2 v 3 + 0.7 v #3
TA1360ANG 2003-01-21 46 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p06 black stretch area reinforcement current b ? c b on 1. connect external power supply ps1 to #3. 2. leave sw2 open, put an ammeter between sw2a and #2, connect external power supply ps2 to sw2a, set ps1 to 5.7 v, and set ps2 to 5 v. 3. measure current value ibsa0 and ibsa1 when bus data of black stretch area reinforcement [18] is set to on [80] and off [81]. calculate ibsa using the following equation. ibsa = ibsa0 � ibsa1 p07 d.abl detection voltage b a c b open 1. set d.abl sensitivity to maximum (11), and black stretch point 1 to off (000). 2. connect external power supply ps to #53 and decrease voltage from 6.5 v. 3. repeat 2 when d.abl detection voltage is changed to 00, 01, 10, and 11. at the moment when #56 picture period changes to low, measure respective ps voltages v 00 , v 01 , v 10 , and v 11 . 4. calculate voltage differences between v 00 and v 01 (dv 01 ), between v 00 and v 10 (dv 10 ), and between v 00 and v 11 (dv 11 ) dv *** = v 00 ? v 01 (v 10 , v 11 ) #2 waveform #56 detected #56 undetected �� mmeter sw2a ps2 5 v a
TA1360ANG 2003-01-21 47 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p08 d.abl sensitivity b a c b on 1. set black stretch point 1 to off (000), and connect external power supply to #53. 2. set d.abl detection voltage to minimum (00). interrelation between #53 voltage and #56 voltage when d.abl sensitivity is set to minimum (00) and maximum (11) can be plotted as figure shown below. 3. measure gradients sdamin and sdamax using the figure below. s damin = ? y/ ? x s damax = ? y/ ? x ? y #53 ? x 100% 10% 10% #56
TA1360ANG 2003-01-21 48 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p09 black level correction b a a b open 1. set black stretch point 1[18] to off (00). 2. input signal of 0.7-v picture period amplitude to #3, and measure #43 picture period amplitude vb [v]. 3. set black level correction [18] to on [04], determine dc change vblc [v], and calculate blc [v] using the following equation blc = (vblc/vb)] 100 [(ire)] vb #43 vblc black level correction on black level correction off
TA1360ANG 2003-01-21 49 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p10 dynamic y correction point a b c b open 1. connect external power supply ps1 to #3, ps2 to tp1, and set ps2 to 0 v. 2. set dark area dynamic y gain vs dark area to min (00), static y gain1 to off (000). 3. increase ps1 from v 3 [v] to v 3 [v] + 0.7 v and plot voltage change of #43 picture period. take 0 for v 3 [v] when the change is plotted. (v 3 is pin voltage of pin 3) 4. set dark area dynamic y gain vs dark area max (11), static y gain1 to max (111) and ps2 to 1.2 v. 5. increase ps1 from v 3 [v] to v 3 [v] + 0.7 v and plot voltage change of #43 picture period. 6. measure vdgp by the following figure, and p dgp using the following equation. dgp = (vdgp [v] ? v 3 [v])/0.7 [v] 100 off on #43 voltage [v] #3 voltage [v] vdgp v 3 + 0.7v (100 ire) v 3
TA1360ANG 2003-01-21 50 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p11 dark area dynamic y gain a b c b open 1. connect external power supply ps1 to #3, external power supply ps2 to tp1, and set ps2 to 0 v. 2. set dark area dynamic y gain [1c] to min [03], and dark area static y gain [1c] to 0db [17]. 3. set ps1 to v 3 [v], and measure #43 picture period voltage vddgv 3 [v]. set ps1 vdgp [v], and measure #43 picture period voltage vddgmin [v]. 4. set dark area dynamic y gain [1c] to max [d7], ps2 to 1.2 v, measure voltage vddgmax [v] of #43 picture period when ps1 is vdgp [v], and calculate the following equations. vddgmax ? vddgmin = a vddgmin ? vddgv 3 = b gddgmax = 20 og l [b/(b-a)] [db] off on #43 voltage [v] #3 voltage [v] vdgp vddgv 3 vddgmin vddgmax vddgmin ? vddgv 3 = b vddgmax ? vddgmin = a v 3 v 3 + 0.7 v (100ire)
TA1360ANG 2003-01-21 51 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p12 dark area static y gain a b c b open 1. connect external power supply ps1 to #3, external power supply ps2 to tp1, and set ps2 to 0 v. 2. set dark area dynamic y gain [1c] to min [03], and dark area static y gain [1c] to off [03]. 3. set ps1 to v 3 [v], and measure #43 picture period voltage vsgoff1 [v]. 4. set ps1 to vdgp [v], and measure #43 picture period voltage vsgoff2 [v]. 5. set dark area static y gain [1c] to max [1f], ps1 to vdgp [v], measure #43 picture period voltage vsgmax, and calculate gdsgmax using the following equations. vsgmax ? vsgoff2 = a vsgoff2 ? vsgoff1 = b gdsgmax = 20 og l [b/(b - a)] [db] 6. set dark area static y gain [1c] to min [07], ps1 to vdgp [v], measure #43 picture period voltage vsgmin, and calculate gdsgmin using the following equation. gdsgmin = 20 og l [(vsgmin ? vsgoff1)/(vsgoff2 ? vsgoff1)] [db] off on #43 voltage [v] #3 voltage [v] vdgp vsgoff1 vsgoff2 vsgmax vsgmax ? vsoff2 = a v 3 v 3 + 0.7 v (100ire) vsgoff2 ? vsgoff1 vsgmin ? vsgoff1 off on #43 voltage [v] #3 voltage [v] vdgp vsgoff1 vsgoff2 vsgmin v 3 v 3 + 0.7 v (100ire)
TA1360ANG 2003-01-21 52 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p13 light area y correction point a b c a open 1. connect external power supply ps1 to #3, external power supply ps2 to tp1, and set ps2 to 0 v . 2. set dark area static y gain [1c] to 0db [17], and bright area static y gain [1c] to 0db [17]. 3. increase ps1 from v 3 [v] to v 3 [v] + 0.7 [v], and plot the voltage change of #43 picture period. take 0 for v 3 [v] when the change is plotted. (v 3 is pin voltage of pin 3) 4. set light area static y gain [1c] to max [04]. 5. increase ps1 from v 3 [v] to v 3 [v] + 0.7 [v], and plot the voltage change of #43 picture period. 6. measure vlgp using the following figure, and plgp using the following equation. lgp = (vlgp [v] ? v 3 [v])/0.7 [v] 100 (ire) #43 voltage [v] off on #3 voltage [v] vlgp v 3 v 3 + 0.7 v (100ire)
TA1360ANG 2003-01-21 53 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p14 light area dynamic y gain a b c a open 1. connect external power supply ps1 to #3, external power supply ps2 to tp7, and set ps2 to 1.2 v. 2. set dark area static y gain [1c] to 0db [17], and light area static y gain [1c] to 0db [17]. 3. set ps1 to v 3 [v], and measure #43 picture period voltage vldgoff1. 4. set ps1 to vlgp [v], and measure #43 picture period voltage vldgoff2. 5. set light area static y gain [1c] to max [14], ps2 to 0 v, ps1 to vlgp [v], determine #43 picture period voltage vldgmax [v] using the following equations. vldgmax ? vldgoff2 = a vldgoff2 ? vldgoff1 = b gldg = 20 og l [b/(b ? a)] vldgmax ? vldgoff2 = a vldgoff2 ? vldgoff1 = b off on #43 voltage [v] #3 voltage [v] vlgp vldgoff1 vldgoff2 vldgmax v 3 v 3 + 0.7 v (100ire)
TA1360ANG 2003-01-21 54 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p15 light area static y gain b b c a open 1. connect external power supply ps1 to #3, external power supply ps2 to tp7, and set ps2 to 0 v. 2. set dark area static y gain [1c] to 0db [17], and light area static y gain [1c] to 0db [17]. 3. set ps1 to v 3 [v], and measure #43 picture period voltage vlsgoff1 [v]. 4. set ps1 to vlgp [v], and measure #43 picture period voltage vldgoff2 [v]. 5. set light area static y gain [1c] to max [14], ps1 to vlgp [v], measure #43 picture period voltage vlsgmax, and calculate glasgmax [db] using the following equations. vlsgmax ? vlsgoff2 = a vlsgoff2 ? vlsgoff1 = b glsgmax = 20 og l [b/(b ? a)] [db] 6. set light area static y gain [1c] to min [16], ps1 to vlgp [v], measure #43 picture period voltage vlsgmin, and calculate glasgmin [db] using the following equations. vlsgmin ? vlsgoff2 = c vlsgoff2 ? vlsgoff1 = b glsgmin = 20 og l [b/(b ? c)] [db] vlsgmin ? vldgoff2 = c vlsgoff2 ? vlsgoff1 = b off on #43 voltage [v] #3 voltage [v] vlgp vlsgoff1 vlsgmin v 3 v 3 + 0.7 v (100ire) vlsgmax ? vldgoff2 = a vlsgoff2 ? vlsgoff1 = b off on #43 voltage [v] #3 voltage [v] vlgp vlsgoff1 vlsgoff2 vlsgmax v 3 v 3 + 0.7 v (100ire)
TA1360ANG 2003-01-21 55 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p16 dark area detection sensitivity a b a a open 1. input the signal whose picture period amplitude is 0.18 v to #3 as shown in the figure below. 2. measure #1 pin voltage damin, dacen, and damax [v] when dark area detection sensitivity [1d] is set to min [00], cen [04] and max [07]. #3 0.18 v #1 damin �k cen �k max [v]
TA1360ANG 2003-01-21 56 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p17 dc restoration rate correction gain b b c b on 1. set dc restoration rate correction point to minimum (000), dc restoration rate correction limit point to 80% (11), and connect external power supply ps1 to #3. 2. monitor dc level of #43 picture period. set ps1 to v 3 + 0.7 v, and adjust uncolor so that dc level is + 0.7. 3. set dc restoration correction rate to minimum (000), and measure v dt1 and v dt2 of v 3 [v] and v 3 + 0.1 v as shown in the figure below. 4. set #3 to v 3 + 0.1 v, dc restoration correction rate to maximum (111), and measure v dt3 . 5. set dc restoration correction rate sw to less than 100 % (1), #3 to v 3 + 0.1 v, dc restoration correction rate to maximum (111), and measure v dt4 . 6. calculate adt 100 , adt 135 , and adt 65 using following equations. adt 100 = (v dt2 [v] ? v dt1 [v]) 0.1 [v] adt 135 = (v dt3 [v] ? v dt1 [v]) 0.1 [v] adt 65 = 1 ? ( (v dt2 [v] ? v dt4 [v]) 0.1 [v]) picture period v dt1 v 3 [v] v dt2 v dt3 v dt4 v 3 + 0.1 v #43 waveform
TA1360ANG 2003-01-21 57 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p18 dc restoration rate correction point b b c b on 1. set dc restoration rate correction point to minimum (000), dc restoration rate correction limit point to 80% (11), and connect external power supply ps1 to #3. 2. monitor dc level of #43 picture period. set ps1 to v 3 + 0.7 v, and adjust unicolor so that dc level is + 1.0. 3. set dc restoration correction rate to minimum (000), and increase ps1 from v 3 . plot relation between #56 (dc voltage) and #43 (voltage in picture period). 4. set dc restoration correction rate to maximum (111), and increase ps1 from v 3 . plot relation between #56 and #43. 5. set dc restoration correction rate to maximum (111), dc restoration rate correction point (111), and increase ps1 from v 3 . plot relation between #56 and #43. 6. determine v dt0 , and v dt1 using the following equations. v dt0 = [(v sp0 ? v 56 )/1 v] 100% v dt1 = [(v sp1 ? v 56 )/1 v] 100% dc restoration correction rate 000 dc restoration rate correction point 111 dc restoration rate correction point 000 #56 v sp1 v sp0 v pc #43
TA1360ANG 2003-01-21 58 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p19 dc restoration rate correction limit point b b b c on 1. set unicolor to maximum (1111111), dc restoration rate correction point to minimum (000), and connect external power supply ps1 to #56. 2. set dc restoration correction rate to maximum (111). 3. increase ps from 5 v. monitor #43, and plot dc restoration correction amount. 4. repeat the step 3 above by changing data at dc restoration rate correction limit point. measure the value using the figure below. calculate p dtl60 , p dtl75 , p dtl87 , and p dtl100 using following equations. p dtl60 = [(v l60 ? v 56 )/1.0] 100% p dtl75 = [(v l75 ? v 56 )/1.0] 100% p dtl87 = [(v l87 ? v 56 )/1.0] 100% p dtl100 = [(v l100 ? v 56 )/1.0] 100% 100% (00) 87% (01) 73% (10) 60% (11) v l87 v l100 v l75 v l60 #56 #43
TA1360ANG 2003-01-21 59 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p20 dc fluctuation at switching sharpness control peak frequency b b a b on 1. set unicolor [05] to max [7f], srt gain [19] to min [00], and cde [15] to cen [80]. input setup signal (0.2 vp-p) to tpa as shown in the figure below. 2. set sharpness [09] to min [00] and max [80]. monitor #43, measure dc level vrdcmin and vrdcmax [v]. calculate vrdc [v] using the following equation. vrdc = vrdcmin ? vrdcmax �? [v] #3 0.2 v #43 vrdc *
TA1360ANG 2003-01-21 60 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p21 sharpness control range b b a b on 1. input sine wave to tpa. (the frequency is variable.) 2. set #3 amplitude to 20 mvp-p. 3. set unicolor to maximum (1111111), srt-gain to minimum (00000), apacon peak frequency to 13.5 m (00), and color detail enhancer (cde) to center (10). 4. set picture mute to off (p-mode: normal 1, 000), and monitor #43. 5. set picture sharpness to center (1000000). set input frequency to 100 khz, and measure the amplitude v 100 . 6. set picture sharpness to maximum (1111111). set input frequency to f ap00 , measure the amplitude v max00 , and calculate g max00 using the following equations. 7. set picture sharpness to minimum (0000000). set input frequency to f ap00 , measure the amplitude v min00 , and calculate g min00 using the following equations. 8. set apacon peak frequency to 9.5 m (01). set input frequency to f ap01 , measure v max01 /v min01 and calculate g max01 /g min01 . 9. set apacon peak frequency to 6.4 m (10). set input frequency to f ap10 , measure v max10 /v min10 and calculate g max10 /g min10 . 10. set apacon peak frequency to 4.5 m (11). set input frequency to f ap11 , measure v max11 /v min11 and calculate g max11 /g min11 . g max *** = 20 og l (v max *** v 100 ) [db] g min *** = 20 og l (v min *** v 100 ) [db] note: when a spectrum analyzer is used, measure gain for low frequency.
TA1360ANG 2003-01-21 61 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p22 sharpness control center characteristic b b a b on 1. input sine wave to tpa. (the frequency is variable.) 2. set the amplitude of #3 to 20 mvp-p. 3. set unicolor to maximum (1111111), srt-gain to minimum (00000), apacon peak frequency to 13.5 m (00), and color detail enhancer (cde) to center (10). 4. set picture mute to off (p-mode: normal 1, 000), and monitor #43. 5. set picture sharpness to center (1000000). set input frequency to 100 khz, and measure the amplitude v 100 . 6. set picture sharpness to center (1000000). set input frequency to f ap00 , measure #43 amplitude v cen00 , and calculate g cen00 using the following equations. 7. set apacon peak frequency to 9.5 m (01). set input frequency to f ap01 , measure v cen01 and calculate g cen01 . 8. set apacon peak frequency to 6.4 m (10). set input frequency to f ap10 , measure v cen10 and calculate g cen10 . 9. set apacon peak frequency to 4.5 m (11). set input frequency to f ap11 , measure v cen11 and calculate g cen11 . g cen *** = 20 og l (v cen *** v 100 ) [db] note: when a spectrum analyzer is used, measure gain for low frequency.
TA1360ANG 2003-01-21 62 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p23 2t pulse response srt control b b a b on 1. input 2t pulse (0.7 vp-p) signal to tpa. set unicolor to maximum (1111111), srt-gain to minimum (00000), cde to center (10) picture sharpness control to center (1000000). 2. set apacon peak frequency to13.5 m (00), and monitor #43. 3. measure t srtmin00 and v srtmin00 as shown in the figure below. 4. set srt-gain to maximum (11111), and measure t srtmax00 and v srtmax00 . 5. set apacon peak frequency to 9.5 m (01). set srt-gain to minimum (00000) and maximum (11111). measure t srtmin01 /v srtmin01 and t srtmax01 / v srtmax01 . 6. set apacon peak frequency to 6.4 m (10). set srt-gain to minimum (00000) and maximum (11111). measure t srtmin10 /v srtmin10 and t srtmax10 / v srtmax10 . 7. set apacon peak frequency to 4.5 m (11). set srt-gain to minimum (00000) and maximum (11111). measure t srtmin11 /v srtmin11 and t srtmax11 /v srtmax11 . 8. calculate the following equations. t srt00 = 20 og l ((v srtmax00 /t srtmax00 )/(v srtmin00 /t srtmin00 )) t srt01 = 20 og l [(v srtmax01 /t srtmax01 )/(v srtmin01 /t srtmin01 )] t srt10 = 20 og l [(v srtmax10 /t srtmax10 )/(v srtmin10 /t srtmin10 )] t srt11 = 20 og l [(v srtmax11 /t srtmax11 )/(v srtmin11 /t srtmin11 )] 20% 100% t *** 20% v ***
TA1360ANG 2003-01-21 63 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p24 vsm gain b b a b on 1. input sine wave of f vsm frequency to tpa. set #3 amplitude to 0.02 vp-p. 2. turn on sw54 and change vsm gain from minimum (001) to maximum (111). measure #54 amplitude, v 001 , v 011 , v 100 , v 101 , v 110 , and v 111 . set input amplitude to 0.7 vp-p, and vsm gain to off (000). measure tp54 amplitude v 000 . 3. calculate the following equations. g v000 = 20 og l (v 000 /0.7) [db] g v001 = 20 og l (v 001 /0.02) [db] g v010 = 20 og l (v 010 /0.02) [db] g v011 = 20 og l (v 011 /0.02) [db] g v100 = 20 og l (v 100 /0.02) [db] g v101 = 20 og l (v 101 /0.02) [db] g v110 = 20 og l (v 110 /0.02) [db] g v111 = 20 og l (v 111 /0.02) [db] p25 vsm limit b b b a on 1. input sine wave of frequency f vsm to tpa. 2. set vsm gain to 111, and #3 amplitude to 0.7 vp-p. 3. turn on sw54 and measure tp54 amplitude v lu and v ld [vp-p] as shown in the figure below. v lu v ld
TA1360ANG 2003-01-21 64 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p26 y delay time switching b b a b on 1. set unicolor to maximum (1111111), srt-gain to minimum (00000), and input 2t pulse sig nal (approximately 0.7 v (p-p)) to tpa. 2. set picture sharpness to center (1000000). 3. monitor #3 and #43 as shown in the figure below. measure ydl00 that is the time difference between signals #3 and #43. 4. set y/c-dl1 to + 5 ns (1), and measure ydl01 as shown in the figure below. 5. set y/c-dl1 to 0 ns (0), y/c-dl2 to + 10 ns (1) and measure ydl10 as shown in the figure below. 6. set y/c-dl1 to + 5 ns (1), y/c-dl2 to + 10 ns (1) and measure ydl11 as shown in the figure below. 7. determine ydla, ydlb, and ydlc using the following equations. ydla = ydl01 ? ydl00 ydlb = ydl10 ? ydl00 ydlc = ydl11 ? ydl00 2t pulse approximately 0.7 v p - p 50% 50% ydl00 #3 #43 ydl01 ydl10 ydl11
TA1360ANG 2003-01-21 65 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p27 y group delay correction b b a b on 1. input multi burst signal (4.2-mhz frequency, 0.1 vp-p at #3) of a signal in tpa. set unicolor to maximum (1111111), srt-gain to minimum (00000), and color detail enhancer (cde) to minimum (00000). 2. set sharpness to flat (dec [30]), apacon peak frequency to 4.5 m (11), and monitor #43. 3. sine wave signal a input becomes like signal b on #43 as shown in the figure on the right. measure s a and s b . 4. when group delay correction is set to minimum (0000), signal a becomes like signal c on #43. measure s amin and s bmin . 5. when group delay correction is set to maximum (1111), signal a becomes like signal d on #43. measure s amax and s bmax . 6. calculate the following equations. g amin = 20 og l (s amin /s a ) [db] g bmin = 20 og l (s bmin /s b ) [db] g amax = 20 og l (s amax /s a ) [db] g bmax = 20 og l (s bmax /s b ) [db] note: sine wave input starts and ends within the picture period such as a burst signal. the wave is not continuous. signal a signal b signal c signal d s a s b s amin s bmin s bmax s amax
TA1360ANG 2003-01-21 66 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p28 color detail enhancer (cde) b b a b on 1. set unicolor to maximum (1111111), srt-gain to minimum (00000), color to center (1000000), and color limiter level to 2 vp (1). input sweep signal to tpa so that #3 amplitude is 20 mvp-p. set sw4 to a, and input signal as shown in the figure below (#4 amplitude is 0.2 vp-p) to tp4. 2. set picture sharpness to center (1000000), y detail control to center (1000), and monitor #41 with a spectrum analyzer. 3. when cde is at minimum (00), set low frequency area to 0db, and determine peak level g cdemin . 4. when cde is at maximum (11), set low frequency area to 0db, and determine peak level g cdemax . 5. calculate the following equation. g cde00 = g cdemax00 ? g cdemin00 6. when apacon peak frequency is 13.5 m (00), 9.5 m (01), 6.4 m (10), and 4.5 m (11), calculate g cde00 , g cde01 , g cde10 , and g cde11 respectively using above equation. max output gain [db] input frequency [mhz] 0db picture period blk period 0.2 vp-p min
TA1360ANG 2003-01-21 67 test conditions sw mode note no. characteristics sw1 sw2 sw3 sw7 sw56 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) p29 y detail control range b b a b on 1. set unicolor to maximum (1111111), srt-gain to minimum (00000), cde to center (10), an d apacon peak frequency to 4.5 m (11). input sweep signal to tpa. 2. set #3 amplitude to 20mvp-p. 3. set picture sharpness to center (1000000), y detail control to maximum (1111), and monitor #43 with a spectrum analyzer. 4. set low frequency area to 0db, and measure each peak level g ydmax . 5. set y detail control to center (1000), and measure peak level g ydcen . 6. set y detail control to minimum (0000), and measure peak level g ydmin .
TA1360ANG 2003-01-21 68 test conditions for color difference block 1: yuv input and matrix common test condition for color difference block 1: yuv input and matrix 1. sw1 = b, sw2 = b, sw20 = on, sw33 sw39 = a, sw54 = open, sw56 = open 2. transfer bus control data with preset values. 3. turn acb operation switching to acb off (0), and turn high blight color off (0). 4. input sync signal [must be sync with input signal for testing except sweep.] to #14 (sync input), and set sync-in-sw to 1. test conditions sw mode note no. characteristics sw3 sw4 sw5 sw7 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) c a a b sw8 sw9 sw10 �? s01 color srt gain b b b �? 1. set y mute on (p-mode: y-mute, 001), brightness to center (10000000), color to center (1000000), unicolor to maximum (1111111). 2. input 2t pulse signal to tp4 so that #4 amplitude is 423 mvp-p. 3. monitor #41 output waveform. when color srt peak frequency is 4.5 mhz (0), measure gradients of color srt gain for minimum (00), center (10), and maximum (11) that are sb00min, sb00cen, and sb00max as shown in the figure below. set sb00min to 0db, calculate gs b00cen = 20 og l (sb00cen/sb00min) and gs b00max = 20 og l (sb00max/ssb00min). 4. when color srt peak is 5.8 mhz (1), measure gradients of color srt gain for minimum (00), center (10), and maximum (11). calculate g sb01cen and g sb01max . 5. input 2t pulse signal to tp5 so that #5 amplitude is 300 mvp-p. 6. monitor #43 output waveform. when color srt peak frequency is 4.5 mhz (0), measure gradients of color srt gain for minimum (00), center (10), and maximum (11) that are sr00min, s r00cen , and s r00max as shown in the figure below. set sr00min to 0db, calculate gsb00cen = 20 og l (sb00cen/sb00min) and gsb00max = 20 og l (sb00max/ssb00min). 7. when color srt peak is 5.8 mhz (1), measure gradients of color srt gain for minimum (00), center (10), and maximum (11). calculate g sr01cen and g sr01max . 20% 100% t *** 20% v *** gradient s *** = v *** /t ***
TA1360ANG 2003-01-21 69 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw7 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) c a a b sw8 sw9 sw10 sw56 s02 dynamic y/c compensation b b b open 1. input 100-khz sync signal to tp4, and set #4 amplitude to 0.2 vp-p. 2. set y mute off (p-mode: normal 1, 000), brightness to center (1000000), color to center (1000000), unicolor to maximum (1111111), and y/c gain comp to minimum (00). set black stretch point 1 to off (000), dark area static y gain to minimum (00), light area static y gain to maximum (11), and sw1 to b. apply 5.16 v to #3 from external power supply ps1. 3. monitor #41 output waveform, and measure amplitude vbdy0. 4. set y/c gain comp to maximum (11). set sw1 to b. set black stretch point 1 to off (000), dark area static y gain to maximum (11), light area static y gain to maximum (00), and monitor #41 amplitude vbdy1. 5. set y/c gain comp to maximum (11). switch sw1 to a, and tpi to gnd. set black stretch point 1 to maximum (111), dark area static y gain to minimum (00), bright area static y gain to maximum (11), and monitor #41 amplitude vbdy2. 6. calculate the following equations. gc bdy1 = 20 og l (vbdy1/vbdy0), gc bdy2 = 20 og l (vbdy2/vbdy0) 7. input 100-khz sync signal to tp5, and repeat the procedure above. calculate the following equations. gc rdy1 = 20 og l (vrdy1/vrdy0), gc rdy2 = 20 og l (vrdy2/vbdy0)
TA1360ANG 2003-01-21 70 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw7 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) a/c a/b a/b b sw8 sw9 sw10 sw56 s03 yuv gain b b b open 1. set picture mute to off (p-mode: normal 1, 000), brightness to maximum (11111111), color to center (1000000), and unicolor to maximum (1111111). 2. set sw3 to a. set sw4 and sw5 to b, and input 100-khz sine wave to tpa. set #3 amplitude to 0.2 vp-p. 3. set sw56 open. measure #56 amplitude vy00 and vy01 when y/color difference input mode is set to y/cb/cr (0) and y/pb/pr (1). 4. set sw3 to c, sw4 to a, and sw5 to b. input 100-khz sine wave to tp4, and set #4 amplitude to 0.2 vp-p. 5. measure #41 amplitude vb00 when y/color difference input mode is set to y/cb/cr (0). 6. measure #41 and #43 amplitude vbb01 and vbr01 when y/color difference input mode is set to y/pb/pr (1). 7. set sw3 to c, sw4 to b, and sw5 to a. input 100-khz sine wave to tp5, and set #5 amplitude to 0.2 vp-p. 8. measure #43 amplitude vr00 when y/color difference input mode is set to y/cb/cr (0). 9. measure #41 and #43 amplitude vrb01 and vrr01 when y/color difference input mode is set to y/pb/pr (1). 10. calculate the following equations. g y00 = 20 og l (vy00/0.2), g y01 = 20 og l (vy01/0.2) g cbb = 20 og l (vb00/0.2), g pbb = 20 og l (vbb01/0.2), g pbr = 20 og l (vbr01/0.2) g crr = 20 og l (vr00/02), g prb = 20 og l (vrb01/0.2), g prr = 20 og l (vrr01/0.2)
TA1360ANG 2003-01-21 71 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw7 test method (test condition: v cc = 9 v/2 v, ta = 25 3 c) c a a ? sw33 sw34 sw35 sw37 a a a a sw38 sw39 ? ? s04 green stretch a a ? ? 1. input signal b as shown in the figure below from tp4 (cb/pb1 input), and signal a from tp5 (cr/pr input). 2. set brightness [06] to maximum (ff). 3. measure amplitudes a, b, c, d, and e at #42 (gout) as shown in the figure below. (a00 to e00) 4. set green stretch [14] data to (08), and repeat the step 3 above. (a01 to e01) 5. set green stretch [14] data to (10), and repeat the step 3 above. (a10 to e10) 6. set green stretch [14] data to (18), and repeat the step 3 above. (a11 to e11) 7. green stretch gain is calculated by the following equations a00 a01 gra01 = a00 a10 gra10 = a00 a11 gra11 = b00 b01 grb01 = b00 b10 grb10 = b00 b11 grb11 = c00 c01 grc01 = c00 c10 grc10 = c00 c11 grc11 = d00 d01 grd01 = d00 d10 grd10 = d00 d11 grd11 = e00 e01 gre01 = e00 e10 gre10 = e00 e11 gre11 = si g nal a 0.05 v p - p ? 0.087 vp-p ? 0.05 v p - p 0 vp-p ? 0.1 vp-p si g nal b ? 0.07 vp-p ? 0.122 vp-p ? 0.14 vp-p ? 0.122 vp-p 0 vp-p b pin 42 e d c a 150 270 240 210 180
TA1360ANG 2003-01-21 72 test conditions for color difference block 2 common test conditions for color difference block 2 1. sw1 = b, sw2 = b, sw7~sw10 = b, sw20 = on, sw23 = b 2. unless otherwise specified, measure each bus data with preset values. 3. set the following data. subaddress (00) data (02) subaddress (02) data (0c) subaddress (05) data (7f) subaddress (06) data (6c) subaddress (07) data (40) subaddress (0b) data (7f) subaddress (0c) data (84) subaddress (12) data (f0) subaddress (13) data (f0) subaddress (15) data (00) subaddress (18) data (00) subaddress (1a) data (c0) subaddress (1b) data (e0) subaddress (1c) data (03) subaddress (1d) data (78) test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method a01 color difference contrast adjustment characteristic c a or b a or b a a a a a a 1. set brightness to maximum, and subaddress (12) data to (f0). 2. input signal 3 (f 0 = 100 khz, picture period amplitude = 0.23 vp-p) from pin 5. 3. change unicolor data to maximum (7f), center (40), and minimum (00), and measure pin 43 picture period amplitude v ucymax , v ucycnt , and v ucymin respectively. 4. determine unicolor amplitude ratio between maximum and minimum in decibels. ( ? v ucy ) 5. repeat the steps 2 to 4 above with the following pins: input (picture period amplitude 0.2 vp-p) from pin 4, and measure pin 41.
TA1360ANG 2003-01-21 73 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method a02 color adjustment characteristic c a or b a or b a a a a a a 1. set brightness to maximum, and subaddress (12) data to (f0). 2. input signal 3 (f 0 = 100 khz, picture period amplitude = 0.115 vp-p) from pin 5. 3. change color data to maximum (7f), center (40), and minimum (01), and measure pin 43 picture period amplitudes v ccymax �z v ccycnt , and v ccymin respectively. 4. calculate amplitude ratios of maximum and minimum against color center in decibels. ( ? v ccy ) 5. repeat the steps 2 to 4 above with the following pins: input (picture period amplitude 0.1vp-p) from pin 4 and measure pin 41. a03 color difference halftone characteristic c a or b a or b a a a a a a 1. input signal 3 (f 0 = 100 khz, picture period amplitude 0.2 vp-p) from pin 5. 2. measure pin 43 output picture period amplitude vhtary. 3. apply 1.5 v to pin 52 from external power supply. 4. measure pin 43 output picture period amplitude vhtbry. 5. calculate ght ry = vhtbry/vhtary 6. repeat the steps 1 to 5 above and measure pin 42. calculate ght gy = vhtbgy/vhtagy 7. repeat the steps 1 to 5 above and measure pin 4. calculate ght by = vhtbby/vhtaby.
TA1360ANG 2003-01-21 74 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method a04 color characteristic c b a a a a a a a 1. input signal 2 from pin 5. 2. increase signal 2 amplitude a. determine gamma correction point v 1, v 2, and v 3 of subaddress data (14). set subaddress (14) data as follows: (01) ? off (03) ? 1on (05) ? 2on (07) ? 3on measure #43 output signal amplitude levels and chart a characteristic diagram. 3. determine v where starts applying and gradient ? at on when linearity at off is 1. #43 output amplitude #5 input amplitude v off on
TA1360ANG 2003-01-21 75 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method a05 color limiter characteristic c b a a a a a a a 1. input signal 2 (picture period amplitude = 0.56 vp-p) from pin 4. 2. set subaddress (14) to (00)/(01), and measure pin 43 output signal picture period amplitude, clt 0 /clt 1 . a06 high-bright color gain c b a a a a a a a 1. input signal 2 (picture period amplitude = 0.28 vp-p) from pin 4. 2. adjust color so that pin 41 output picture period amplitude is 1.2 vp-p. 3. set subaddress (0b) data to (80) and measure pin 41 output signal picture period amplitude v 41 . 4. calculate the following equation. hbc 1 = (1.2 ? v 41 )/1.2
TA1360ANG 2003-01-21 76 test conditions for text block common test conditions for text block 1. sw1 = b, sw2 = b, sw7~sw10 = b, sw20 = on, sw23 = b 2. unless otherwise specified, measure each bus data with preset values. 3. set the following data. subaddress (00) data (02) subaddress (02) data (0c) subaddress (05) data (7f) subaddress (06) data (6c) subaddress (07) data (40) subaddress (0b) data (7f) subaddress (0c) data (84) subaddress (12) data (f0) subaddress (13) data (f0) subaddress (15) data (00) subaddress (18) data (00) subaddress (1a) data (c0) subaddress (1b) data (e0) subaddress (1c) data (03) subaddress (1d) data (78) test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t01 ac gain a b b a a a a a a 1. input signal 1 (f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. 2. measure pins 41, 42, and 43 picture period amplitude, v 41 , v 42 , and v 43 . 3. calculate ac gain using the following equations. g r = v 43 /0.2 g g = v 42 /0.2 g b = v 41 /0.2 t02 unicolor adjustment characteristic a b b a a a a a a 1. input signal 1 (f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. 2. change unicolor data to maximum (7f), center (40), and minimum (00) and measure pin 43 picture period amplitude, v umax , v ucnt , and v umin respectively. 3. calculate amplitude ratio of v umax and v umin in decibels ( ? v u ) t03 brightness adjustment characteristic a b b a a a a a a 1. input signal 2 from pin 3 and adjust pin 43 picture period output amplitude to 1 vp-p. 2. change brightness data to maximum (7f), center (80), and minimum (00) and measure pin 43 voltages, v brmax , v brcnt , and v brmin respectively.
TA1360ANG 2003-01-21 77 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t04 white peak slice level c b b a a a a a a 1. set subcontrast to maximum. 2. apply external power supply to pin 3 and gradually increase voltage from 5.8 v. 3. when picture period of pin 43 is clipped, measure pin 43 picture period amplitude voltage, v wps1 . 4. change subaddress (0c) data to (fc) and repeat the steps 1 to 3 above. (v wps2 ) t05 black peak slice level c b b a a a a a a 1. apply external power supply to pin 3 and gradually decrease voltage from 5.8 v. 2. when picture periods are clipped, measure pins 41, 42, and 43 voltage, v bps . t06 rgb output s/n c b b a a a a a a 1. adjust brightness data so that picture period voltage of pin 41 is 2.4 v. 2. set color data to minimum. 3. measure noise levels n41-, n42-, and n43-vp-p in picture period of pin 41, 42, and 43 with an oscilloscope. 4. calculate s/n. n 41 = ? 20 og l [2.3/(0.2 n41)] n 42 = ? 20 og l [2.3/(0.2 n42)] n 43 = ? 20 og l [2.3/(0.2 n43)] t07 halftone characteristic a b b a a a a a a 1. input signal 1 (f 0 = 100 khz, picture period amplitude 0.2 vp-p) from pin 3. 2. measure pin 41 picture period amplitude v41a. 3. apply 1.5 v to pin 52 from external power supply. 4. measure pin 41 picture period amplitude v41b 5. calculate the following equation. g ht1 = v41b/v41a 6. stop applying voltage to pin 52. set subaddress (1a) to data (e2) and measure pin 41-picture period amplitude, v41c. 7. calculate the following equation. g ht2 = v41c/v41a
TA1360ANG 2003-01-21 78 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t08 blk pulse delay time c b b a a a a a a 1. apply signal shown in the figure (a) below to pin 24 (blk input), and measure td on and td off of output signals from pins 41, 42, and 43 shown in the figure (b) below. 63.5 s td on td off (a) appling signal to pin 24 (b) output signal from pins 41, 42, and 43
TA1360ANG 2003-01-21 79 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t09 drive adjustment variable range a b b a a a a a a 1. input signal 1 (f 0 = 100 khz, picture period amplitude 0.2 vp-p) from pin 3. 2. measure picture period amplitude of pin 42 when subaddress (0d) data is changed to maximum (fe), center (80), and minimum (00). 3. use picture period amplitude at center as the base. determine amplitude ratio dr g1 + and dr g1 ? at maximum and minimum in decibels. 4. repeat the steps 1 to 3 above to measure amplitude ratio of pin 41, dr b1 + and dr b1 ? in decibels when subaddress (0e) data is changed. 5. repeat the steps 1 to 3 above to measure amplitude ratio of pin 42, dr g2 + and dr g2 ? in decibels when subaddress (0e) center data is set to (81) used as the base. 6. repeat the steps 1 to 3 above to measure picture period amplitude ratio of pin 41, dr b2 + and dr b2 ? in decibels when subaddress (0e) data is changed to maximum (ff), center (81), and minimum (01). 7. repeat the steps 1 to 3 above to measure picture period amplitude ratio of pin 43, dr r1 + and dr r2 ? in decibels when subaddress (0d) data is changed to maximum (ff), center (81), and minimum (01). 8. repeat the steps 1 to 3 above to measure picture period amplitude ratio of pin 41, dr b3 + and dr b3 ? in decibels when subaddress (0d) data is set to (81), and subaddress (0e) data is changed. 9. repeat the steps 1 to 3 above to measure picture period amplitude ratio of pin 42, dr g3 + and dr g3 ? in decibels when subaddress (0e) data is set to (81), and subaddress (0d) data is changed to maximum (ff), center (81), and minimum (01). 10. repeat the steps 1 to 3 above to measure picture period amplitude ratio of pin 43, dr r2 + and dr r2 ? in decibels when subaddress (0d) data is set to (81), and subaddress (0e) data is changed to maximum (ff), center (81), and minimum (01). t10 #53 input impedance c b b a a a a a a 1. connect external power supply, an ammeter, and a voltmeter to pin 53. adjust voltage so that current value is set to zero. 2. measure the current when voltage of pin 53 is increased by 0.2v. (l in ) 3. calculate the following equation. �/ in53 = 0.2 v/i in ( ? ) ? + ammeter ( a) voltmeter 53 a v
TA1360ANG 2003-01-21 80 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t11 acl characteristic a b b a a a a a a 1. input signal 1 (f 0 = 100 khz, picture period amplitude 0.2 vp-p) from pin 3. 2. measure pin 43 picture period amplitude, vacl1. 3. apply ?dc voltage of pin 53 ? 0.8 v? to pin 53 from external power supply and measure pin 43-picture period amplitude, vacl2. 4. apply ?dc voltage of pin 53 ? 1.3 v? to pin 53 from external power supply and measure pin 43-picture period amplitude, vacl3. 5. calculate the following equations. acl 1 = ? 20 og l (vacl2/vacl1) acl 2 = ? 20 og l (vacl3/vacl1) t12 abl point c b b a a a a a a 1. measure dc voltage of pin 53, vabl1. 2. set subaddress (1b) data to (1c). 3. apply external voltage to pin 53, and decrease voltage from 6.5 v. when voltage of pin 43 starts changing, measure pin 53 voltage, vabl2. 4. change subaddress (1b) data to (3c), (5c), (7c), (9c), (bc), (dc), and (fc) under the status of the step 3 above. measure pin 53 voltage: vabl3, vabl4, vabl5, vabl6, vabl7, vabl8, and vabl9. 5. abl p1 = vabl2 ? vabl1 abl p5 = vabl6 ? vabl1 abl p2 = vabl3 ? vabl1 abl p6 = vabl7 ? vabl1 abl p3 = vabl4 ? vabl1 abl p7 = vabl8 ? vabl1 abl p4 = vabl5 ? vabl1 abl p8 = vabl9 ? vabl1
TA1360ANG 2003-01-21 81 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t13 abl gain c b b a a a a a a 1. apply 6.5-v external voltage to pin 53. 2. set subaddress (1b) data to (00). 3. set brightness data to maximum. 4. apply 4.5-v external voltage to pin 53. 5. change subaddress (1b) data to (00), (04), (08), (0c), (10), (14), (18), and (1c). repeat the step 3 above, and measure vabl11, vabl12, vabl13, vabl14, vabl15, vabl16, vabl17, and vabl18. 6. abl g1 = vabl11 ? vabl10 abl g2 = vabl12 ? vabl10 abl g3 = vabl13 ? vabl10 abl g4 = vabl14 ? vabl10 abl g5 = vabl15 ? vabl10 abl g6 = vabl16 ? vabl10 abl g7 = vabl17 ? vabl10 abl g8 = vabl18 ? vabl10 t14 rgb output mode c b b a a a a a a 1. adjust brightness data so that picture period voltage of pin 43 is 2.4 v. 2. set subaddress (1b) data to (01). 3. measure pins 43, 42, and 41 picture period voltage, v 43r , v 42r , and v 41r . 4. set subaddress (1b) data to (02), and repeat the step 3 above. measure pins 43, 42, and 41 picture period voltage, v 43g , v 42g , and v 41g . 5. set subaddress (1b) data to (03), and repeat the step 3 above. measure pins 43, 42, and 41 picture period voltage, v 43b , v 42b , and v 41b .
TA1360ANG 2003-01-21 82 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t15 y-out characteristic a b b a a a a a a 1. input ramp waveform from pin 3. adjust input amplitude so that picture period amplitude of pin 43 is 2.3 vp-p. 2. set subaddress (0c) data to (81). 3. adjust input amplitude so that picture period amplitude of pin 43 is 2.3 vp-p. 4. monitor pin 43. according to the figure below, determine y-out correction start points 1 and 2. also determine ratios of gradients at y-out on to y-out off in decibel. ( ? 1, ? 2, and ? 3) 100 ire 2 1 output amplitude (y-out) input amplitude 2.3 vp-p ? 1 ? 2 ? 3 note: solid line indicates gamma off. dotted line indicates gamma on.
TA1360ANG 2003-01-21 83 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t16 whitepeak blue characteristic a b b a a a a a a 1. input 0.7-vp-p ramp signal from pin 3. 2. set subcontrast data to maximum. 3. set subaddress (1f) data to (04). 4. set subaddress (1e) data to (01), and monitor pin 41. determine blue stretch start point bs pmin using the figure below. 5. repeat the step 4 above by changing subaddress (1e) data to (04) and (07). determine blue stretch start point bs pcnt and bs pmax . 6. set subaddress (1e) data to (04). 7. monitor pin 41 and calculate ratio of blue stretch on gradient in relative to blue stretch off gradient in decibel (bs gcnt ) using the figure below. 8. repeat the step 7 above by changing subaddress (1f) data to (00) and (07). calculate gradient ratio in decibel (bs gmin and bs gmax ). note: calculate white-peak blue start point in ire as setting positive amplitude at pedestal level of output signal to 2.3 vp-p = 100 ire. on off start point output input amplitude (output from pin 41)
TA1360ANG 2003-01-21 84 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t17 acb insertion pulse phase and amplitude a or c b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. set brightness data to 108. 2. measure pins 46, 47, and 48 voltage. apply measured voltages from external power supply. 3. set subaddress (02) data to (40). 4. use output signals from pins 43, 42, and 41, and measure acb insertion pulse phase as shown in the figure 1. note: take picture period following fbp input fall after v �~ blk ends as phase 1h. after next h �k blk, count the phase as 2h, 3h, and so on. 5. monitor pins 43, 42, and 41. measure acb insertion pulse amplitudes (level from picture period amplitude at quiescent.): vacb1r, vacb1g, and vacb2b. 6. set subaddress (02) data to (80), and repeat the step 5 above: vacb2r, vacb2g, and vacb2b. 7. set subaddress (02) data to (c0), and repeat the step 5 above: vacb3r, vacb3g, and vacb3b. figure 1: rgb output acb insertion pulse 1h 2h 3h 4h v �k blk period figure 2: fbp input (#24)
TA1360ANG 2003-01-21 85 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t18 ik input amplitude a or c b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. set subaddress (02) data to (40). 3. measure voltage amplitude of pin-45 input signal in acb insertion period. 1h = ik r 2h = ik g 3h = ik b t19 ik input cover range c b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. set subaddress (02) data to (40). 3. measure pin 45 dc voltage in v �k blk period. (#45vblk) 4. apply the current externally to pin 45. 5. measure dc voltage of pin 45 in v �k blk period when pin-43 picture period voltage begins to be decreased. (#45vblk + ) 6. apply current outward from pin 45. 7. measure dc voltage of pin 45 in v �k blk period when pin-43 picture period voltage begins to be increased. (#45vblk ? ) 8. dik in + = (#45vblk + ) ? (#45vblk) dik in ? = (#45vblk ? ) + (#45vblk) t20 analog rgb gain a b b a or b a or b a or b a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pin 49. 3. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 35. 4. measure pin 43 picture period amplitude, v43r. 5. repeat the steps 3 and 4 above with the following pins: input from pin 34, and measure output from pin 42 (v42g). input from pin 33, and measure output from pin 41 (v41b). 6 calculate the following equations. gtxr = v43r/0.2 gtxg = v42g/0.2 gtxb = v41b/0.2 t21 analog rgb white peak slice level a b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pin 49. 3. set rgb contrast data to maximum (7f). 4. input signal 2 to pin 35. gradually increase picture amplitude, and measure picture period amplitude voltage when output from pin 43 is clipped. 5. repeat the steps 3 and 4 above with following pins: input from pin 34 and measure output from pin 42. input from pin 33 and measure output pin 41.
TA1360ANG 2003-01-21 86 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t22 analog rgb black peak limit level a b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pin 49. 3. set rgb contrast data to maximum (7f). 4. input signal 2 to pin 35. gradually decrease picture amplitude, and measure picture period amplitude voltage when output from pin 43 is clipped. 5. repeat the step 4 above with the following pins: input from pin 34 and measure output from pin 42. input from pin 33 and measure output pin 41. t23 rgb contrast adjustment characteristic a b b a or b a or b a or b a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pin 49. 3. input signal 1 (f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 35. 4. rgb contrast data to maximum (7f), center (40), and minimum (00). measure pin 43 picture period amplitudes v utxr (maximum, center, and minimum) respectively. 5. calculate amplitude ratio of maximum and minimum in decibels. 6. repeat the steps 4 and 5 above with the following pins: input from pin 34 and measure pin 42. input from pin 33 and measure pin 41. t24 analog rgb brightness adjustment characteristic a b b a or b a or b a or b a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. input signal 2 from pins 33, 34, and 35. 3. apply 5-v external voltage to pin 49. 4. adjust amplitude a of signal 2 so that picture period amplitude of pin 43 is 0.5 vp-p. 5. change rgb brightness data to maximum (fe), center (80), and minimum (00). measure pins 43, 42, and 41 picture period voltage v brtx (maximum, center, and minimum) respectively. t25 analog rgb mode switching transfer characteristic c b b a a a a a a 1. set rgb brightness data to maximum (fe). 2. input signal 4 (signal amplitude = 1.5 vp-p) from pin 49. 3. measure input/output transfer characteristics using pin 43 according to the figure t-2. 4. repeat the steps 2 and 3 above with the following pins: input from pin 34 and measure pin 42. input from pin 33 and measure pin 41. 5. calculate maximum inter-axial rise/fall transfer delay time, using the data measured above.
TA1360ANG 2003-01-21 87 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t26 text acl characteristic a b b a a b a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pin 49. 3. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 35. 4. measure pin 43 picture period amplitude, vtxacl1. 5. apply ?pin 53 dc voltage ? 0.8 v? to pin 53 from external power supply, and measure pin 43-picture period amplitude, vtxacl2. 6. apply ?pin 53 dc voltage ? 1.3 v? to pin 53 from external power supply, and measure pin 43-picture period amplitude, vtxacl3. 7. txacl 1 = ? 20 og l (vtxacl2/vtxacl1) txacl 2 = ? 20 og l (vtxacl3/vtxacl1) t27 analog osd gain a b b a a a a or b a or b a or b 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pins 50 and 51. 3. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 39. 4. measure pin 43 picture period amplitude, v43r. 5. repeat the steps 3 and 4 above with the following pins: input from pin 38, and measure pin 42. input from pin 37 and measure pin 41. (v42g and v41b) 6. calculate the following equations. g osdr = v43r/0.2 g osdg = v42g/0.2 g osdb = v41b/0.2 t28 analog osd input white peak slice level a b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pins 50 and 51. 3. input signal 2 from pin 39. gradually increase picture amplitude, and measure picture period amplitude voltage when output from pin 43 is clipped. 4. repeat the step 3 above with the following pins: input from pin 38, and measure pin 42. input from pin 37, and measure pin 41. t29 analog osd black peak limit level a b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pins 50 and 51. 3. input signal 2 from pin 39. gradually decrease picture amplitude, and measure picture period amplitude voltage when output from pin 43 is clipped. 4. repeat the step 3 above with the following pins: input from pin 38, and measure pin 42. input from pin 37, and measure pin 41.
TA1360ANG 2003-01-21 88 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t30 osd contrast adjustment characteristic a b b a a a a or b a or b a or b 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pins 50 and 51. 3. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 39. 4. change osd contrast data to (11), (10), (01), and (00). measure pin 43 picture period amplitude v uosdr (11), (10), (01), and (00) respectively. 5. repeat the steps 3 and 4 above with the following pins: input from pin 38, and measure pin 42, v uosdg (11), (10), (01), and (00). input from pin 37, and measure pin 41, vuosdb (11), (10), (01), and (00). t31 analog osd brightness adjustment characteristic c b b a a a a a a 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. apply 5-v external voltage to pins 50 and 51. 3. change osd brightness data (subaddress 1d) to (38), (78), (b8), and (f8), and measure picture period voltage of pins 43, 42, and 41 respectively. data (38) = v brosd0 data (78) = v brosd1 data (b8) = v brosd2 data (f8) = v brosd3 t32 analog osd mode switching transfer characteristic c b b a a a a a a 1. set osd brightness data to maximum (11). 2. input signal 4 (signal amplitude = 4.5 vp-p) from pin 50. 3. measure input/output transfer characteristics using pin 43 according to the figure t-2. 4. repeat the steps 2 and 3 above, and measure pins 42 and 41. 5. calculate maximum inter-axial rise/fall transfer delay time, using the data measured above. 6. repeat the steps 1 to 5 above with the following pin. input signal 4 (signal amplitude 4.5 vp-p) from pin 51.
TA1360ANG 2003-01-21 89 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t33 osd acl characteristic a b b a a a a a b 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. control drive gain adjustment data so that pins 41 and 42 picture period amplitude equals that of pin 43. 2. set subaddress (07) data to (01). 3. apply 5-v external voltage to pins 50 and 51. 4. input signal 1 (f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 39. 5. measure pin 43 picture period amplitude, vosdacl1. 6. apply ?pin 53 dc voltage ? 0.8 v? to pin 53 from external power supply, and measure pin 43-picture period amplitude, vosdacl2. 7. apply ?pin 53 dc voltage ? 1.3 v? to pin 53 from external power supply, and measure pin 43-picture period amplitude, vosdacl3. 8. osdacl 1 = ? 20 og l (vosdacl2/vosdacl1) osdacl 2 = ? 20 og l (vosdacl3/vosdacl1) 9. osdacl3 �z osdacl4 change subaddress (07) data to (80), and repeat the steps 6 to 8 above to measure osdacl3 and osdacl4.
TA1360ANG 2003-01-21 90 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t34 osd blending characteristic a c b b a a a a b a b b b 1. input signal 1(f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pin 3. 2. measure pins 41, 42, and 43 picture period amplitude, v41a, v42a, and v43a. 3. apply 5-v external voltage to pin 51. 4. measure pins 41, 42, and 43 picture period amplitude, v41b, v42b, and v43b. 5. calculate v41b amplitude in relation to v41a, v42b amplitude in relation to v42a, and v43b amplitude in relation to v43a in decibel: 41tv1, 42tv1, and 43tv1. 6. apply 5-v external voltage to pin 50, and repeat the steps 3 to 5 above: 41tv2, 42tv2, and 43tv2. 7. apply 5-v external voltage to pins 50 and 51, and repeat the steps 3 to 5 above: 41tv3, 42tv3, and 43tv3. 8. set sw3 to c. set sw37, 38, and 39 to b. 9. input signal 1 (f 0 = 100 khz, picture period amplitude = 0.2 vp-p) from pins 37, 38, and 39. 10. apply 5-v external voltage to pins 50 and 51. 11. measure pins 41, 42, and 43 picture period amplitude, v41c, v42c, and v43c. 12. apply 5-v external voltage to pin 50. 13. measure pins 41, 42, and 43 picture period amplitude, v41d, v42d, and v43d. 14. calculate v41d amplitude in relation to v41c, v42d amplitude in relation to v42c, and v43d amplitude in relation to v43c in decibel: 41osd1, 42osd1, and 43osd1. 15. apply 5-v external voltage to pin 51, and repeat the steps 12 to 14 above: 41osd2, 42osd2, and 43osd2. 16. apply 5-v external voltage to pins 50 and 51, and repeat the steps 12 to 14 above: 41osd3, 42osd3, and 43osd3.
TA1360ANG 2003-01-21 91 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t35 blue stretch point/gain a b b a a a a a a 1. input ramp signal 0.7 vp-p from pin 3. 2. set subcontrast data to maximum. 3. set subaddress (15) data to (0c). 4. set subaddress (1a) data to (c0), monitor pin 41, and measure blue stretch start point using the figure below (blp min ). 5. set subaddress (1a) data to (cc), and repeat the step 4 above. (blp max ) 6. set subaddress (1a) data to (c4). 7. monitor pin 41 and measure gradient at blue stretch on in decibel in relation to the one at blue stretch off according to the figure below. (blg max ) 8. set subaddress (15) data to (04), and repeat the step 7 above. (blg min ) note: calculate blue stretch start point in ire as setting positive amplitude at pedestal level of output signal to 2.3 vp-p = 100 ire. blue stretch on blue stretch off output amplitude input amplitude
TA1360ANG 2003-01-21 92 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t36 blue stretch gamma correction a b b a a a a a a 1. input ramp signal 0.7 vp-p from pin 3. 2. set subcontrast data to maximum. 3. set subaddress (15) data to (08). 4. set subaddress (09) data to (81). 5. monitor pin 41 and measure amplitude of the intersection point of blue stretch off and blue stretch on according to the figure below. calculate pin 41 output amplitude in ire as setting positive amplitude at pedestal level of output signal to 2.3 vp-p = 100 ire. 6. set subaddress (1a) data to (c4), (c8), and (cc). repeat the step 5 above. (bl 2, bl 3, and bl 4) blue stretch off blue stretch on output amplitude input amplitude intersection poiint bl
TA1360ANG 2003-01-21 93 test conditions sw mode note no. characteristics sw3 sw4 sw5 sw33 sw34 sw35 sw37 sw38 sw39 test method t37 white letters improvement a b b a a a a a a 1. apply a pulse to pin 3 as shown in figure a. 2. monitor # 43 output waveform. plot # 43 output amplitude when changing # 3 input signal amplitude from 0 to 120 ire (0.857 vp-p) (see figure b below). 3. set subaddress (19) data to (80). 4. monitor # 43 output waveform. plot # 43 output amplitude when changing # 3 input signal amplitude from 0 to 120 ire (0.857 vp-p). then, compare to the plot in the step 2, calculate a point where a gradient changes (wpl1). 5. repeat the step 4 above by changing subaddress (19) data to (83) and (86). calculate points where gradients change (wpl2, wpl3). figure a 80 ns # 43 output amplitude data 87 data 86 data 83 data 80 figure b # 3 input amplitude wpl2 wpl3 wpl1
TA1360ANG 2003-01-21 94 test condition for synchronization block common test conditions for synchronization block: unless otherwise specified, v cc = = = = 9 v, ta = = = = 25c, bus data; preset value, sw3 = = = = a, sw14 = = = = a, sw input = = = = b, sw20 = = = = on, sw22 = = = = open, sw23 = = = = b, sw24a = = = = b, sw24b = = = = open, sw26 = = = = b note characteristics test conditions ha01 sync input horizontal sync phase 1. input signal a (as shown in the figure below) to tpa. set subaddress (00) data to 82h. 2. monitor # 14 (sync input) and #20 (afc filter) waveforms. measure phase difference (s ph ). ha02 hd input horizontal sync phase 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp 16. 3. monitor # 16 (sync input) and #20 (afc filter) waveforms. measure phase difference (hd ph ). 29.36 s 0.285 v 0.593 s signal a #20 waveform s ph 31.75 s 1.5 v 2.35 s signal b #20 waveform hd ph
TA1360ANG 2003-01-21 95 note characteristics test conditions ha03 polarity detection range 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp16 pin. 3. decrease signal b duty from 10% (to shorter negative polarity period) and measure signal b duty (hd duty1 ) when #16 input signal phase no longer locks with that of #26 (h-out). 4. increase signal b duty from 10% (to longer negative polarity period) and measure signal b duty (hd duty2 ) when #24 (fbp input) phase changes in relation to signal b. 5. further increase signal b duty (to longer negative polarity period) and measure signal b duty (hd duty3 ) when #16 input signal phase no longer locks with that of #26 (h-out). 6. decrease signal b duty from 90 % (to shorter negative polarity period) and measure signal b duty (hd duty4 ) when #24 (fbp input) phase changes in relation to signal b. duty = a/b 100% (0 to 100%) ha04 sync input threshold amplitude 1. set subaddress (00) data to 82h, and test mode to 01. 2. connect variable power supply to #14 via 20-k ? resistor. 3. set variable power supply voltage to 0 v, and measure #14 voltage. (sync_tip_00) also check that #28 voltage is set to low (gnd level). 4. increase variable power supply voltage so that #28 voltage becomes high (vcc level). measure #14 voltage. (sync_off_00) 5. calculate the following equation to determine sync input separation level at sync separation level is 00. v ths00 = (sync_off_00 ? sync_tip_00)/0.286 100 6. change sync separation level to 01, 10, and 11. calculate following equations to determine vths01, vths10, and vths11. v ths01 = (sync_off_01 ? sync_tip_01)/0.286 100 v ths10 = (sync_off_10 ? sync_tip_10)/0.286 100 v ths11 = (sync_off_11 ? sync_tip_11)/0.286 100 31.75 s 1.5 v signal b a b sync separation level 0.08h 40ire ( = 286 mvp-p) � 14 1h sync tip level � 28 (sync output mode �
TA1360ANG 2003-01-21 96 note characteristics test conditions ha05 hd input threshold amplitude 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp 16. 3. increase signal b amplitude from 0 vp-p. when #26 (h-out) phase locks with that of signal b, measure signal b amplitude v thhd . ha06 horizontal picture phase adjustment variable range 1. set subaddress (00) data to 40h. 2. input signal b (the figure is shown below) to tp16. 3. change subaddress (01) data from 80h to 00h, and measure phase change amount ? h sft ? of #24 (h-out) waveform. 4. change slave address (01) data from 80h to feh, and measure phase change amount ? h sft + of #24 (h-out) waveform. 31.75 s v thdh 2.35 s signal b 31.75 s 1.5 v 2.35 s signal b #24 waveform data: 00h ? h sft ? ? h sft + #24 waveform data: feh #24 waveform data: 80h
TA1360ANG 2003-01-21 97 note characteristics test conditions ha07 curve correction amount 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp16. 3. connect external voltage to #23 (curve correction), and measure phase change amount ( ? h#23) of #26 (h-out) output waveform at 1.5 v and 3.5 v. ha08 clamp pulse phase, width and level 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp16. 3. measure #18 (scp output) clamp pulse phase (cp s0 ), width (cp pw0 ), and output level (cp v0 ) in relation to signal b. 4. set subaddress (01) data to 81h, and repeat the step 3 above to measure (cp s1 ), (cp w1 ), and (cp v1 ). 5. apply no signal input to tp16. 6. measure #18 clamp pulse phase (cp s2 ), width (cp w2 ), and output level (cp v2 ) in relation to #24. 31.75 s 1.5 v 2.35 s signal b #26 waveform (#23 voltage; 1.5 v) ? h#23 #26 waveform (#23 voltage; 3.5 v) 31.75 s 1.5 v 2.35 s signal b #18 waveform #24 waveform cp v0/1 cp w0/1 cp s0/1 #18 waveform cp v2 cp w2 cp s2
TA1360ANG 2003-01-21 98 note characteristics test conditions ha09 black peak detection pulse phase and level 1. set subaddress (00) data to 40h. 2. set sw2 to c, sw3 to c, and sw24a to open 3. input signal c (as the figure shown below) to #24 (fbp input). 4. measure #2 (bph filter) black peak detection pulse phase (hbp s00a and hbp s00b ) in relation to signal c. 5. set hbp-phs 1/2 to (01), (10), and (11). measure black peak detection pulse phase. ha10 fbp input threshold 1. set subaddress (00) data to 40h. 2. input signal b (as shown in the figure below) to tp16. 3. increase amplitude of fbp signal to be input to #24 (fbp input) from 0 vp-p. when #26 (h-out) phase locks with that of signal b, measure #24 input amplitude v thfbp . 31.75 s 1.5 v 2.35 s 31.5 s 2 v 0 v signal c #2 waveform 4.13 s hbp s ** b hbp s ** a
TA1360ANG 2003-01-21 99 note characteristics test conditions hb01 h-out pulse duty 1. no signal input. 2. measure t1 and t2 (as shown in the figure below) from #26 (h-out) output waveform when subaddress (00) data is 80h and a0h. calculate duties (th a and th b ) using the following equation: th = t1/(t1 + t2) 100 % hb02 horizontal free-run frequency 1. set sw20 to open. 2. set subaddress (00) data to 01h and measure horizontal free-run frequency (f15k) according to #26 (h-out) output waveform. 3. set subaddress (00) data to 00h, 41h, 81h, c0h, and c1h. measure horizontal free-run frequency f28k, f31k, f33k, f37k, and f45k as in the step 2 above. hb03 horizontal oscillation frequency variable range 1. set subaddress (00) data to 01h. 2. connect 10-k ? resistor between #20 and v cc . measure horizontal frequency (f15k min ) according to #26 (h-out) output waveform. 3. connect 68-k ? resistor between #20 and gnd. measure horizontal frequency (f15k max ) according to #26 (h-out) output waveform. 4. set subaddress (00) data to 00h, 41h, 81h, c0h, and c1h. repeat the steps 2 and 3 above and measure horizontal frequencies f28k min , f28k max , f31k min , f31k max , f33k min , f33k max , f37k min , f37k max , f45k min , and f45k max . hb04 horizontal oscillation control sensitivity 1. set sw20 to open. 2. connect external power supply to tp 20, and set subaddress (00) data to 01h. 3. apply v 20 + 0.05 v, and v 20 ? 0.05 v to tp 20. measure frequencies fa and fb according to #26 (h-out) output waveform. calculate frequency change rate (bh15k) using the following equation. bh15k = (fb ? fa)/0.1 4. set subaddress (00) data to 00h, 41h, 81h, c0h, and c1h. repeat the step 2 above, and measure frequency change rate bh28k, bh31k, bh33k, bh37k, and bh45k hb05 h-out output voltage 1. set sw26 to open. 2. measure voltage at high (v26 h ) and low (v26 l ) of #26 (h-out) output waveform. #26 waveform t1 t2
TA1360ANG 2003-01-21 100 note characteristics test conditions v01 vp output pulse width, vertical free-run (maximum pull-in range) 1. input signal d (shown in the figure below) to tp 16, and signal e (shown in the figure below) to #24 (fbp input). 2. measure vp output pulse width (vpw) according to tp 27 output waveform. 3. measure vp pull-in range (vpt0) according to tp 27 output waveform. 4. set subaddress (03) data to 01h, 02h, 03h, 04h, 05h, and 06h. measure pull-in range vpt1, vpt2, vpt3, vpt4, vpt5, and vpt6 as in the step 3 above. v02 vertical minimum pull-in range 1. repeat the step 1 of note# v01. 2. input signal f (shown in the figure below) to tp 15. 3. increase signal-f cycle from 30h. measure the cycle (t vpull ) when phase locks with that of tp 27. signal f (tp 15 waveform input) t vpull 3h #24 input waveform tp 27 waveform #24 input waveform vpt tp 27 waveform vpw signal e (#24 input waveform) 9 v gnd 5.6 s signal d (tp 16 input signal) 4 v 2.35 s 29.63 s
TA1360ANG 2003-01-21 101 note characteristics test conditions v03 vertical black peak detection pulse 1. repeat the step 1 of note# v01. set sw2 to c, and sw3 to c. 2. input signal f (shown in the figure below) to tp 15. 3. measure phase differences vbpp 0e and vbpp 0s according to #2 output waveform. 4. set subaddress (03) data to 01h, 02h, 03h, 04h, 05h, and 06h. measure phase differences vbpp 1e , vbpp 1s , vbpp 2e , vbpp 2s , vbpp 3e , vbpp 3s , vbpp 4e , vbpp 4s , vbpp 5e , vbpp 5s , vbpp 6e , and vbpp 6s as in the step 3 above. v04 vertical blanking stop phase 1. repeat the step 1 of note# v01. 2. input signal f (shown in the figure below) to tp 15. 3. set subaddress (03) data to 00h and f0h. measure blanking stop phase vblk min and vblk max according to #43 output waveform. signal f (tp 15 waveform input) 1125h 3h #24 input waveform #24 input vblk signal f (tp 15 waveform input) 262.5h to 1125h 3h vbpp e vbpp s #24 input waveform #2 waveform
TA1360ANG 2003-01-21 102 figure t-1 signals for text/color difference signal 2 sine wave of frequency f 0 (2) input signal 1 amplitude a (3) input signal 2 (4) input signal 3 sine wave of frequency f 0 63.5 s (1) video signal
TA1360ANG 2003-01-21 103 figure t-2 test pulses for text/color difference signal 2 63.5 s 20 s 20 s 20 s 20 ns 20 ns 50% 0% 10% 50% 90% t p r t pf r f t p r t pf r f 0% 10% 50% 90% 100% 100% (1) input signal 4 (2) (3)
TA1360ANG 2003-01-21 104 test circuit a b c 2 k ? tpd 3.9 k ? 30 k ? 100 f 0.01 f sw4 0.1 f 10 k ? v cc (9 v) #49 #50 #51 #52 apl filte r y/c v cc vsm out abcl in y m /p-mute/bl k y s 1 (analog osd) dark area det filter bph filter y1 in c b1 /p b1 in c r1 /p r1 in y/c gnd light area det filter y s 2 (analog osd) y2 in c b2 /p b2 in c r2 /p r2 in color limiter vsm filter h-freqsw1 sync in vd in hd in scp in cp out def/dac v cc afc filter hvco h-freq sw2 h curve correction fbp in def/dac gnd h-out vp out dac1 (sync out) y s 3 (analog rgb) r s/h g s/h b s/h i k in rgb gnd r out g out b out rgb v cc analog osd r in analog osd g in analog osd b in dac2 (acb pulse) analog r in analog g in analog b in i 2 l gnd sda scl i 2 l v dd 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 TA1360ANG 0.01 f 0.01 f 2.0 v #56 #40 10 k ? 100 f 0.01 f #54 #53 sw56 sw54 1 k ? 100 k ? tp31 0.01 f #48 0.01 f #47 0.01 f #46 #45 10 k ? 10 k ? 6.8 v 300 pf #43 100 ? 10 k ? #42 100 ? 10 k ? #41 100 ? 10 k ? 0.1 f #39 tp39 sw39 a b 0.1 f #38 tp38 sw38 a b 0.1 f #37 tp37 sw37 a b #36 470 ? 9 v 0.1 f #35 tp35 sw35 a b 0.1 f #34 tp34 sw34 a b 0.1 f #33 tp33 sw33 a b #31 470 ? #30 tp30 1/2w 220 ? #29 0.1 f #55 0.47 f 0.01 f 470 ? led #1 sw2 #2 #3 #4 sw1 tp1 tp4 a b a b #5 tp5 sw5 a b #7 sw7 a b #8 sw8 a b 0.1 f 0.1 f 0.1 f #9 sw9 a b 0.1 f #10 sw10 a b 0.1 f tp9 tp10 #11 #12 100 ? tp13 #13 100 ? tp15 #15 100 ? tp16 #16 100 ? tp17 #17 100 ? tp18 #18 1 k ? tp27 #27 30 k ? #28 #14 tp14a 0.1 f tp14b a b sw20 #20 tp20 1 k ? 3 k ? 10 f 1 f 0.01 f #21 tp21 csbla503keczf30 470 ? #22 2 k ? 5.1 k ? 75 ? tpc tpb 3.9 k ? 2 k ? 5.1 k ? 75 ? tpa 10 f 10 f a b sw input sw3 0.1 f 20 k ? 100 k ? a b c 1 f 20 k ? 30 pf 1 f #23 sw23 a b tp23b 1 f tp23a 100 ? 10 k ? #24 3.9 k ? #26 10 k ? sw24b v cc (9 v) 5.1 k ? 16 15 14 13 12 11 10 9 1 2 3 4 5 6 7 8 tc4538bp 1200 pf 50 k ? 7.5 k ? 1000 pf 5.1 k ? 50 k ? 51 k ? 51 k ? 16 15 14 13 12 11 10 9 1 2 3 4 5 6 7 8 tc4538bp 1200 pf 50 k ? 7.5 k ? 1000 pf 5.1 k ? 50 k ? 51 k ? 51 k ? 16 15 14 13 12 11 10 9 1 2 3 4 5 6 7 8 tc4538bp 1200 pf 50 k ? 7.5 k ? 1000 pf 5.1 k ? 50 k ? 51 k ? 51 k ? sw24a sw26 a c b a c b 15.75 kh z 31.5/33.75 khz 45 kh z 10 f 10 f 10 f 2.2 f 100 f 10 k ? 0.1 f 15 k ? 15 k ? 15 k ? sw14 0.47 f tp7 tp53 tp54
TA1360ANG 2003-01-21 105 application circuit �h m : mylar capacito r application of h-freq switching (31.5 k/33.75 k/45 khz) tr. h-freq a b pin 13 voltage pin 22 voltage 31.5 khz l l 9 v 6 v 33.75 khz l h 9 v 3 v 45 khz h * 9 v 0 v * : dont care �h m �h m �h m �h m �h m �h m �h m 10 k ? 100 k ? 470 ? csbla503keczf30 470 ? v cc scl vd-in hd-in scp-in cp-out curve cor r fbp-in h-out vp-out sda v cc analog b-in analog g-in analog r-in dac2-out osd b-in osd g-in osd r-in b-out g-out r-out ys3 ys2 ys1 ym abcl vsm-out apl filte r y/c v cc vsm out abcl in y m /p-mute/bl k y s 1 (analog osd) dark area det filter bph filter y1 in c b1 /p b1 in c r1 /p r1 in y/c gnd light area det filter y s 2 (analog osd) y2 in c b2 /p b2 in c r2 /p r2 in color limiter vsm filter h-freq sw1 sync in vd in hd in scp in cp out def/dac v cc afc filter hvco h-freq sw2 h curve correction fbp in def/dac gnd h-out vp out dac1 (sync out) y s 3 (analog rgb) r s/h g s/h b s/h i k in rgb gnd r out g out b out rgb v cc analog osd r in analog osd g in analog osd b in dac2 (acb pluse) analog r in analog g in analog b in i 2 l gnd sda scl i 2 l v dd 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 TA1360ANG 0.1 f 0.1 f 0.47 f 0.1 f 1 f 0.1 f 0.1 f 0.1 f 0.1 f 2.2 f 1 k ? 3.9 k ? 5.1 k ? 75 ? y2-in y1-in cb/ pb2-in cr/pr2-in cr/pr1-in cb/pb1-in 1 k ? 75 ? 1 k ? 10 f 75 ? 1 k ? 3.9 k ? 5.1 k ? 75 ? 10 f 10 f 10 f 1 k ? 10 f 75 ? 1 k ? 10 f 75 ? 1 k ? 3.9 k ? 5.1 k ? 75 ? sync-in 10 f 3 k ? 100 f 0.01 f 1 f 1 k ? 470 ? 0.01 f 0.1 f 0.1 f 0.1 f 0.1 f 0.1 f 0.1 f 2.2 f 2.2 f 2.2 f 2.2 f 100 f 0.01 f 0.01 f 30 k ? 0.01 f 100 ? 100 ? ik in 2.0 v 30 k ? 300 pf 100 f 0.01 f 6.8 v 100 ? 47 h 47 h 47 h 1 k ? a 560 ? b 1.5 k ? 0.1 f 0.47 f 0.01 f 30 k ? dac1-out
TA1360ANG 2003-01-21 106 acb application circuit 45 crt b crt g crt r 20~51 k ? 51~330 pf 6.8 v z + b r g b 1 v p-p 0~3.0 v (dc) clamp i k in
TA1360ANG 2003-01-21 107 package dimensions weight: 5.55 g (typ.)
TA1360ANG 2003-01-21 108 ? toshiba is continually working to improve the quality and reliability of its products. nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. it is the responsibility of the buyer, when utilizing toshiba products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such toshiba products could cause loss of human life, bodily injury or damage to property. in developing your designs, please ensure that toshiba products are used within specified operating ranges as set forth in the most recent toshiba products specifications. also, please keep in mind the precautions and conditions set forth in the ?handling guide for semiconductor devices,? or ?toshiba semiconductor reliability handbook? etc.. ? the toshiba products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.). these toshiba products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (?unintended usage?). unintended usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc.. unintended usage of toshiba products listed in this document shall be made at the customer?s own risk. ? the products described in this document are subject to the foreign exchange and foreign trade laws. ? the information contained herein is presented only as a guide for the applications of our products. no responsibility is assumed by toshiba corporation for any infringements of intellectual property or other rights of the third parties which may result from its use. no license is granted by implication or otherwise under any intellectual property or other rights of toshiba corporation or others. ? the information contained herein is subject to change without notice. 000707eb a restrictions on product use
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