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| ta1287pg,TA1287FG 2004-08-03 1 toshiba bipolar linear integrated circuit silicon monolithic ta1287pg,TA1287FG rgb to yuv / iq high-speed matrix ic ta1287pg, TA1287FG are a high-speed switching ic which have 2-channel inputs circuit and a rgb to yuv / iq matrix circuit. another feature, ta1287pg, TA1287FG have a signals mixing circuit, which are enable to mix a main signal with an external input signal and outputs the mixed signal. the mixing circuit has 8 combinations of mixing gain ratio of a main to an external signals, which is controlled by high-speed switch. features rgb to yuv / iq matrix circuit the mixing circuit for a main signal and an external signal the high-speed switching circuit of a main signal an external signal band width : 30mhz at ? 3db point. ta1287pg TA1287FG weight dip16-p-300-2.54a: 1.0 g (typ.) ssop16-p-225-1.00a: 0.14 g (typ.)
ta1287pg,TA1287FG 2004-08-03 2 block diagram ta1287pg,TA1287FG 2004-08-03 3 terminal functions pin no. pin name function interface circuit input / output signal 1 v in input r-y (v) or r signal through a clamping capacitor. 2 y in input y or g signal through a clamping capacitor. 3 u in input b-y (u) or b signal through a clamping capacitor. dc : 6.2 v y : 1 v p-p (with sync) u / v : 0.3 v p-p (b : c = 1 : 1) r / g / b : 0.7 v p-p (100% white) 4 cp in input clamping pulse. threshold : 0.75 v 5 gnd gnd. D D 6 r in input r or r-y (v) signal through clamping capacitor. 7 g in input g or y signal through a clamping capacitor. 8 b in input b or b-y (u) signal through a clamping capacitor. dc : 6.2 v y : 1v p-p (with sync) u / v : 0.3 v p-p (b : c = 1 : 1) r / g / b : 0.7 v p-p (100% white) ta1287pg,TA1287FG 2004-08-03 4 pin no pin name function interface circuit input / output signal 9 10 11 ys1,2, 3 selector to switch mixing ratios. threshold : 0.75 v 12 v cc supply 9 v. D dc : 9 v 13 v out outputs r-y (v) or r signal. 14 y out outputs y or g signal. 15 u out outputs b-y (u) or b signal. dc : 4.7 v y : 1 v p-p (with sync) u / v : 0.3 v p-p (b : c = 1 : 1) r / g / b : 0.7 v p-p (100% color bar) 16 matrix control this terminal?s voltage control the matrix coefficient for output signals.selects the output mode. ta1287pg,TA1287FG 2004-08-03 5 function description mixing ratio ta1287pg, TA1287FG have a circuit, which mixes a main signal with an external input signal and outputs the mixed signal. the mixing circuit has 8 combinations of mixing gain ratio of a main to an external signals. table the mixing ratio of external to main (tv) the mixing ratio ys1 ys2 ys3 external main (tv) l l l 0 1 h l l 0.3 0.7 l h l 0.4 0.6 h h l 0.5 0.5 l l h 0.6 0.4 h l h 0.7 0.3 l h h 0.8 0.2 h h h 1 0 matrix control pin 16 is a high-speed switch to control the matrix mode for output signals. table matrix mode depending on by the voltage of pin 16 voltage of pin 16 [v] mode 0 ~ 0.7 through ~ 2.3 rgb to yuv (pal) ~ 3.8 rgb to yuv (ntsc) 3.8 ~ rgb to yiq ta1287pg,TA1287FG 2004-08-03 6 maximum ratings (ta = 25c) characteristic symbol rating unit supply voltage v ccmax 12 v input pin voltage v in gnd ? 0.3 to v cc + 0.3 v ta1287pg p dd (note 1) 1400 power consumption TA1287FG p df (note 1) 641 mw ta1287pg 1 / jad ? 11.2 mw / c power consumption reduction ratio TA1287FG 1 / jaf ? 5.13 mw / c operating temperature t opr ? 20~65 c storage temperature t stg ? 55~150 c note 1: refer to the figure below. note 2: it is possible that TA1287FG function faultily caused by leak problems according to a field intensity from crt. put ic lay-out position to crt be far more than 20 cm. if there is not a enough distance, intercept it by a shield. fig. power consumption reduction against ambient temperature ta1287pg,TA1287FG 2004-08-03 7 operating conditions characteristic description min typ. max unit supply voltage pin 12 8.1 9.0 9.9 v y input signal level white : 100% with sync. D 1.0 D v p-p u input signal level b : c = 1 : 1 D 300 D mv p-p v input signal level b : c = 1 : 1 D 300 D mv p-p r input signal level 100% white D 700 D mv p-p g input signal level 100% white D 700 D mv p-p b input signal level 100% white D 700 D mv p-p cp input level pin 4 1.1 1.5 5.0 v ys1, ys2, ys3, input level pin 9, 10, 11 1.1 1.5 5.0 v electrical characteristics (v cc = 9v and ta = 25c, unless otherwise specified) current consumption pin name symbol testcircuit min typ. max unit v cc i cc D 20.0 26.0 32.0 ma terminal voltages pin no. pin name symbol test circuit min typ. max unit 1 v in v 1 D 6.0 6.2 6.4 2 y in v 2 D 6.0 6.2 6.4 3 u in v 3 D 6.0 6.2 6.4 6 r in v 6 D 6.0 6.2 6.4 7 g in v 7 D 6.0 6.2 6.4 8 b in v 8 D 6.0 6.2 6.4 13 v out v 13 D 4.5 4.7 4.9 14 y out v 14 D 4.5 4.7 4.9 15 u out v 15 D 4.5 4.7 4.9 v ta1287pg,TA1287FG 2004-08-03 8 ac characteristics characteristic symbol test cir- cuit test condition min typ. max unit yuv gain (through mode) gtry gty gtby D (note a 1 ) ? 0.5 ? 0.5 ? 0.5 0 0 0 0.5 0.5 0.5 db rgb gain (through mode) grr grg grb D (note a 2) ? 0.5 ? 0.5 ? 0. 5 0 0 0 0.5 0.5 0.5 db r gain (input to pin 6) (matrix mode) grryp gryp grbyp grryn gryn grbyn grryi gryi grbyi D (note a 3 ) ? 4.7 ? 10.3 ? 17.3 ? 4.3 ? 10.3 ? 18.4 ? 4.6 ? 10.3 ? 13.0 ? 4.2 ? 9.8 ? 16.8 ? 3.8 ? 9.8 ? 17.9 ? 4.1 ? 9.8 ? 12.5 ? 3.7 ? 9.3 ? 16.3 ? 3.3 ? 9.3 ? 17.4 ? 3.6 ? 9.6 ? 12.0 db g gain (input to pin 7) (matrix mode) ggryp ggyp ggbyp ggryn ggyn ggbyn ggryi ggyi ggbyi D (note a 4 ) ? 6.3 ? 4.5 ? 11.5 ? 5.9 ? 4.5 ? 10.9 ? 11.5 ? 4.5 ? 5.6 ? 5.8 ? 4.0 ? 11.0 ? 5.4 ? 4.0 ? 10.4 ? 11.0 ? 4.0 ? 5.1 ? 5.3 ? 3.5 ? 10.5 ? 4.9 ? 3.5 ? 9.9 ? 10.5 ? 3.5 ? 4.6 db b gain (input to pin 8) (matrix mode) gbryp gbyp gbbyp gbryn gbyn gbbyn gbryi gbyi gbbyi D (note a 5 ) ? 21.1 ? 19.1 ? 7.7 ? 20.3 ? 19.1 ? 7.9 ? 10.2 ? 19.1 ? 10.7 ? 20.6 ? 18.6 ? 7.2 ? 19.8 ? 18.6 ? 7.4 ? 9.7 ? 18.6 ? 10.2 ? 20.1 ? 18.1 ? 6.7 ? 19.3 ? 18.1 ? 6.9 ? 9.2 ? 18.1 ? 9.7 db r-y gain (input to pin 1) (matrix mode) gtry73 gtry64 gtry55 gtry46 gtry37 gtry28 D (note a 6 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db ta1287pg,TA1287FG 2004-08-03 9 characteristic symbol test cir- cuit test condition min typ. max unit y gain (input to pin 2) (mixing mode) gty73 gty64 gty55 gty46 gty37 gty28 D (note a 7 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db b-y gain (input to pin 3) (mixing mode) gtby73 gtby64 gtby55 gtby46 gtby37 gtby28 D (note a 8 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db r gain (input to pin 6) (mixing mode) grr37 grr46 grr55 grr64 grr73 grr82 D (note a 9 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db g gain (input to pin 7) (mixing mode) grg37 grg46 grg55 grg64 grg73 grg82 D (note a 10 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db b gain (input to pin 8) (mixing mode) grb37 grb46 grb55 grb64 grb73 grb82 D (note a 11 ) ? 3.7 ? 5.0 ? 6.6 ? 8.5 ? 11.0 ? 14.3 ? 3.2 ? 4.5 ? 6.1 ? 8.0 ? 10.5 ? 13.8 ? 2.7 ? 4.0 ? 5.6 ? 7.5 ? 10.0 ? 13.3 db yuv input dynamic range (through mode) dtv dty dtu D (note a 12 )1.2 1.2 1.2 1.5 1.5 1.5 1.7 1.7 1.7 v p-p rgb input dynamic range (through mode) drr drg drb D (note a 13 )1.2 1.2 1.2 1.5 1.5 1.5 1.7 1.7 1.7 v p-p r input dynamic range (input to pin 6) (matrix mode) drp drnu drni D (note a 14 )1.2 1.2 1.2 1.5 1.5 1.5 1.7 1.7 1.7 v p-p g input dynamic range (input to pin 7) (matrix mode) dgp dgnu dgni D (note a 15 )1.2 1.2 1.2 1.5 1.5 1.5 1.7 1.7 1.7 v p-p ta1287pg,TA1287FG 2004-08-03 10 characteristic symbol test cir- cuit test condition min typ. max unit b input dynamic range (input to pin 8) (matrix mode) dbp dbnu dbni D (note a 16 )1.2 1.2 1.2 1.5 1.5 1.5 1.7 1.7 1.7 v p-p yuv input and output frequency characteristic (at ? 3 db point) (through mode) gftry gfty gftby D (note a 17 ) 30 30 30 D D D D D D mhz rgb input and output frequency characteristic (at ? 3 db point) (through mode) gfrr gfrg gfrb D (note a 18 ) 30 30 30 D D D D D D mhz ys switching delay time ysryr ysrry ysyg ysgy ysbyb ysbby D (note a 19 ) D D D D D D 25.0 20.0 25.0 20.0 25.0 20.0 40.0 40.0 40.0 40.0 40.0 40.0 ns crosstalk between each input D D (note a 20 ) D ? 50 ? 40 db ta1287pg,TA1287FG 2004-08-03 11 test condition test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method ta1287pg,TA1287FG 2004-08-03 12 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method 1) calculate gains against each item, in the same way as note a 1 . a a a b b a (pal) grryp : r-in (pin 6) to v-out (pin 13) gryp : r-in (pin 6) to y-out (pin 14) grbyp : r-in (pin 6) to u-out (pin 15) a b a (ntsc, uv) grryn : r-in (pin 6) to v-out (pin 13) gryn : r-in (pin 6) to y-out (pin 14) grbyn : r-in (pin 6) to u-out (pin 15) a 3 r gain (input to pin 6) (matrix mode) a a a (ntsc, iq) grryi : r-in (pin 6) to v-out (pin 13) gryi : r-in (pin 6) to y-out (pin 14) grbyi : r-in (pin 6) to u-out (pin 15) ta1287pg,TA1287FG 2004-08-03 13 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method 1) calculate gains against each item, in the same way as note a 1 . a a a b b a (pal) ggryp : g-in (pin 7) to v-out (pin 13) ggyp : g-in (pin 7) to y-out (pin 14) ggbyp : g-in (pin 7) to u-out (pin 15) a b a (ntsc, uv) ggryn : g-in (pin 7) to v-out (pin 13) ggyn : g-in (pin 7) to y-out (pin 14) ggbyn : g-in (pin 7) to u-out (pin 15) a 4 g gain (input to pin 7) (matrix mode) a a a (ntsc, iq) ggryi : g-in (pin 7) to v-out (pin 13) ggyi : g-in (pin 7) to y-out (pin 14) ggbyi : g-in (pin 7) to u-out (pin 15) ta1287pg,TA1287FG 2004-08-03 14 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method 1) calculate gains against each item, in the same way as note a 1 . a a a b b b (pal) ggryp : b-in (pin 8) to v-out (pin 13) ggyp : b-in (pin 8) to y-out (pin 14) ggbyp : b-in (pin 8) to u-out (pin 15) a b a (ntsc, uv) ggryn : b-in (pin 8) to v-out (pin 13) ggyn : b-in (pin 8) to y-out (pin 14) ggbyn : b-in (pin 8) to u-out (pin 15) a 5 b gain (input to pin 8) (matrix mode) a a a (ntsc, iq) ggryi : b-in (pin 8) to v-out (pin 13) ggyi : b-in (pin 8) to y-out (pin 14) ggbyi : b-in (pin 8) to u-out (pin 15) ta1287pg,TA1287FG 2004-08-03 15 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method a 6 r-y gain (input to pin 1) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) input signal into pin 4. 2) supply dc 0v to ys1 (pin 9), ys2 (pin 10), ys3 (pin 11). 3) input signal 2 (f 0 = 100 khz, v 0 = 0.2 v p-p ) into v-in (pin 1, sw 1 = a). 4) measure each amplitude of output signal from v-out (pin 13) in each sw mode. calculate the gains. a 7 y gain (input to pin 2) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) calculate gains of y-in (pin 2) to y-out (pin 14), in the same way as note a 6 . (sw 2 = a) a 8 b-y gain (input to pin 3) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) calculate gains of u-in (pin 3) to y-out (pin 15), in the same way as note a 6 . (sw 3 = a) a 9 r gain (input to pin 6) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) calculate gains of r-in (pin 6) to v-out (pin 13), in the same way as note a 6 . (sw 6 = a) a 10 g gain (input to pin 7) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) calculate gains of g-in (pin 7) to y-out (pin 14), in the same way as note a 6 . (sw 7 = a) ta1287pg,TA1287FG 2004-08-03 16 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method a 11 b gain (input to pin 8) (mixing mode) a b a b a b b a a b b a b b b a a a b b b 1) calculate gains of b-in (pin 8) to u-out (pin 15), in the same way as note a 6 . (sw 8 = a) a 12 yuv input dynamic range (through mode) b b b b b b 1) input signal into pin 4. 2) supply dc 0v to ys1 (pin 9), ys2 (pin 10), ys3 (pin 11). 3) input signal 2 (f 0 = 100 khz, v 0 = 0.2 v p-p ) into v-in (pin 1, sw 1 = a). 4) increase the amplitude of input-signal 2 gradually. measure the biggest amplitude of input-signal 2 without any distortion on v-out wave shape. (dtry) 5) measure in the same way as (pin 3) to (pin 4) for y-in (pin 2, sw 2 = a) and u-in (pin 3, sw 3 = a), dty : y-in (pin 2) to y-out (pin 14) dtby : u-in (pin 3) to u-out (pin 15) a 13 rgb input dynamic range (through mode) b b b b b b 1) measure in the same way as note a 12 for r-in (pin 6, sw 6 = a) g-in (pin 7, sw 7 = a) and b-in (pin 8, sw 8 = a). a 14 r input dynamic range (input to pin 6) (matrix mode) a a a b a a b b a a a a 1) for each combination of sw 16a, 16b and 16c , measure each item in the same way as 1) to 4) of note a 12 . (sw 6 = a, r-in (pin 6) to v-out (pin 13)) drp : pal drnu : ntsc, uv drni : ntsc, iq ta1287pg,TA1287FG 2004-08-03 17 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method a 15 g input dynamic range (input to pin 7) (matrix mode) a a a b a a b b a a a a 1) measure each item in the same way as note a 14 . (sw 7 = a, g-in (pin 7) to y-out (pin 14)) dgp : pal dgnu : ntsc, uv dgni : ntsc, iq a 16 b input dynamic range (input to pin 8) (matrix mode) a a a b a a b b a a a a 1) measure each item in the same way as note a 14 . (sw 8 = a, b-in (pin 8) to u-out (pin 15)) dbp : pal dbnu : ntsc, uv dbni : ntsc, iq a 17 yuv input and output frequency characteristic (at ? 3 db point) (through mode) b b b b b b 1) input signal 1 into pin 4. 2) supply dc 0v to ys1 (pin 9), ys2 (pin 10), ys3 (pin 11). 3) input signal 2 (f 0 = 30 mhz, v 0 = 0.2 v p-p ) into v-in (pin 1, sw 1 = a). 4) measure the amplitude during picture period on v-out (pin13). (v 13 -30 mhz) 5) calculate the frequency gain by using the following equation and v 13 , which is measured as the output amplitude in note a 1 . gftry = 20 og l (v 13 -30 mhz / v 13 ) 6) calculate following items, in the same way as clause 5). gfty : y-in (pin 2) to y-out (pin 14) gftby : u-in (pin 3) to u-out (pin 15) ta1287pg,TA1287FG 2004-08-03 18 test condition (unless otherwise specified, v cc = 9 v and ta = 25 3c) sw mode note item sw 9 sw 10 sw 11 sw 16a sw 16b sw 16c measuring method a 18 rgb input and output frequency characteristic (at ? 3 db point) (through mode) a a a b b b 1) in the same way as note a 17 , calculate items against r-in (pin 6, sw 6 = a), g-in (pin 7, sw 7 = a) and b-in (pin 8, sw 8 = a). gfrr : r-in (pin 6) to v-out (pin 13) gfrg : g-in (pin 7) to y-out (pin 14) gfrb : b-in (pin 8) to u-out (pin 15) a 19 ys switching delay time D D D b b b 1) input signal 1 into pin 4. 2) input signal 3 into r-in (pin 6, sw 6 = a). input signal 4 into ys1 (pin 9), ys2 (pin 10), ys3 (pin 11). 3) measure (i) and (ii) periods on v-out (pin 13). 4) measure in the same way as 2) to 3) for g-in (pin 7, sw 7 = a) and b-in (pin 8, sw 8 = a). r-in (i) : ysryr (ii) : ysryr g-in (i) : ysyg (ii) : ysyg b-in (i) : ysbyb (ii) : ysbby a 20 crosstalk between each input a or b a or b a or b b b b 1) input signal into pin 4. 2) supply dc 0v to ys1 (pin 9), ys2 (pin 10), ys3 (pin 11). 3) input signal 2 (f 0 = 4 mhz, v 0 = 0.5 v p-p ) into v-in (pin 1, sw 1 = a). 4) changing sw 9 , sw 10 , and sw 11 against each case, measure each leak levels. 5) calculate the gains, input level to leak level. ta1287pg,TA1287FG 2004-08-03 19 test signals signal 1 signal 2 signal 3 signal 4 output wave-form ta1287pg,TA1287FG 2004-08-03 20 test circuit ta1287pg,TA1287FG 2004-08-03 21 application circuit the mixing ratio table for external to tv ys1 ys2 ys3 ext : tv l l l 0 : 1 h l l 0.3 : 0.7 l h l 0.4 : 0.6 h h l 0.5 : 0.5 l l h 0.6 : 0.4 h l h 0.7 : 0.3 l h h 0.8 : 0.2 h h h 1 : 0 ta1287pg,TA1287FG 2004-08-03 22 package dimensions weight: 1.0g (typ.) ta1287pg,TA1287FG 2004-08-03 23 package dimensions weight: 0.14g (typ.) ta1287pg,TA1287FG 2004-08-03 24 ? the information contained herein is subject to change without notice. ? the information contained herein is presented only as a guide for the applications of our products. no responsibility is assumed by toshiba for any infringements of patents or other rights of the third parties which may result from its use. no license is granted by implication or otherwise under any patent or patent rights of toshiba or others. ? toshiba is continually working to improve the quality an d 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 malfuncti on 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. ? toshiba products should not be embedded to the downstream products which are prohibited to be produced and sold, under any law and regulations. 030619eba restrictions on product use about solderabilit y, following conditions were confirmed ? solderability (1) use of sn-63pb solder bath solder bath temperature = 230c dipping time = 5 seconds the number of times = once use of r-type flux (2) use of sn-3.0ag-0.5cu solder bath solder bath temperature = 245c dipping time = 5 seconds the number of times = once use of r-type flux |
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