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data sheet the information in this document is subject to change without notice. before using this document, please confirm that this is the latest version. not all devices/types available in every country. please check with local nec representative for availability and additional information. bipolar analog integrated circuit m m m m pc3206gr 50db agc amp + video amp document no. p13710ej3v0ds00 (3rd edition) date published october 1999 n cp(k) printed in japan data sheet the mark shows major revised points. 1998, 1999 description the m pc3206gr is silicon monolithic ic designed for digital dbs and digital catv receivers. this ic consists of a two stage gain control amplifier and a wideband linear video amplifier. this ic is packaged in 20-pin ssop. therefore, it can make rf block small. features ? broadband agc dynamic range 50 db (min.) ? supply voltage 5 v ? packaged in 20-pin ssop suitable for high-density surface mount applications ? digital dbs receiver ? stb of digital catv ordering information part number package supplying form m pc3206gr-e1 20-pin plastic ssop (225 mil) embossed tape 12 mm wide. pin 1 indicates pull-out direction of tape. qty 2.5 kp/reel. to order evaluation samples, please contact your local nec office. (part number for sample order : m pc3206gr) caution electro-static sensitive device
data sheet p13710ej3v0ds00 2 m m m m pc3206gr hpf saw 1st if rf in pc2799gr m pc1686gv m pc3206gr m dual pll saw a/d qam demo. &fec lpf 2nd if video amp. internal block diagram and pin configulation (top view) 1 agc amp1 agc amp2 video amp agc gnd1 20 agc out1 2 agc in1 19 agc in2 3 v agc 18 agc v cc 1 4 agc v cc 1 17 agc out2 5 bpcap 16 agc gnd2 6 bpcap 15 ina 7 g1a 14 inb 8 g1b 13 vamp v cc 2 9 vamp gnd1 12 vamp out1 10 vamp gnd2 11 vamp out2 typical application
data sheet p13710ej3v0ds00 3 m m m m pc3206gr pin functions pin no. pin name pin voltage typ.(v) function and explanation equivalent circuit 1agc gnd1 0 ground pin of agc amplifier1. form a ground pattern as wide as possible to maintain the minimum impedance. 1.02 2 agc in 1 note 1 1.02 signal input pin to agc amplifier. 4 agc control 6 2 5 3 vagc 0 to 5 gain control pin. this pins bias govern the agc output level. minimum gain at v agc = 0 v maximum gain at v agc = 5 v recommended to use by dividing agc voltage with externally resistor (ex.100 k w ). 4agc v cc 1 5 power supply pin of agc amplifier1. must be connected bypass capacitor to minimize ground impedance. agc control 3 4 2.61 5 bpcap4 note 1 2.61 2.84 6 bpcap2 note 1 2.49 bypass pin of agc amplifier1 and 2. refer to equivalent circuit of pin1 and pin2. 1.72 7 g1a note 2 3.34 1.72 8 g1b note 2 3.34 gain control pin of video amplifier. maximum gain at g1a C g1b = short. minimum gain at g1a C g1b = open. gain is able to adjust by inserting arbitrary resistor between 7pin and 8pin. refer to equivalent circuit of pin14 and pin15. 9 vamp gnd1 0 10 vamp gnd2 0 ground pin of video amplifier. form a ground pattern as wide as possible to maintain the minimum impedance. 2.52 11 vamp out2 note 2 4.92 2.52 12 vamp out1 note 2 4.92 signal output pin of video amplifier. in case of r l = 1 k w , single-end output voltage equal 2v p-p . 13 12 11 reg notes 1. above : v agc = v cc 1 below : v agc = 0 v 2. above : v cc 2 = 5 v below : v cc 2 = 9 v
data sheet p13710ej3v0ds00 4 m m m m pc3206gr pin no. pin name pin voltage typ.(v) function and explanation equivalent circuit 13 vamp v cc 2 5 to 9 power supply pin of video amplifier. must be connected bypass capacitor to minimize ground impedance. 2.49 14 inb note 2 4.13 2.49 15 ina note 2 4.13 signal input pin to video amplifier. reg 7 8 13 15 14 16 agc gnd2 0 ground pin of agc amplifier2. form a ground pattern as wide as possible to maintain the minimum impedance. 1.69 17 agc out2 note 1 3.31 signal output pin of agc amplifier2. 18 17 18 agc v cc 1 5 power supply pin of agc amplifier2. must be connected bypass capacitor to minimize ground impedance. 1.01 19 agc in2 note 1 1.01 signal input pin of agc amplifier2. 18 agc control 6 19 5 1.71 20 agc out1 note 1 3.35 signal output pin of agc amplifier1. 4 20 notes 1. above : v agc = v cc 1 below : v agc = 0 v 2. above : v cc 2 = 5 v below : v cc 2 = 9 v
data sheet p13710ej3v0ds00 5 m m m m pc3206gr absolute maximum ratings (t a = 25 c unless otherwise specified) parameter symbol conditions rating unit supply voltage 1 v cc 1 mixer block 6.0 v supply voltage 2 v cc 2 video amp block 6.0 v agc control voltage v agc 6.0 v maximum input power p in (max.) +10 dbm power dissipation p d t a = 85 c note 433 mw operating ambient temperature t a C40 to +85 c storage temperature t stg C55 to +150 c parameter symbol conditions rating unit supply voltage 1 v cc 1 mixer block 6.0 v supply voltage 2 v cc 2 video amp block 11.0 v agc control voltage v agc 6.0 v maximum input power p in (max.) +10 dbm power dissipation p d t a = 75 c note 500 mw operating ambient temperature t a C40 to +75 c storage temperature t stg C55 to +150 c note mounted on 50 50 1.6 mm double epoxy glass board. recommended operating range parameter symbol min. typ. max. unit supply voltage 1 v cc 1 4.5 5.0 5.5 v supply voltage 2 v cc 2 4.5 9.0 10.0 v operating ambient temperature 1 note 1 t a 1 C40 +25 +85 c operating ambient temperature 2 note 2 t a 2 C40 +25 +75 c notes 1. v cc 1 = v cc 2 = 4.5 to 5.5 v 2. v cc 1 = 4.5 to 5.5 v, v cc 2 = 4.5 to 10 v
data sheet p13710ej3v0ds00 6 m m m m pc3206gr electrical characteristics (t a = 25 c) parameter symbol test conditions min. typ. max. unit agc amplifier block (v cc 1 = 5 v, fin = 100 mhz, r l = 560 w ) circuit current 1 i cc 1 no input signal, v agc = 5 v note 1 11 16 22 ma circuit current 2 i cc 2 no input signal, v agc = 0 v note 1 15 22 32 ma bandwidth 1 bw1 maximum gain (v agc = 5 v), pin = C60 dbm note 2, 3 100 220 C mhz bandwidth 2 bw2 minimum gain (v agc = 0 v), pin = C15 dbm note 3 500 C C mhz maximum gain 1 g max 1 pin = C60 dbm, v agc = 5 v note 3 36 38.5 41 db minimum gain 1 g min 2 pin = C15 dbm, v agc = 0 v note 3 C C28 C15 db gain control range gcr pin = C35 dbm , v agc = 0 to 5v note 3 50 C C db maximum output power p o (sat) v agc = 5 v, pin = 0 dbm note 3 02Cdbm video amplifier block (v cc 2 = 9 v, fin = 100 mhz, r l = 1 k w ) circuit current 3 i cc 3 no input signal note 4 16 24 34.5 ma differential gain 1 g1 g1a-g1b pins:short note 5 160 260 400 v/v differential gain 2 g2 g1a-g1b pins:open note 5 22 25 30 v/v video amplifier block (v cc 2 = 5 v, fin = 100 mhz, r l = 1 k w ) circuit current 4 i cc 4 no input signal note 4 8 12.5 18 ma differential gain 3 g3 g1a-g1b pins:short note 5 80 140 230 v/v differential gain 4 g4 g1a-g1b pins:open note 5 16 22 30 v/v video amplifier block (v cc 2 = 5 v, 9 v common, fin = 100 mhz, r l = 1 k w , single-ended) bandwidth 1 bw g1 g1a-g1b pins:short note 2, 5 C 100 C mhz notes 1. by measurement circuit 1 2. C3 db down from gain at 5 mhz 3. by measurement circuit 2 4. by measurement circuit 3 5. by measurement circuit 4
data sheet p13710ej3v0ds00 7 m m m m pc3206gr standard characteristics (for reference) (t a = 25 c) parameter symbol test conditions reference values unit agc amplifier block (v cc 1 = 5 v, fin = 100 mhz, r l = 560 w ) noise figure nf maximum gain (v agc = 5 v) note 1 5.5 db output intercept point oip 3 fin2 = 106 mhz, maximum gain (v agc = 5 v) note 2 +4.5 dbm video amplifier block (v cc 2 = 9 v, fin = 100 mhz, r l = 1 k w ) output voltage vout single-ended note 3 2v p-p single-end gain 1 avs1 g1a-g1b pins:short note 3 130 v/v single-end gain 2 avs2 g1a-g1b pins:open note 3 12 v/v input intercept point 1 iip 3 1 fin2 = 106 mhz, g1a-g1b pins:short note 3 C16 dbm input intercept point 2 iip 3 2 fin2 = 106 mhz, g1a-g1b pins:open note 3 4dbm video amplifier block (v cc 2 = 5 v, fin = 100 mhz, r l = 1 k w ) single-end gain 3 avs3 g1a-g1b pins:short note 3 70 v/v single-end gain 4 avs4 g1a-g1b pins:open note 3 11 v/v input intercept point 3 iip 3 3 fin2 = 106 mhz, g1a-g1b pins:short note 3 C15 dbm input intercept point 4 iip 3 4 fin2 = 106 mhz, g1a-g1b pins:open note 3 2dbm total block (v cc 1 = 5 v, fin = 100 mhz, r l = 1 k w ) maximum gain 2 g max 2 v agc = 5 v, v cc 2 = 5 v, g1a-g1b pins:short note 4 76 db maximum gain 3 g max 3 v agc = 5 v, v cc 2 = 5 v, g1a-g1b pins:open note 4 62 db minimum gain 2 g min 2 v agc = 0 v, v cc 2 = 5 v, g1a-g1b pins:short note 4 10 db maximum gain 4 g max 4 v agc = 5 v, v cc 2 = 9 v, g1a-g1b pins:short note 4 80 db maximum gain 5 g max 5 v agc = 5 v, v cc 2 = 9 v, g1a-g1b pins:open note 4 63 db minimum gain 3 g min 3 v agc = 0 v, v cc 2 = 9 v, g1a-g1b pins:short note 4 14 db notes 1. by measurement circuit 5 2. by measurement circuit 2 3. by measurement circuit 4 4. by measurement circuit 6
data sheet p13710ej3v0ds00 8 m m m m pc3206gr typical characteristics (t a = 25 c) 40 35 30 25 20 15 10 5 0 024 supply voltage v cc (v) circuit current i cc (ma) circuit current vs. supply voltage 6 8 10 12 no input signal measurement circuit1, 3 50 40 30 20 10 0 - 10 - 20 - 30 012 agc voltage v agc (v) gain (db) gain vs. agc voltage 3456 f in = 100 mhz r l = 560 w measurement circuit2 v cc 1 = 4.5 v v cc 1 = 5.0 v v cc 1 = 5.5 v 25 20 15 10 5 0 0 100 200 input frequency f in (mhz) gain (50 w /560 w ) (db) gain vs. input frequency 300 400 500 v cc 1 = v agc = 5 v p in = - 60 dbm measurement circuit2 note1 0 - 10 - 20 - 30 - 40 - 50 - 60 - 50 - 40 input power p in (dbm) output power p out (50 w /560 w ) (dbm) output power vs. input power - 30 - 20 - 10 0 - 20 - 30 - 40 - 50 - 60 0 100 200 input frequency f in (mhz) gain (50 w /560 w ) (db) gain vs. input frequency 300 400 500 v cc 1 = 5 v v agc = 0 v p in = - 15 dbm measurement circuit2 note1 v agc = v cc 1 f in = 100 mhz r l = 560 w measurement circuit2 note2 notes 1. 2. gain = (gain at spectrum analyzer) + 20 log (560 w /50 w ) output power = (output power at spectrum analyzer) + 10 log (560 w /50 w ) v cc 1 = 4.5 v v cc 1 = 5.0 v v cc 1 = 5.5 v - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 35 - 25 - 15 input power p in (dbm) output power p out (50 w /560 w ) (dbm) output power vs. input power - 515 5 v agc = 0 v f in = 100 mhz r l = 560 w measurement circuit2 note2 v cc 1 = 4.5 v v cc 1 = 5.0 v v cc 1 = 5.5 v agc (v agc = 0 v) video amp. agc (v agc = v cc 1)
data sheet p13710ej3v0ds00 9 m m m m pc3206gr typical characteristics (t a = 25 c) 450 400 350 300 250 200 150 100 50 0 0 50 100 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 150 200 250 f in = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit4 v cc 2 = 8 v v cc 2 = 9 v v cc 2 = 10 v 40 35 30 25 20 15 10 5 0 0 50 100 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 150 200 250 f in = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit4 v cc 2 = 8 v v cc 2 = 9 v v cc 2 = 10 v 250 200 150 100 50 0 0 50 100 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 150 200 250 f in = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit4 v cc 2 = 4.5 v v cc 2 = 5.0 v v cc 2 = 5.5 v 40 35 30 25 20 15 10 5 0 0 50 100 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 150 200 250 f in = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit4 v cc 2 = 4.5 v v cc 2 = 5.0 v v cc 2 = 5.5 v 0 - 5 - 10 - 15 - 20 - 25 - 30 - 35 - 40 - 50 - 40 - 30 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) output power vs. input power - 20 - 10 0 f in = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit4 note 0 - 10 - 20 - 30 - 40 - 50 - 60 - 50 - 40 - 30 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) output power vs. input power - 20 - 10 0 10 f in = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit4 note note output power = (output power at spectrum analyzer) + 10 log (1 k w /50 w ) v cc 2 = 9 v v cc 2 = 5 v v cc 2 = 9 v v cc 2 = 5 v
data sheet p13710ej3v0ds00 10 m m m m pc3206gr standard characteristics (t a = 25 c) 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 60 - 40 input power p in (dbm) output power p out (50 w /560 w ) (dbm) output power vs. input power - 20 0 20 v cc 1 = 5 v f in = 100 mhz r l = 560 w measurement circuit2 note 0 - 20 - 40 - 60 - 80 - 100 - 50 - 45 input power p in (dbm) output power p out (50 w /560 w ) (dbm) 3rd order intermodulation distortion - 40 - 35 - 30 - 25 ?0 v cc 1 = v agc = 5 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 560 w measurement circuit2 note 10 9 8 7 6 5 4 3 2 1 0 10 100 input frequency f in (mhz) noise figure nf (db) noise figure vs. input frequency 1000 v agc = v cc 1 r l = 560 w measurement circuit5 v cc 1 = 4.5 v v cc 1 = 5.0 v v cc 1 = 5.5 v note output power = (output power at spectrum analyzer) + 10 log (560 w /50 w ) v agc = 5 v v agc = 2.8 v v agc = 2 v v agc = 0 v v agc = 3.25 v
data sheet p13710ej3v0ds00 11 m m m m pc3206gr standard characteristics (t a = 25 c) 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 50 - 40 - 30 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 20 - 10 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 25 - 20 - 15 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 10 - 50 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 50 - 40 - 30 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 20 - 10 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 25 - 20 - 15 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 10 - 50 v cc 2 = 9 v f in = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = short measurement circuit4 note v cc 2 = 9 v f in = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = open measurement circuit4 note v cc 2 = 5 v f in = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = short measurement circuit4 note v cc 2 = 5 v f in = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = open measurement circuit4 note note output power = (output power at spectrum analyzer) + 10 log (1 k w /50 w )
data sheet p13710ej3v0ds00 12 m m m m pc3206gr standard characteristics (t a = 25 c) 100 80 60 40 20 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6 70 60 50 40 30 20 10 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 9 v v agc = 3 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6 100 80 60 40 20 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6 70 60 50 40 30 20 10 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 5 v v agc = 3 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6 25 20 15 10 5 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 9 v v agc = 0 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6 25 20 15 10 5 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 5 v v agc = 0 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit6
data sheet p13710ej3v0ds00 13 m m m m pc3206gr standard characteristics (t a = 25 c) 80 60 40 20 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit6 40 30 20 10 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 9 v v agc = 3 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit6 80 60 40 20 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit6 40 30 20 10 0 0 100 input frequency f in (mhz) gain (db) gain vs. input frequency 200 300 400 500 v cc 1 = 5 v v cc 2 = 5 v v agc = 3 v f in 1 = 100 mhz r l = 1 k w g1a-g1b = open measurement circuit6
data sheet p13710ej3v0ds00 14 m m m m pc3206gr standard characteristics (t a = 25 c) 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 65 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 60 - 55 - 50 0 - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 65 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 60 - 55 - 50 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = short measurement circuit6 note v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = short measurement circuit6 note 0 - 20 - 40 - 60 - 80 - 15 - 10 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 50 5 v cc 1 = 5 v v cc 2 = 9 v v agc = 0 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = short measurement circuit6 note 0 - 20 - 40 - 60 - 80 - 60 - 50 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 40 - 30 v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = open measurement circuit6 note 0 - 20 - 40 - 60 - 80 - 60 - 50 input power p in (dbm) output power p out (50 w /1 k w ) (dbm) 3rd order intermodulation distortion - 40 - 30 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v f in 1 = 100 mhz f in 2 = 106 mhz r l = 1 k w g1a-g1b = open measurement circuit6 note note output power = (output power at spectrum analyzer) + 10 log (1 k w /50 w )
data sheet p13710ej3v0ds00 15 m m m m pc3206gr standard characteristics (t a = 25 c) 10 9 8 7 6 5 4 3 2 1 0 10 100 input frequency f in (mhz) noise figure nf (db) noise figure vs. input frequency 1000 10 9 8 7 6 5 4 3 2 1 0 10 100 input frequency f in (mhz) noise figure nf (db) noise figure vs. input frequency 1000 10 9 8 7 6 5 4 3 2 1 0 10 100 input frequency f in (mhz) noise figure nf (db) noise figure vs. input frequency 1000 10 9 8 7 6 5 4 3 2 1 0 10 100 input frequency f in (mhz) noise figure nf (db) noise figure vs. input frequency 1000 v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v r l = 1 k w g1a-g1b = short measurement circuit7 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v r l = 1 k w g1a-g1b = short measurement circuit7 v cc 1 = 5 v v cc 2 = 9 v v agc = 5 v r l = 1 k w g1a-g1b = open measurement circuit7 v cc 1 = 5 v v cc 2 = 5 v v agc = 5 v r l = 1 k w g1a-g1b = open measurement circuit7
data sheet p13710ej3v0ds00 16 m m m m pc3206gr input impedance (2 pin) marker z in 1 45 mhz 938.4 w C j604.8 w 2 100 mhz 434.7 w C j573.8 w 3 250 mhz 122.5 w C j324.9 w start 0.045000000 ghz stop 0.250000000 ghz 1 3 2 conditions t a = 25c v cc 1 = 5 v output impedance (20 pin) marker z out 1 45 mhz 19.86 w + 3.83 w 2 100 mhz 20.28 w + 9.26 w 3 250 mhz 22.28 w + 22.48 w start 0.045000000 ghz stop 0.250000000 ghz 2 1 3 conditions t a = 25c v cc 1 = 5 v
data sheet p13710ej3v0ds00 17 m m m m pc3206gr input impedance (19 pin) marker z in 1 45 mhz 965.8 w C j601.2 w 2 100 mhz 446.6 w C j661.8 w 3 250 mhz 126.8 w C j312.4 w start 0.045000000 ghz stop 0.250000000 ghz 1 3 2 conditions t a = 25c v cc 1 = 5 v output impedance (17 pin) marker z out 1 45 mhz 10.32 w + j2.88 w 2 100 mhz 10.86 w + j6.42 w 3 250 mhz 12.67 w + j15.39 w start 0.045000000 ghz stop 0.250000000 ghz 2 1 3 conditions t a = 25c v cc 1 = 5 v
data sheet p13710ej3v0ds00 18 m m m m pc3206gr input impedance (15 pin) (i) t a = 25c, v cc 2 = 5 v marker z in 1 45 mhz 840.0 w C j2560 w 2 100 mhz 50.19 w C j1259 w 3 250 mhz 52.03 w C j475.6 w start 0.045000000 ghz stop 0.250000000 ghz 1 3 2 (ii) t a = 25c, v cc 2 = 9 v marker z in 1 45 mhz 478.3 w C j3091 w 2 100 mhz 106.13 w C j1368 w 3 250 mhz 55.11 w C j501.3 w start 0.045000000 ghz stop 0.250000000 ghz 1 3 2
data sheet p13710ej3v0ds00 19 m m m m pc3206gr output impedance (12 pin) (i) t a = 25c, v cc 2 = 5 v, 11 pin is grounded through 50 w w w w resistor. marker z out 1 45 mhz 9.88 w + j6.25 w 2 100 mhz 14.21 w + j11.78 w 3 250 mhz 23.64 w + j15.73 w start 0.045000000 ghz stop 0.250000000 ghz 2 1 3 (ii) t a = 25c, v cc 2 = 9 v, 11 pin is grounded through 50 w w w w resistor. marker z out 1 45 mhz 7.36 w + j4.85 w 2 100 mhz 10.50 w + j9.58 w 3 250 mhz 19.37 w + j13.70 w start 0.045000000 ghz stop 0.250000000 ghz 2 1 3
data sheet p13710ej3v0ds00 20 m m m m pc3206gr thermal characteristics (for reference) 30 25 20 15 10 5 0 - 50 - 25 0 25 50 75 ambient temperature t a ( c) circuit current i cc (ma) circuit current vs. ambient temperature (agc block) 100 no input signal v cc 1 = 5 v measurement circuit1 30 25 20 15 10 5 0 - 50 - 25 0 25 50 75 ambient temperature t a ( c) circuit current i cc (ma) circuit current vs. ambient temperature (video amp block) 100 no input signal measurement circuit3 0 - 10 - 20 - 30 - 40 - 50 - 60 - 50 - 40 - 30 - 20 - 10 input power p in (dbm) output power p out (50 w /560 w ) (dbm) output power vs. input power 0 v cc 1 = 5 v v agc = v cc 1 f in = 100 mhz r l = 560 w measurement circuit2 note t a = - 40 c t a = +25 c t a = +85 c - 10 - 20 - 30 - 40 - 50 - 60 - 70 - 80 - 90 - 35 - 25 - 15 - 55 input power p in (dbm) output power p out (50 w /560 w ) (dbm) output power vs. input power 15 v cc 1 = 5 v v agc = 0 v f in = 100 mhz r l = 560 w measurement circuit2 note t a = - 40 c t a = +25 c t a = +85 c note output power = (output power at spectrum analyzer) + 10 log (560 w /50 w ) v agc = 0 v v agc = 5 v v cc 2 = 9 v v cc 2 = 5 v
data sheet p13710ej3v0ds00 21 m m m m pc3206gr thermal characteristics (for reference) 450 400 350 300 250 200 150 100 50 0 0 50 100 150 200 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 250 v cc 2 = 9 v f in = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit4 t a = - 40 c t a = +25 c t a = +85 c 50 40 30 20 10 0 - 10 - 20 - 30 012345 agc voltage v agc (v) gain (db) gain vs. agc voltage 6 v cc 1 = 5 v f in = 100 mhz r l = 560 w measurement circuit2 t a = - 40 c t a = +25 c t a = +85 c 250 200 150 100 50 0 0 50 100 150 200 input frequency f in (mhz) differential gain g video (v/v) differential gain vs. input frequency 250 v cc 2 = 5 v f in = 100 mhz r l = 1 k w g1a-g1b = short measurement circuit4 t a = - 40 c t a = +25 c t a = +85 c
data sheet p13710ej3v0ds00 22 m m m m pc3206gr measurement circuit 1 1 agc amp1 agc amp2 video amp 20 2 in v agc 1 f 100 k 100 k m 19 318 417 516 615 714 813 912 10 11 v cc 1 1 f 0.022 f m 0.1 f m 0.1 f m m 0.022 f m 0.022 f m 0.1 f m 0.022 f m v cc 1 1 f 200 4700pf 0.1 f mm 0.1 f agc out m 510 measurement circuit 2 1 agc amp1 agc amp2 video amp 20 2 v agc 1 f 100 k note 100 k m 19 318 417 516 615 714 813 912 10 11 v cc 1 1 f 0.022 f m 0.1 f m 0.1 f m m 0.022 f m 0.022 f m 0.1 f m 0.022 f m v cc 1 1 f 200 510 4700pf 0.1 f mm 0.1 f m spectrum analyzer (50 w ) sg1 (50 w ) mixpad sg2 (50 w ) note in the case of measurement of im 3
data sheet p13710ej3v0ds00 23 m m m m pc3206gr measurement circuit 3 in1 51 1 agc amp1 agc amp2 video amp 20 219 318 417 516 615 714 813 912 10 11 0.022 f 950 open /short m 0.022 f 1000pf m 0.1 f m out1 v cc 2 0.022 f 950 m out2 measurement circuit 4 51 1 agc amp1 agc amp2 video amp 20 219 318 417 516 615 714 813 912 10 11 0.022 f 950 open /short m 0.022 f 1000pf m 0.1 f m v cc 2 0.022 f 1 k m note sg1 (50 w ) mixpad sg2 (50 w ) spectrum analyzer (50 w ) note in the case of measurement of im 3
data sheet p13710ej3v0ds00 24 m m m m pc3206gr measurement circuit 5 1 agc amp1 agc amp2 video amp 20 2 v agc 1 f 100 k 100 k m 19 318 417 516 615 714 813 912 10 11 v cc 1 1 f 0.022 f m 0.1 f m 0.1 f m m 0.022 f m 0.022 f m 0.1 f m 0.022 f m v cc 1 1 f 200 4700pf 0.1 f mm 0.1 f m noise source nf meter 510 measurement circuit 6 1 agc amp1 agc amp2 video amp 20 2 v agc 1 f 100 k 100 k m 19 318 417 516 615 714 813 912 10 11 v cc 1 1 f 0.022 f m 0.1 f m 0.1 f m m 0.022 f m 0.022 f m 0.1 f m 0.022 f open /short m v cc 1 1 f 200 510 4700pf 0.1 f mm 0.1 f m v cc 2 0.022 f 1000pf m 0.022 f 1 k m 0.022 f 950 m spectrum analyzer (50 w ) sg1 (50 w )
data sheet p13710ej3v0ds00 25 m m m m pc3206gr measurement circuit 7 1 agc amp1 agc amp2 video amp 20 2 v agc 1 f 100 k 100 k m 19 318 417 516 615 714 813 912 10 11 v cc 1 1 f 0.022 f m 0.1 f m 0.1 f m m 0.022 f m 0.022 f m 0.1 f m 0.022 f open /short m v cc 1 1 f 200 510 4700pf 0.1 f mm 0.1 f m v cc 2 0.022 f 1000pf m 0.022 f 1 k m 0.022 f 950 m nf meter noise source
data sheet p13710ej3v0ds00 26 m m m m pc3206gr illustration of the evaluation board for measurement circuit6 agc in agc out vdeo in vdeo out vdeo out vcc vcc vcc nec pc3206 fxtr vagc m m 0.022 m 0.1 m 0.1 m 0.1 m 0.1 m 1 m 0.022 m 0.022 m 0.022 m 0.022 m 0.022 m 0.022 m 0.1 m 1f m 1f 950 950 short/open 100 k 200 100 k 4700 p 510 1000 p notes on evaluation board (1) gnd pattern on rear side (2) : through hole (3) : represents cutout
data sheet p13710ej3v0ds00 27 m m m m pc3206gr package dimensions 20 pin plastic ssop (225 mil) (unit: mm) 20 detail of lead end 1.8 max. 3 +7 C3 0.65 0.10 m 0.15 0.5 0.2 11 110 6.7 0.3 1.5 0.1 0.1 0.1 0.22 +0.10 C0.05 0.575 max. 0.15 +0.10 C0.05 6.4 0.2 4.4 0.1 1.0 0.2 note each lead centerline is located within 0.10 mm of its true position (t.p.) at maximum material condition.
data sheet p13710ej3v0ds00 28 m m m m pc3206gr note on correct use (1) observe precautions for handling because of electro-static sensitive devices. (2) form a ground pattern as wide as possible to minimize ground impedance (to prevent undesires osillation). (3) keep the track length of the ground pins as short as possible. (4) a low pass filter must be attached to v cc line. (5) a matching circuit must be externally attached to output port. recommended soldering conditions this product should be soldered under the following recommended conditions. for soldering methods and conditions other than those recommended below, contact your nec sales representative. soldering method soldering conditions recommended condition symbol infrared reflow package peak temperature: 235c or below time: 30 seconds or less (at 210c) count: 3, exposure limit note : none ir35-00-3 vps package peak temperature: 215c or below time: 40 seconds or less (at 200c) count: 3, exposure limit note : none vp15-00-3 partial heating pin temperature: 300c time: 3 seconds or less (per side of device) exposure limit note : none C note after opening the dry pack, keep it in a place below 25c and 65% rh for the allowable storage period. caution do not use different soldering methods together (except for partial heating). for details of the recommended soldering conditions for surface mounting, refer to information document semiconductor device mounting technology manual (c10535e) .
data sheet p13710ej3v0ds00 29 m m m m pc3206gr [memo]
data sheet p13710ej3v0ds00 30 m m m m pc3206gr [memo]
data sheet p13710ej3v0ds00 31 m m m m pc3206gr [memo]
m m m m pc3206gr the information in this document is subject to change without notice. before using this document, please confirm that this is the latest version. ? no part of this document may be copied or reproduced in any form or by any means without the prior written consent of nec corporation. nec corporation assumes no responsibility for any errors which may appear in this document. ? nec corporation does not assume any liability for infringement of patents, copyrights or other intellectual property rights of third parties by or arising from use of a device described herein or any other liability arising from use of such device. no license, either express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of nec corporation or others. ? descriptions of circuits, software, and other related information in this document are provided for illustrative purposes in semiconductor product operation and application examples. the incorporation of these circuits, software, and information in the design of the customer's equipment shall be done under the full responsibility of the customer. nec corporation assumes no responsibility for any losses incurred by the customer or third parties arising from the use of these circuits, software, and information. ? while nec corporation has been making continuous effort to enhance the reliability of its semiconductor devices, the possibility of defects cannot be eliminated entirely. to minimize risks of damage or injury to persons or property arising from a defect in an nec semiconductor device, customers must incorporate sufficient safety measures in its design, such as redundancy, fire-containment, and anti-failure features. ? nec devices are classified into the following three quality grades: "standard", "special", and "specific". the specific quality grade applies only to devices developed based on a customer designated "quality assurance program" for a specific application. the recommended applications of a device depend on its quality grade, as indicated below. customers must check the quality grade of each device before using it in a particular application. standard: computers, office equipment, communications equipment, test and measurement equipment, audio and visual equipment, home electronic appliances, machine tools, personal electronic equipment and industrial robots special: transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster systems, anti-crime systems, safety equipment and medical equipment (not specifically designed for life support) specific: aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life support systems or medical equipment for life support, etc. the quality grade of nec devices is "standard" unless otherwise specified in nec's data sheets or data books. if customers intend to use nec devices for applications other than those specified for standard quality grade, they should contact an nec sales representative in advance. m7 98. 8

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