View TUA6034-V_644904.PDF datasheet online --- IC-ON-LINE

Datasheet File OCR Text:

specification, v 2.5, april 2004 tua6034, tua6036 3-band digital tv / set-top-box tuner ic taifun version 2.5 wireless communication never stop thinking.
edition 2004-04-28 published by infineon technologies ag, st.-martin-strasse 53, 81669 mnchen, germany ? infineon technologies ag 2004. all rights reserved. attention please! the information herein is given to describe certain components and shall not be considered as a guarantee of characteristics. terms of delivery and rights to technical change reserved. we hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and charts stated herein. information for further information on technology, delivery terms and conditions and prices please contact your nearest infineon technologies office in germany or the infineon technologies companies and our infineon technologies representatives worldwide ( www.infineon.com ). warnings due to technical requirements components may contain dangerous substances. for information on the types in question please contact your n earest infineon technologies office. infineon technologies components may only be used in life-support devices or systems with the express written approval of infineon technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or system. life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. if they fail, it is reasonable to assume that the health of the user or other persons may be endangered.
specification, v 2.5, april 2004 tua6034, tua6036 3-band digital tv / set-top-box tuner ic taifun version 2.5 wireless communication never stop thinking.
tua6034, tua6036 revision history: 2004-04-28 v 2.5 page (in previous version) page (in current version) subjects (major changes since last revision) revision history: target spec. v1.1, january 2001 data sheet: target spec. v1.0, november 2000 div. div. in extended mode reference division ratio 80 replaced by 32 5-2 5-2 new definition of thermal properties revision history: current version:preliminary spec. v1.2, april 2001 data sheet: target spec. v1.1, january 2001 div. div. status: preliminary div. div. bug fixes: tssop and vqfn pinning. changes: application focus to digital applications, tbd?s replaced by values 5-10, 5-11 5-10, 5-11 phase noise values added 5-21 5-21 diagrams added revision history: current version:preliminary spec. v1.3, july 2001 data sheet: target spec. v1.2, april 2001 div. div stand-by mode added 5-5 5-5 crystal oscillator: input impedances added 5-7 5-7 output leakage current replaced by port output voltage symbol for port output saturation voltages changed 5-12 5-12 agc source current 2 and agc output voltage changed 5-15 5-15 definition for ma1= 0 and ma0 = 1 changed revision history: current version:preliminary spec. v1.4, october 2001 data sheet: target spec. v1.3, july 2001 3-5, 3-7 3-5, 3-7 pnp ports: pull-down resistors added 5-5 5-5 mid band: i vcc corrected 5-10, 5-11 5-10, 5-11 phase noise: new values 5-12 5-12 agc output voltage changed revision history: current version:preliminary spec. v2.0, may2002 data sheet: target spec. v1.4, october 2001 all all preliminary and confidential deleted
div div tbf?s replaced, isdb-t application deleted revision history: current version:preliminary spec. v2.1, august 2002 data sheet: target spec. v2.0, may 2002 5-6 5-6 bus output sda, low-level output voltage, i ol = 6 ma at 400 khz deleted revision history: current version:preliminary spec. v2.2, december 2002 data sheet: target spec. v2.1, august 2002 3-2 ff 3-2 ff pinning of TUA6034-V changed revision history: current version: v2.3, february 2003 data sheet: target spec. v2.2, december 2002 all all mirrored version tua6036 added revision history: current version v2.4, march 2003 data sheet: target spec. v2.3, february 2003 2-10, 4-29, 4-30 2-10, 4-29, 4-30 frequencies corrected 5-34 5-34 ambient temperature extended 5-38, 5-39, 5-40 5-38, 5-39, 5-40 input ip2,input iip3, output voltage causing 1 db compression added, test frequencies changed revision history: current version: v2.5, april 2004 data sheet: target spec. v2.4, march 2003 5-35 33 crystal oscillation frequency added div. div. TUA6034-V in vqfn-48 package n.a. 28 isdb-t application added all all new infineon template (a5 letter page size) tua6034, tua6036 revision history: 2004-04-28 v 2.5 we listen to your comments any information within this document that you feel is wrong, unclear or missing at all? your feedback will help us to continuously improve the quality of this document. please send your proposal (including a reference to this document) to: horst.klein@infineon.com
tua6034, tua6036 specification 6 v 2.5, 2004-04-28 product info general description the tua6034, tua6036 ?taifun? device combines a mixer-oscillator block with a digitally programmable phase locked loop (pll) for use in tv and vcr tuners and in set- top-box applications. ordering information type ordering code package tua6034-t q67034-h0009 tssop-38 tua6036-t q67037-a0012 tssop-38 TUA6034-V q67034-h0008 vqfn-48 features general suitable for pal, ntsc, dvb and atsc wideband agc detector for internal tuner agc ? 5 programmable take-over points ? 2 programmable time constants low phase noise full esd protection mixer/oscillator high impedance mixer input (common emitter) for low band low impedance mixer input (common base) for mid band low impedance mixer input (common base) for high band 2 pin oscillator for low band 2 pin oscillator for mid band 4 pin oscillator for high band if-amplifier symmetrical if preamplifier with low output impedance able to drive a compensated saw filter (500 ? //40pf) pll 4 independent i 2 c addresses i 2 c bus protocol compatible with 3.3 v and 5v micro-controllers up to 400 khz high voltage vco tuning output 4 pnp ports 1 npn port/adc input internal low/mid/high band switch stand-by mode lock-in flag 6 programmable reference divider ratios (24, 28, 32, 64, 80, 128) 4 programmable charge pump currents application the ic is suitable for pal, ntsc, dvb-c, dvb-t, isdb-t and atsc tuners. the focus is on digital terrestrial. the agc stage makes the tuner agc independent of the video-if agc.
tua6034, tua6036 table of contents page specification 7 v 2.5, 2004-04-28 1 product description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 1.1 features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 1.1.1 general . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 1.1.2 mixer/oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 1.1.3 if-amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 1.1.4 pll . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 1.2 application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 2 functional description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 2.1 pin configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 2.2 pin definition and functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 2.3 functional block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 2.4 circuit description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 2.4.1 mixer-oscillator block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 2.4.2 pll block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 2.4.3 agc . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 2.4.4 i2c-bus interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 3 applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 3.1 application circuit for atsc . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 3.2 application circuit for dvb-t . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 3.3 application circuit for isdb-t . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 4 reference . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 4.1 electrical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 4.1.1 absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 4.1.2 operating range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 4.1.3 ac/dc characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 4.2 programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 4.3 i2c bus timing diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 4.4 electrical diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 4.4.1 input admittance (s11) of the low band mixer (40 to 150 mhz) . . . . . 52 4.4.2 input impedance (s11) of the mid band mixer (150 to 455 mhz) . . . . . 52 4.4.3 input impedance (s11) of the high band mixer (450 to 865 mhz) . . . . 53 4.4.4 output admittance (s22) of the of the mixers (30 to 50 mhz) . . . . . . . . 53 4.4.5 input impedance (s11) of the if amplifier (30 to 50 mhz) . . . . . . . . . . . 54 4.4.6 output impedance (s22) of the if amplifier (30 to 50 mhz) . . . . . . . . . 54 4.5 measurement circuits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55 4.5.1 gain (gv) measurement in low band . . . . . . . . . . . . . . . . . . . . . . . . . 55 4.5.2 gain (gv) measurement in mid and high bands . . . . . . . . . . . . . . . . 55 4.5.3 matching circuit for optimum noise figure in low band . . . . . . . . . . . . 56 4.5.4 noise figure (nf) measurement in low band . . . . . . . . . . . . . . . . . . . 56 4.5.5 noise figure (nf) measurement in mid and high bands . . . . . . . . . . . 57 4.5.6 cross modulation measurement in low band . . . . . . . . . . . . . . . . . . . 57
specification 8 v 2.5, 2004-04-28 4.5.7 cross modulation measurement in mid and high bands . . . . . . . . . . . 58 4.5.8 ripple susceptibility measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58 5 package outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 5.1 tssop-38 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 5.2 vqfn-48 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
specification 9 v 2.5, 2004-04-28 tua6034, tua6036 product description 1 product description the tua6034, tua6036 ?taifun? device combines a mixer-oscillator block with a digitally programmable phase locked loop (pll) for use in tv and vcr tuners and in set- top-box applications. the mixer-oscillator block includes three balanced mixers (one mixer with an unbalanced high-impedance input and two mixers with a balanced low-impedance input), two 2-pin asymmetrical oscillators for the low and the mid band, one 4-pin symmetrical oscillator for the high band, an if amplifier, a reference voltage, and a band switch. the pll block with four independently selectable chip addresses forms a digitally programmable phase locked loop. with a 4 mhz quartz crystal, the pll permits precise setting of the frequency of the tuner oscillator up to 1024 mhz in increments of 31.25, 50, 62.5, 125, 142.86 or 166.7 khz. the tuning process is controlled by a microprocessor via an i 2 c bus. the device has 5 output ports, one of them (p4) can also be used as adc input port. a flag is set when the loop is locked. the lock flag can be read by the processor via the i 2 c bus. 1.1 features 1.1.1 general suitable for pal, ntsc, dvb, isdb-t and atsc wideband agc detector for internal tuner agc ? 5 programmable take-over points ? 2 programmable time constants low phase noise full esd protection 1.1.2 mixer/oscillator high impedance mixer input (common emitter) for low band low impedance mixer input (common base) for mid band low impedance mixer input (common base) for high band 2 pin oscillator for low band 2 pin oscillator for mid band 4 pin oscillator for high band 1.1.3 if-amplifier symmetrical if preamplifier with low output impedance able to drive a compensated saw filter (500 ? //40 pf)
tua6034, tua6036 product description specification 10 v 2.5, 2004-04-28 1.1.4 pll 4 independent i 2 c addresses i 2 c bus protocol compatible with 3.3 v and 5v micro-controllers up to 400 khz high voltage vco tuning output 4 pnp ports 1 npn port/adc input stand-by mode internal low/mid/high band switch lock-in flag 6 programmable reference divider ratios (24, 28, 32, 64, 80, 128) 4 programmable charge pump currents 1.2 application the ic is suitable for pal, ntsc, dvb-c, dvb-t, isdb-t and atsc tuners. the focus is on digital terrestrial. the agc stage makes the tuner agc independent of the video-if agc. recommended band limits in mhz: table 1 atsc tuners rf input oscillator band min max min max low 55.25 157.25 101 203 mid 163.25 451.25 201 479 high 457.25 861.25 503 907 table 2 dvb-t tuners rf input oscillator band min max min max low 48.25 154.25 87.15 193.15 mid 161.25 439.25 200.15 478.15 high 447.25 863.25 486.15 902.15
specification 11 v 2.5, 2004-04-28 tua6034, tua6036 product description note: tuning margin of 3 mhz not included. table 3 isdb-t tuners rf input oscillator band min max min max low 93 167 150 224 mid 173 467 230 524 high 473 767 530 824
tua6034, tua6036 functional description specification 12 v 2.5, 2004-04-28 2 functional description 2.1 pin configuration figure 1 pin configuration tua6034 in tssop-38 package highin highin lowin rfgnd mixout mixout p2 agc gnd sda scl as osclowout osclowin oscgnd oscmidin oscmidout oschighin oschighout oschighout oschighin vcc ifgnd ifout ifout pllgnd 1 2 3 4 5 6 7 8 9 10 11 12 13 14 38 37 36 35 34 33 32 31 30 29 28 27 26 25 tua6034-t tssop-38 package 15 16 17 18 24 23 22 21 vt cp p4/adc xtal p1 p0 p3 ifin 19 20 xtal ifin midin midin
specification 13 v 2.5, 2004-04-28 tua6034, tua6036 functional description figure 2 pin configuration tua6036 in tssop-38 package 1 2 3 4 5 6 7 8 9 10 11 12 13 14 38 37 36 35 34 33 32 31 30 29 28 27 26 25 tua6036-t tssop-38 package 15 16 17 18 24 23 22 21 19 20 highin highin lowin rfgnd mixout mixout p2 agc gnd sda scl as p1 p0 p3 ifin ifin midin midin osclowout osclowin oscgnd oscmidin oscmidout oschighin oschighout oschighout oschighin vcc ifgnd ifout ifout pllgnd vt cp p4/adc xtal xtal
tua6034, tua6036 functional description specification 14 v 2.5, 2004-04-28 figure 3 pin configuration tua6034 in vqfn-48 package TUA6034-V vqfn-48 package n.c. n.c. oschighin oschighout oschighout oschighin vcc ifgnd ifout ifout pllgnd vt 1 2 3 4 5 6 7 8 9 10 11 12 n.c. n.c. cp p4/adc n.c. xtal xtal p3 p0 p1 as n.c. 14 15 16 17 18 19 20 21 22 23 24 13 oscmidin oscgnd n.c. oscmidout n.c. highin highin midin midin lowin osclowin osclowout 48 47 46 45 44 43 42 41 40 39 38 37 mixout mixout n.c. rfgnd n.c. p2 agc gnd sda scl ifin ifin 36 35 34 33 32 31 30 29 28 27 26 25
specification 15 v 2.5, 2004-04-28 tua6034, tua6036 functional description 2.2 pin definition and functions table 4 pin defintion and functions pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 1/38 43 osclowout 2.1 v 2/37 44 osclowin 1.45 v 3/36 45 oscgnd oscillator ground 0.0 v 0.0 v 0.0 v 4/35 46 oscmidin 1.45 v 5/34 47 oscmidout 2.1 v 2 (44) 1 (43 ) 4 (46) 5 (47 )
tua6034, tua6036 functional description specification 16 v 2.5, 2004-04-28 6/33 3 oschighin 1.5 v 7/32 4 oschighout 2.4 v 8/31 5 oschighout 2.4 v 9/30 6 oschighin 1.5 v 10/ 29 7 vcc supply voltage 5.0 v 5.0 v 5.0 v 11/ 28 8 ifgnd if ground 0.0 v 0.0 v 0.0 v 12/ 27 9ifout 2.2 v 2.2 v 2.2 v 13/ 26 10 ifout 2.2 v 2.2 v 2.2 v 14/ 25 11 pllgnd pll ground 0.0 v 0.0 v 0.0 v 15/ 24 12 vt vt vt vt 16/ 23 15 cp 2.0 v 2.0 v 2.0 v pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 7 (4) 6 (3) 8 (5) 9 (6) 13 (10) 12 (9) 16 (15) 15 (12)
specification 17 v 2.5, 2004-04-28 tua6034, tua6036 functional description 17/ 22 16 p4/adc 5 v or v ce 5 v or v ce 5 v or v ce 18/ 21 18 xtal 1.7 v 1.7 v 1.7 v 19/ 20 19 xtal 1.7 v 1.7 v 1.7 v 20/ 19 20 p3 0 v or v cc - v ce 0 v or v cc - v ce 0 v or v cc - v ce 21/ 18 21 p0 v cc - v ce n.a. n.a. 22/ 17 22 p1 n.a. v cc - v ce n.a. pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 17 (16) 18 (18) 19 (19) 20 (20) or 21 (21) or 22 (22)
tua6034, tua6036 functional description specification 18 v 2.5, 2004-04-28 23/ 16 23 as n.a. n.a. n.a. 24/ 15 25 scl n.a. n.a. n.a. 25/ 14 26 sda n.a n.a n.a 26/ 13 27 gnd ground 0.0 0.0 0.0 pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 23 (23) 24 (25) 25 (26)
specification 19 v 2.5, 2004-04-28 tua6034, tua6036 functional description 27/ 12 28 agc 3.5 v 3.5 v 3.5 v 28/ 11 29 p2 n.a. n.a. 0 v or v cc - v ce 29/ 10 31 ifin n.a. n.a. n.a. 30/9 32 ifin n.a. n.a. n.a. 31/8 33 mixout 4.0 v 4.0 v 4.0 v 32/7 34 mixout 4.0 v 4.0 v 4.0 v 33/6 35 rfgnd rf ground 0.0 v 0.0 v 0.0 v pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 27 (28) 28 (29) 29 (31) 30 (32) oscillator 32 (34) 31 (33)
tua6034, tua6036 functional description specification 20 v 2.5, 2004-04-28 34/5 37 lowin 1.9 v 35/4 38 midin 0.75 v 36/3 39 midin 0.75 v 37/2 40 highin 0.75 v 38/1 41 highin 0.75 v pin no. symbol equivalent i/o schematic pin designation in parenthesis refer to vqfn-48 package average dc voltage tss op- 38 vq fn- 48 low mid high 34 (37) 35 (38) 36 (39) 37 (40) 38 (41)
specification 21 v 2.5, 2004-04-28 tua6034, tua6036 functional description 2.3 functional block diagram figure 4 block diagram tua6034 in tssop-38 package rf input high rf input low mixer high mixer low oscillator low oscillator mid oscillator high saw filter driver agc detector prog. divider crystal oscillator reference divider ports i 2 c bus lock detector adc p0 atc v cc agc f div f ref cp, os fl p1 p0 p0.p1 9 10 11 12 13 17 18 19 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 hi ghin hi ghin l ow in m ixout r fgnd m ixout rf input mid mixer mid m idin m idin p1 charge pump 14 15 16 phase/ freq comp 1 2 3 4 5 6 7 8 p2 agc s da gnd scl as p1 p3 p0 i fin i fin os clow out os clowin o scgnd os cmidin osc midout osc highin osch ighout osch ighout osc highin vcc if gnd if out if out p 4/adc xtal p llgnd vt cp xtal p1 p0 p0.p1 p0.p1
tua6034, tua6036 functional description specification 22 v 2.5, 2004-04-28 figure 5 block diagram tua6036 in tssop-38 package rf input high rf input low mixer high mixer low oscillator low oscillator mid oscillator high saw filter driver agc detector prog. divider crystal oscillator reference divider ports i 2 c bus lock detector adc p0 atc v cc agc f div f ref cp, os fl p1 p0 p0.p1 hi ghin hi ghin l ow in m ixout r fgnd m ixout rf input mid mixer mid m idin m idin p1 charge pump phase/ freq comp p2 agc s da gnd scl as p1 p3 p0 i fin i fin os clow out os clow in o scgnd os cmidin osc midout osc highin osch ighout osch ighout osc highin vcc if gnd if out if out p 4/adc xtal p llgnd vt cp xtal p1 p0 p0.p1 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 9 10 11 12 13 17 18 19 14 15 16 1 2 3 4 5 6 7 8 p0.p1
specification 23 v 2.5, 2004-04-28 tua6034, tua6036 functional description figure 6 block diagram tua6034 in vqfn-48 package mixer mid oscillator mid oscillator high p0.p1 rf input mid mixer low saw filter driver agc detector i 2 c bus prog. divider crystal oscillator reference divider ports lock detector adc agc f div f ref cp, os fl phase/ freq comp oscillator low rf input high charge pump p0 p1 v cc rf input low mixer high p0 p1 p0.p1 n.c. n.c. cp p4/adc n.c. xtal xtal p3 p0 p1 as n.c. 13 14 15 16 17 18 19 20 21 22 23 24 p0.p1 p1 p0 42 37 39 38 40 41 43 44 45 46 47 48 n.c. oscmidout oscmidin oscgnd n.c. h ighin m idin m idin lowin h ighin osclowin osclowout n.c. n.c. oschighin oschighout oschighout oschighin vcc ifgnd ifout ifout pllgnd vt 1 2 3 4 5 6 7 8 9 10 11 12 30 25 27 26 28 29 31 32 33 34 35 36 n.c. rfgnd mixout mixout n.c. p2 gnd sda scl agc ifin ifin
tua6034, tua6036 functional description specification 24 v 2.5, 2004-04-28 2.4 circuit description 2.4.1 mixer-oscillator block the mixer-oscillator block includes three balanced mixers (one mixer with an unbalanced high-impedance input and two mixers with a balanced low-impedance input), two 2-pin asymmetrical oscillators for the low and the mid band, one 4-pin symmetrical oscillator for the high band, an if amplifier, a reference voltage, and a band switch. filters between tuner input and ic separate the tv frequency signals into three bands. the band switching in the tuner front-end is done by using three pnp port outputs. in the selected band the signal passes a tuner input stage with a mosfet amplifier, a double- tuned bandpass filter and is then fed to the mixer input of the ic which has in case of low band a high-impedance input and in case of mid or high band a low-impedance input. the input signal is mixed there with the signal from the activated on chip oscillator to the if frequency. the if is filtered by means of an if filter in between the 2 mixer output pins and the 2 input pins of the following if amplifier. the if amplifier has a low output impedance to drive the saw filter directly. 2.4.2 pll block the oscillator signal is internally dc-coupled as a differential signal to the programmable divider inputs. the signal subsequently passes through a programmable divider with ratio n = 256 through 32767 and is then compared in a digital frequency/phase detector with a reference frequency f ref = 31.25, 50, 62.5, 125, 142.86 or 166.67 khz. this frequency is derived from a balanced, low-impedance 4 mhz crystal oscillator (pins xtal, xtal ) divided by 128, 80, 64, 32, 28 or 24. the reference frequencies will be different with a quartz other than 4 mhz. the phase detector has two outputs which drive four current sources of a charge pump. if the negative edge of the divided vco signal appears prior to the negative edge of the reference signal, the positive current source pulses for the duration of the phase difference. in the reverse case the negative current source pulses. if the two signals are in phase, the charge pump output (cp) goes into the high-impedance state (pll is locked). an active low-pass filter integrates the current pulses to generate the tuning voltage for the vco (internal amplifier, external pull-up resistor at vt and external rc circuitry). the charge pump output is also switched into the high-impedance state if the control bits t2, t1, t0 = 0, 1, 0. here it should be noted, however, that the tuning voltage can alter over a long period in the high impedance state as a result of self discharge in the peripheral circuity. vt may be switched off by the control bit os to allow external adjustments.
specification 25 v 2.5, 2004-04-28 tua6034, tua6036 functional description if the vco is not oscillating the pll locks to a tuning voltage of 33v (v th ). by means of control bits cp, t0, t1 and t2 the pump current can be switched between four values by software. this programmability permits alteration of the control response of the pll in the locked-in state. in this way different vco gains can be compensated, for example. the software controlled ports p0 to p4 are general purpose open-collector outputs. the test bits t2, t1, t0 =1, 0, 0 switch the test signals f div (divided input signal) and f ref (i.e .4 mhz / 64) to p0 and p1 respectively. the lock detector resets the lock flag fl if the width of the charge pump current pulses is greater than the period of the crystal oscillator (i.e. 250 ns). hence, if fl = 1, the maximum deviation of the input frequency from the programmed frequency is given by ? f = i p ? (k vco / f xtal ) ? (c1+c2) / (c1 ? c2) where i p is the charge pump current, k vco the vco gain, f xtal the crystal oscillator frequency and c 1 , c 2 the capacitances in the loop filter ( see chapter 3 ). as the charge pump pulses at i.e. 62.5 khz (= f ref ), it takes a maximum of 16 s for fl to be reset after the loop has lost lock state. once fl has been reset, it is set only if the charge pump pulse width is less than 250 ns for eight consecutive f ref periods. therefore it takes between 128 and 144 s for fl to be set after the loop regains lock. 2.4.3 agc the wide band agc stage detects the level of the if output signal and generates an agc voltage for gain control of the tuners input transistors. the agc take-over and the time constant are selectable by the i 2 c bus. 2.4.4 i 2 c-bus interface data is exchanged between the processor and the pll via the i 2 c bus. the clock is generated by the processor (input scl). pin sda functions as an input or output depending on the direction of the data (open collector, external pull-up resistor). both inputs have a hysteresis and a low-pass characteristic, which enhance the noise immunity of the i 2 c bus. the data from the processor pass through an i 2 c bus controller. depending on their function the data are subsequently stored in registers. if the bus is free, both lines will be in the marking state (sda, scl are high). each telegram begins with the start condition
tua6034, tua6036 functional description specification 26 v 2.5, 2004-04-28 and ends with the stop condition. start condition: sda goes low, while scl remains high. stop condition: sda goes high while scl remains high. all further information transfer takes place during scl = low, and the data is forwarded to the control logic on the positive clock edge. the table ?bit allocation? ( see table 8 on page 46 ) should be referred to for the following description. all telegrams are transmitted byte-by-byte, followed by a ninth clock pulse, during which the control logic returns the sda line to low (acknowledge condition). the first byte is comprised of seven address bits. these are used by the processor to select the pll from several peripheral components (address select). the lsb bit (r/w) determines whether data are written into (r/w = 0) or read from (r/w = 1) the pll. in the data portion of the telegram during a write operation, the msb bit of the first or third data byte determines whether a divider ratio or control information is to follow. in each case the second byte of the same data type has to follow the first byte. appropriate setting of the test bits will decide whether the band-switch byte or the auxiliary byte will be transmitted ( see table 11 on page 47 ). if the address byte indicates a read operation, the pll generates an acknowledge and then shifts out the status byte onto the sda line. if the processor generates an acknowledge, a further status byte is output; otherwise the data line is released to allow the processor to generate a stop condition. the status word consists of three bits from the a/d converter, the lock flag and the power-on flag. four different chip addresses can be set by an appropriate dc level at pin as ( see table 10 on page 47 ). while the supply voltage is applied, a power-on reset circuit prevents the pll from setting the sda line to low, which would block the bus. the power-on reset flag por is set at power-on and if v cc falls below 3.2 v. it will be reset at the end of a read operation.
specification 27 v 2.5, 2004-04-28 tua6034, tua6036 applications 3 applications 3.1 application circuit for atsc figure 7 application circuit for atsc remark: tua 6036 has reversed pinning. trans- former 2:10 2p2 2p7 100p l1 bb659c 2k7 12 1p5 1p2 82p l2 bb659c 2k7 8r2 1p2 1p2 1p2 1p2 l3 15p bb565 1k8 1k8 4n7 12p c1 100n c2 1n5 r1 15k 39p r2 560 100n 4n7 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 o s clow out os clow in o scg nd os cm idin osc m idout osc highin osch ighout osch ighout osc highin vcc if gnd if out if out p llgnd vt cp p 4/adc xtal xtal tua6034-t + 33 v p4/ adc ifout + 5 v 100n toko 7kl600 gcs-a1010dx 4 mhz 1n low input high input toko b4f 617db-1023 mid input toko b4f 617db-1023 balun 1:1 balun 1:1 22p 22p 1n 1n 33k 220 220 sda scl as 100p 100p 4n7 4n7 4n7 p0 4n7 p1 l4 68p 68p 4n7 p2 150n agc gnd as p0 p3 hi g hin l ow in r fgnd mid s da scl p1 ag c m ixout m ixout i fin i fin p2 hi ghin m idin p3 39p 560 47n 2p2 turns diam. wire diam. min max min max l1 8.5 3.2 mm 0.5 mm low 55.25 157.25 101 203 l2 2.5 3 mm 0.5 mm mid 163.25 451.25 201 479 l3 1.5 2.4 mm 0.5 mm high 457.25 861.25 503 907 l4 12.5 3.5 mm 0.3 mm coils for atsc application oscillator rf input recommended band limits for atsc in mhz c3 22n
tua6034, tua6036 applications specification 28 v 2.5, 2004-04-28 3.2 application circuit for dvb-t figure 8 application circuit for dvb-t remark: tua 6036 has reversed pinning. trans- former 2:10 2p2 2p7 100p l1 bb659c 2k7 12 1p5 1p2 82p l2 bb659c 2k7 8r2 1p2 1p2 1p2 1p2 l3 15p bb565 1k8 1k8 4n7 12p c1 4n7 c2 100p r1 68k 39p 220 220 33k r2 220 sda scl as 100p 100p 4n7 4n7 4n7 p0 p3 100n 4n7 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 o s c lo w o u t o s c lo w in o s c g n d o s c m id in o s c m id o u t o s c h ig h in o s c h ig h o u t o s c h ig h o u t o s c h ig h in v c c if g n d if o u t if o u t p llg n d v t c p p 4/a d c x ta l x t a l tua6034-t + 33 v p4/ adc ifout + 5 v 100n toko 7kl600 gcs-a1010dx 4 mhz 1n h i g h in low input m id in 4n7 p1 4n7 p2 150n agc g n d a s p 0 p 3 h i g h in l o w in r f g n d m id s d a s c l p 1 a g c m ix o u t m ix o u t i f in i f in p 2 39p high input toko b4f 617db-1023 mid input toko b4f 617db-1023 balun 1:1 balun 1:1 22p 22p 1n 1n 2p2 100p 100p 22p 47p 1k5 22p l4 330n l5 330n turns diam. wire diam. min max min max l1 8.5 3.2 mm 0.5 mm low 48.25 154.25 87.15 193.15 l2 2.5 3 mm 0.5 mm mid 161.25 439.25 200.15 478.15 l3 1.5 2.4 mm 0.5 mm high 447.25 863.25 486.15 902.15 l4, l5 smd 0805 330n smd = surface mounted device coils for dvb-t application recommended band limits for dvb-t in mhz oscillator rf input c3 22n
specification 29 v 2.5, 2004-04-28 tua6034, tua6036 applications 3.3 application circuit for isdb-t figure 9 application circuit for isdb-t remark: tua 6036 has reversed pinning. trans- former 2:10 2p2 2p7 100p l1 bb659c 2k7 12 1p5 1p2 82p l2 bb659c 2k7 8r2 1p2 1p2 1p2 1p2 l3 15p bb555 1k8 1k8 4n7 12p c1 6n8 c2 270p r1 33k 39p 220 220 33k r2 100 sda scl as 100p 100p 4n7 4n7 4n7 p0 p3 100n 4n7 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 o s c lo w o u t o s c lo w in o s c g n d o s c m id in o s c m id o u t o s c h ig h in o s c h ig h o u t o s c h ig h o u t o s c h ig h in v c c if g n d if o u t if o u t p llg n d v t c p p 4/a d c x ta l x t a l tua6034-t + 33 v p4/ adc ifout + 5 v 100n toko 7kl600 gcs-a1010dx 4 mhz 1n h i g h in low input m id in 4n7 p1 4n7 p2 150n agc g n d a s p 0 p 3 h i g h in l o w in r f g n d m id s d a s c l p 1 a g c m ix o u t m ix o u t i fin i fin p 2 39p high input toko b4f 617db-1023 mid input toko b4f 617db-1023 balun 1:1 balun 1:1 22p 22p 1n 1n 2p2 56p 56p 12p 30p 1k5 12p l4 220n l5 220n turns diam. wire diam. min max min max l1 8.5 3.2 mm 0.5 mm low 93 167 150 224 l2 2.5 3 mm 0.5 mm mid 173 467 230 524 l3 1.5 2.4 mm 0.5 mm high 473 767 530 824 l4, l5 smd 0805 220n smd = surface mounted device recommended band limits for isdb-t in mhz coils for isdb-t application rf input oscillator c3 22n
tua6034, tua6036 reference specification 30 v 2.5, 2004-04-28 4 reference 4.1 electrical data 4.1.1 absolute maximum ratings attention: the maximum ratings may not be exceeded under any circumstances, not even momentarily and individually, as permanent damage to the ic will result. table 5 absolute maximum ratings # parameter 1) symbol limit values unit remarks min. max. 1. supply voltage v cc -0.3 6 v 2. ambient temperature t a -40 t amax 2) c 3. junction temperature t j +125 c 4. storage temperature t stg -40 +125 c 5. temperature difference junction to case 3) t jc 2k pll 6. cp v cp -0.3 3 v 7. i cp 1ma 8. crystal oscillator pin xtal v q 6v 9. i q -5 ma 10. bus input/output sda v sda -0.3 6 v 11. bus output current sda i sda(l) 10 ma open collector 12. bus input scl v scl -0.3 6 v 13. chip address switch as v as -0.3 6 v 14. vco tuning output (loop filter) v vt -0.3 35 v 15. npn port output voltage of p4 v p4 -0.3 6 v open collector
specification 31 v 2.5, 2004-04-28 tua6034, tua6036 reference 16. npn port output current of p4 i p4(l) -1 10 ma open collector, t max = 0.1 s at 5.5 v 17. p4/adc input/output voltage v p4/adc -0.3 6 v 18. npn port output current of p4 i p4/adc(l) -1 10 ma open collector, t max = 0.1 s at 5.5 v 19. pnp port output voltage of p0, p1, p2, p3 v p0, 1, 2, 3 -0.3 6 v open collector 20. pnp port output current of p1 i p1(l) +1 -25 ma open collector, t max = 0.1 s at 5.5 v 21. pnp port output current of p0 i p0(l) +1 -10 ma open collector, t max = 0.1 s at 5.5 v 22. pnp port output current of p2, p3 i p2, 3(l) +1 -5 ma open collector, t max = 0.1 s at 5.5 v 23. 7 total port output current of pnp ports i p(l) -40 ma t max = 0.1 s at 5.5 v mixer-oscillator 24. mix inputs low band v low -0.3 3 v 25. mix inputs mid/high band v mid/high 2v 26. i mid/high -5 6 ma 27. vco base voltage v b -0.3 3 v low, mid and high band oscillators 28. vco collector voltage v c 6 v low, mid and high band oscillators esd-protection 4) 29. all pins v esd 2kv 1) all values are referred to ground (pin), unless stated otherwise. currents with a positive sign flow into the pin and currents with a negative sign flow out of pin. # parameter 1) symbol limit values unit remarks min. max.
tua6034, tua6036 reference specification 32 v 2.5, 2004-04-28 4.1.2 operating range table 6 operating range 2) the maximum ambient temperature depends on the mounting conditions of the package. any application mounting must guarantee not to exceed the maximum junction temperature of 125 c. as reference the temperature difference junction to case is given. 3) referred to top center of package. 4) according to eia/jesd22-a114-b (hbm incircuit test), as a single device incircuit contact discharge test. # parameter symbol limit values unit remarks min. max. 1. supply voltage v cc +4.5 +5.5 v 2. programmable divider factor n 256 32767 3. low mixer input frequency range f mixv 30 200 mhz 4. mid and high band mixer input frequency range f mixu 130 900 mhz 5. low oscillator frequency range f oh 65 250 mhz 6. mid band oscillator frequency range f ou 165 530 mhz 7. high band oscillator frequency range f ou 400 950 mhz 8. ambient temperature t a -20 t amax 1) 1) see 4.1.1 absolute maximum ratings on page 30. c
specification 33 v 2.5, 2004-04-28 tua6034, tua6036 reference 4.1.3 ac/dc characteristics table 7 ac/dc characteristics, t a = 25c, v cc = 5v # parameter symbol limit values unit test conditions min. typ. max. supply 1. supply voltage v cc 4.5 5 5.5 v 2. current consumption in active mode i vcc 59 74 89 ma low band 3. i vcc 59 74 89 ma mid band 4. i vcc 57 71 85 ma high band 5. current consumption in stand-by mode i stby 20 ma p0, p1 = 1 digital part pll crystal oscillator connections xtal 6. crystal frequency f xtal 3.2 4.0 4.8 mhz series resonance 7. crystal resistance r xtal 30 300 ? series resonance 8. oscillation frequency f xtal 3,9997 5 4,000 4,0002 5 mhz f xtal = 4 mhz 9. input impedance z xtal -650 -500 ? f xtal = 4 mhz charge pump output cp 10. output current, see table 15 charge pump current on page 49 i cpdh 430 650 860 a v cp = 1.8 v 11. i cph 180 250 360 a v cp = 1.8 v 12. i cpdl 90 125 180 a v cp = 1.8 v 13. i cpl 35 50 70 a v cp = 1.8 v 14. tristate current i cpz 1 na t2, t1, t0 = 0,1,0, v cp = 2 v 15. output voltage v cp 1.0 2.5 v loop locked tuning voltage output vt (open collector) 16. leakage current i th 10 a v th = 33 v, os = 1
tua6034, tua6036 reference specification 34 v 2.5, 2004-04-28 17. output voltage when the loop is closed, (test mode in normal operation) v tl 0.4 32.7 v os = 0, r load = 33 k ?, tuning supply = 33 v i 2 c-bus bus inputs scl, sda 18. high-level input voltage v ih 2.3 5.5 v 19. low-level input voltage v il 01.5v 20. high-level input current i ih 10 a v bus = 5.5 v, v cc = 0 v 21. i ih 10 a v bus = 5.5 v, v cc = 5.5 v 22. low-level input current i il 10 a v bus = 1.5 v, v cc = 0 v 23. i il -10 a v bus = 0 v, v cc = 5.5 v bus output sda (open collector) 24. leakage current i oh 10 a v oh = 5.5 v 25. low-level output voltage v ol 0.4 v i ol = 3 ma edge speed scl,sda 26. rise time t r 300 ns 27. fall time t f 300 ns clock timing scl 28. frequency f scl 0100400khz 29. high pulse width t h 0.6 s 30. low pulse width t l 1.3 s start condition 31. set-up time t susta 0.6 s # parameter symbol limit values unit test conditions min. typ. max.
specification 35 v 2.5, 2004-04-28 tua6034, tua6036 reference 32. hold time t hsta 0.6 s stop condition 33. set up time t susto 0.6 s 34. bus free t buf 1.3 s data transfer 35. set-up time t sudat 0.1 s 36. hold time t hdat 0s 37. input hysteresis scl, sda v hys 200 mv 38. pulse width of spikes which are suppressed t sp 050ns 39. capacitive load for each bus line c l 400 pf pnp port outputs p0, p1, p2, p3 (open collector) 40. port output voltage v poh0to3 0.05 0.4 v i polh0to3 = 0 ma, port disabled 41. output saturation voltage port 0 v pl0 = v cc - v cesat0 0.25 0.4 v i pol0 = 10 ma, port enabled 42. output saturation voltage port 1 v pl1 = v cc - v cesat1 0.25 0.4 v i pol1 = 15 ma port enabled 43. output saturation voltage ports 2, 3 v pl2 ,3 = v cc - v cesat2,3 0.25 0.4 v i pol2, 3 = 5 ma port enabled npn port output p4 (open collector) 44. output leakage current i poh4 10 a v cc = 5.5, v pn4 = 6 v 45. output saturation voltage v pl04 0.25 0.4 v i pol4 = 5 ma adc input 46. adc input voltage v adc 05.5v # parameter symbol limit values unit test conditions min. typ. max.
tua6034, tua6036 reference specification 36 v 2.5, 2004-04-28 47. high-level input current i adch 10 a 48. low-level input current i adcl -10 a address selection input as 49. high-level input current i ash 50 a v ash = 5.5 v 50. low-level input current i asl -50 a v asl = 0 v analog part low band mixer mode (p0 = 1, p1 = 0, including if amplifier) 51. rf frequency f rf 44.25 170.25 mhz picture carrier 1) 52. voltage gain g v 23.5 26 28.5 db f rf = 44.25 mhz, see 4.5.1 on page 55 53. g v 23.5 26 28.5 db f rf =170.25 mhz, see 4.5.1 on page 55 54. noise figure nf 8 10 db f rf = 50 mhz, see 4.5.4 on page 56 see 4.5.3 on page 56 55. nf 8 10 db f rf =150 mhz, see 4.5.4 on page 56 see 4.5.3 on page 56 56. output voltage causing 0.8% of crossmodulation in channel v o 113 dbv f rf = 48.25 mhz, see 4.5.6 on page 57 57. v o 113 dbv f rf = 154.25 mhz, see 4.5.6 on page 57 58. input ip2 iip2 160 dbv f rf1 = 48.25 mhz f rf2 = 97.50 mhz, p rf1 = p rf2 59. iip2 145 dbv f rf1 = 154.25 mhz f rf2 = 309.50 mhz, p rf1 = p rf2 # parameter symbol limit values unit test conditions min. typ. max.
specification 37 v 2.5, 2004-04-28 tua6034, tua6036 reference 60. input ip3 iip3 118 dbv f rf1 = 48.25 mhz f rf2 = 49.25 mhz p rf1 = p rf2 61. iip3 117 dbv f rf1 = 154.25 mhz f rf2 = 155.25 mhz, p rf1 = p rf2 62. output voltage causing 1 db compression v o 124 dbv f rf = 48.25 mhz 63. v o 124 dbv f rf = 154.25 mhz 64. output voltage causing 1.1 khz incidental fm v o 108 111 dbv f rf = 48.25 mhz 2) 65. v o 108 111 dbv f rf = 154.25 mhz 2.) 66. local oscillator fm caused by i 2 c communication fm i2c 2.12 khz f rf = 154.25 mhz 3) 67. 750 hz pulling v i 88 dbv f rf = 154.25 mhz 4) 68. channel s02 beat int s02 57 60 dbc p rf = 115 dbv at if output 5) 69. channel a-5 beat int a-5 57 60 dbc p rf = 115 dbv at if output 6) 70. channel ch6 color beat int ch6 63 66 dbc p rf1 = p rf2 = 80 dbv 7) 71. rf input level without lock-out v i 120 dbv 8) 72. input conductance y i = (g p + j c p ) g p 0.15 ms f rf = 48.25 to 154.25 mhz, see 4.4.1 on page 52 73. input capacitance c p 1pff rf = 48.25 to 154.25 mhz, see 4.4.1 on page 52 mid band mixer mode (p0 = 0, p1 =1, including if amplifier) 74. rf frequency f rf 154.25 454.25 mhz picture carrier 1.) # parameter symbol limit values unit test conditions min. typ. max.
tua6034, tua6036 reference specification 38 v 2.5, 2004-04-28 75. voltage gain g v 33 36 39 db f rf = 161.25 mhz, see 4.5.2 on page 55 76. g v 33 36 39 db f rf = 439.25 mhz, see 4.5.2 on page 55 77. noise figure (not corrected for image) nf 6 8 db f rf = 161.25 mhz, see 4.5.5 on page 57 78. nf 6 8 db f rf = 300 mhz, see 4.5.5 on page 57 79. output voltage causing 0.8% of crossmodulation in channel v o 112 dbv f rf = 161.25 mhz, see 4.5.7 on page 58 80. v o 112 dbv f rf = 439.25 mhz, see 4.5.7 on page 58 81. input ip2 iip2 146 dbv f rf1 = 161.25 mhz f rf2 = 323.50 mhz, p rf1 = p rf2 82. iip2 140 dbv f rf1 = 440.25 mhz f rf2 = 818.50 mhz, p rf1 = p rf2 83. input ip3 iip3 105 dbv f rf1 = 161.25 mhz f rf2 = 162.25 mhz p rf1 = p rf2 84. iip3 106 dbv f rf1 = 439.25 mhz f rf2 = 440.25 mhz p rf1 = p rf2 85. output voltage causing 1 db compression v o 124 dbv f rf = 161.25 mhz 86. v o 124 dbv f rf = 439.25 mhz 87. output voltage causing 1.1 khz incidental fm v o 108 111 dbv f rf = 161.25 mhz 2.) 88. v o 108 111 dbv f rf = 439.25 mhz 2.) 89. local oscillator fm caused by i 2 c communication fm i2c 2.12 khz f rf = 439.25 mhz 3.) # parameter symbol limit values unit test conditions min. typ. max.
specification 39 v 2.5, 2004-04-28 tua6034, tua6036 reference 90. n+5 - 1 mhz pulling n+5 - 1 mhz 77 80 dbv f rfw = 359.25 mhz, f osc = 398.15 mhz, f rfu = 399.25 mhz 9) 91. 750 hz pulling v i 78 dbv f rf = 439.25 mhz 4.) 92. rf input level without lock-out v i 120 dbv 8.) 93. input impedance z i = (r s + j l s ) r s 35 ? f rf = 161.25 mhz, see 4.4.2 on page 52 94. r s 35 ? f rf = 439.25 mhz, see 4.4.2 on page 52 95. l s 8nhf rf = 161.25 mhz, see 4.4.2 on page 52 96. l s 8nhf rf = 439.25 mhz, see 4.4.2 on page 52 high band mixer mode (p0 = 0, p1 = 0, including if amplifier) 97. rf frequency f rf 399.25 863.25 mhz picture carrier 1.) 98. voltage gain g v 33 36 39 db f rf = 447.25 mhz, see 4.5.2 on page 55 99. g v 33 36 39 db f rf = 863.25 mhz, see 4.5.2 on page 55 100. noise figure (not corrected for image) nf 6 8 db f rf = 447.25 mhz, see 4.5.5 on page 57 101. nf 7 9 db f rf = 863.25 mhz, see 4.5.5 on page 57 102. output voltage causing 0.8% of crossmodulation in channel v o 112 dbv f rf = 447.25 mhz, see 4.5.7 on page 58 103. v o 112 dbv f rf = 863.25 mhz, see 4.5.7 on page 58 104. input ip2 iip2 136 dbv f rf1 = 447.25 mhz f rf2 = 895.50 mhz p rf1 = p rf2 # parameter symbol limit values unit test conditions min. typ. max.
tua6034, tua6036 reference specification 40 v 2.5, 2004-04-28 105. input ip3 iip3 106 dbv f rf1 = 447.25 mhz f rf2 = 448.25 mhz p rf1 = p rf2 106. iip3 106 dbv f rf1 = 863.25 mhz f rf2 = 864.25 mhz p rf1 = p rf2 107. output voltage causing 1 db compression v o 124 dbv f rf = 447.25 mhz 108. v o 124 dbv f rf = 863.25 mhz 109. output voltage causing 1.1 khz incidental fm v o 108 111 dbv f rf = 447.25 mhz 2.) 110. v o 108 111 dbv f rf = 454.25 mhz 2.) 111. local oscillator fm caused by i 2 c communication fm i2c 2.12 khz f rf = 863.25 mhz 3.) 112. n+5 - 1 mhz pulling n+5 - 1 mhz 77 80 dbv f rfw = 823.25 mhz, f osc = 862.15 mhz, f rfu = 862.25 mhz 9.) 113. 750 hz pulling v i 78 dbv f rf = 855.25 mhz 4.) 114. rf input level without lock-out v i 120 dbv 8.) 115. input impedance z i = (r s + j l s ) r s 35 ? f rf = 407.25 mhz, see 4.4.3 on page 53 116. r s 35 ? f rf = 863.25 mhz, see 4.4.3 on page 53 117. l s 8nhf rf = 407.25 mhz, see 4.4.3 on page 53 118. l s 8nhf rf = 863.25 mhz, see 4.4.3 on page 53 low band oscillator, (see chapter 3 on page 27) 119. oscillator frequency f osc 80 210 mhz 10) # parameter symbol limit values unit test conditions min. typ. max.
specification 41 v 2.5, 2004-04-28 tua6034, tua6036 reference 120. oscillator frequency shift ? f osc(v) 20 70 khz ? v cc = 5% 11) 121. ? f osc(v) 110 khz ? v cc = 10% 11.) 122. oscillator frequency drift ? f osc(t) 300 500 khz ? t = 25 c, with compensation 12) 123. oscillator frequency drift ? f osc(t) 150 250 khz 5 s to 15 min after switch on 13) 124. phase noise, carrier to noise sideband osc 77 14) 85 dbc/ hz 1 khz frequency offset, worst case in frequency range 125. 88 15) 92 dbc/ hz 10 khz frequency offset, worst case in frequency range 126. 108 14), 15) 112 dbc/ hz 100 khz frequency offset, worst case in frequency range 127. ripple susceptibility of v p rsc 15 20 mv 4.75 < v p < 5.25 v, worst case in frequency range, ripple frequency 500 khz 16) mid band oscillator, (see chapter 3 on page 27) 128. oscillator frequency f osc 201 493 mhz 10.) 129. oscillator frequency shift ? f osc(v) 20 70 khz ? v cc = 5% 11.) 130. ? f osc(v) 110 khz ? v cc = 10% 11.) 131. oscillator frequency drift ? f osc(t) 500 750 khz ? t = 25 c; with compensation 12.) 132. oscillator frequency drift ? f osc(t) 250 500 khz 5 s to 15 min after switch on 13.) # parameter symbol limit values unit test conditions min. typ. max.
tua6034, tua6036 reference specification 42 v 2.5, 2004-04-28 133. phase noise, carrier to noise sideband osc 73 14) 80 dbc/ hz 1 khz frequency offset, worst case in frequency range 134. 88 15) 92 dbc/ hz 10 khz frequency offset, worst case in frequency range 135. 106 14), 15) 112 dbc/ hz 100 khz frequency offset, worst case in frequency range 136. ripple susceptibility of v p rsc 15 20 mv 4.75 < v p < 5.25 v, worst case in frequency range, ripple frequency 500 khz 14.) high band oscillator, (see chapter 3 on page 27) 137. oscillator frequency f osc 435 905 mhz 10.) 138. oscillator frequency shift ? f osc(v) 20 70 khz ? v cc = 5% 11.) 139. ? f osc(v) 300 khz ? v cc = 10% 11.) 140. oscillator frequency drift ? f osc(t) 600 1000 khz ? t = 25 c; with compensation 12.) 141. oscillator frequency drift ? f osc(t) 250 500 khz 5 s to 15 min after switch on 13). 142. phase noise, carrier to noise sideband osc 70 14) 77 dbc/ hz 1 khz frequency offset, worst case in frequency range 143. 86 15) 90 dbc/ hz 10 khz frequency offset, worst case in frequency range 144. 106 14), 15) 109 dbc/ hz 100 khz frequency offset, worst case in frequency range # parameter symbol limit values unit test conditions min. typ. max.
specification 43 v 2.5, 2004-04-28 tua6034, tua6036 reference 145. ripple susceptibility of v p rsc 15 20 mv 4.75 < v p < 5.25 v, worst case in frequency range, ripple frequency 500 khz 14.) if amplifier 146. input impedance z i = (r s + j l s ) r s 460 ? at 36 mhz, see 4.4.4 on page 53 147. l s 10 nh at 36 mhz, see 4.4.4 on page 53 148. output reflection coefficient s 22 10 db magnitude, see 4.4.4 on page 53 149. s 22 0.85 phase, see 4.4.4 on page 53 150. output impedance z o = (r s + j l s ) r s 65 ? at 36 mhz, see 4.4.6 on page 54 151. l s 20 nh at 36 mhz, see 4.4.6 on page 54 rejection at the if outputs 152. level of divider interferences in the if signal int div 20 dbv 17) , worst case 153. crystal oscillator interferences rejection int xtal 60 66 dbc v if = 100 dbv, worst case in frequency range 18) 154. reference frequency rejection int ref 60 66 dbc v if = 100 dbv, worst case in frequency range 19) agc output 155. agc take-over point agc top 112 dbv al2, al1, al0 = 0, 1, 0 156. source current 1 i agc fast 7.2 9.0 10.8 a 157. source current 2 i agc slow 210 300 390 na 158. peak sink to ground i agc peak 80 100 120 a # parameter symbol limit values unit test conditions min. typ. max.
tua6034, tua6036 reference specification 44 v 2.5, 2004-04-28 159. agc output voltage v agcmax 3.6 3.8 4.0 v maximum level, i agc = 9 a 160. agc output voltage v agcmin 0 0.25 v minimum level 161. rf voltage range to switch the agc from active to inactive mode agc slip 0.5 db 162. agc output voltage agc rml 0 2.9 v agc bit high or agc active 163. agc output voltage agc rmh 3.3 3.8 vcc- 0.5 or 4 v agc bit low or agc inactive 164. agc leakage current agc leak -50 50 na al2, al1, al0 = 1,1,0 0 < v agc < v cc 165. agc output voltage agc off 3.3 3.8 vcc- 0.5 or 4 v al2, al1, al0 = 1,1,1 agc is disabled this value is only guaranteed in lab. 1) the rf frequency range is defined by the oscillator frequency range and the intermediate frequency (if). 2) this is the level of the rf unwanted signal (50% amplitude modulated with 1khz) that causes a 1.1 khz fm modulation of the local oscillator and thus of the wanted signal; v wanted = 100 dbv; f unwanted = fwanted + 5.5 mhz. 3) local oscillator fm modulation resulting from i 2 c communication is measured at the if output using a modulation analyser with a peak to peak detector ((p + +p - )/2) and a post detection filter 30 hz - 200 khz. the i 2 c messages are sent to the tuner in such a way that the tuner is addressed but the content of the pll registers are not altered. the refresh interval between each data set shall be 20 ms to 1s. 4) this is the level of the rf signal (100% amplitude modulated with 11.89 khz) that causes a 750 hz frequency deviation on the oscillator signal producing sidebands 30 db below the level of the oscillator signal. 5) channel s02 beat is the interfering product of f rfpix , f if and f osc of channel s02, f beat = 37.35 mhz. the possible mechanisms are f osc - 2 x f if or 2 x f rfpix - f osc . 6) channel a-5 beat is the interfering product of f rfpix, f if and f osc of channel a-5; f beat = 45.5 mhz. the possible mechanisms are: f osc - 2 x f if or 2 x f rfpix - f osc . 7) channel 6 beat is the interfering product of f rfpix + f rfsnd - f osc of channel 6 at 42 mhz. 8) the if output signal stays stable within the range of the f ref step for a low level rf input up to 120 dbv. 9) n+5 -1 mhz is defined as the input level of channel n+5, at frequency 1 mhz lower, causing fm sidebands 30 db below the wanted carrier. # parameter symbol limit values unit test conditions min. typ. max.
specification 45 v 2.5, 2004-04-28 tua6034, tua6036 reference 10) limits are related to the tank circuit used in the application board (see chapter 3 on page 27). frequency bands may be adjusted by the choice of external components. 11) the frequency shift is defined as a change in oscillator frequency when the supply voltage varies from v cc = 5 to 4.75 v (4.5 v) or from v cc = 5 to 5.25 v (5.5 v). the oscillator is free running during this measurement. 12) the frequency drift is defined as a change in oscillator frequency if the ambient temperature varies from t a = 25 to 50 c or from t a = 25 to 0 c. the oscillator is free running during this measurement. 13) the switch-on drift is defined as a change in oscillator frequency between 5 s and 15 min after switch-on. the oscillator is free running during this measurement. 14) see figure 8 application circuit for dvb-t on page 28. 15) see figure 7 application circuit for atsc on page 27. 16) the supply ripple susceptibility is measured in the application board (see chapter 3 on page 27), using a spectrum analyser connected to the if output. an unmodulated rf signal is applied to the test board rf input. a sinewave signal with a frequency of 500 khz is superposed onto the supply voltage (see 4.5.8 on page 58). the amplitude of this ripple is adjusted to bring the 500 khz sidebands around the if carrier to a level of 53.5 dbc referred to the carrier. 17) this is the level of divider interferences close to the if frequency. for example channel s3: f osc = 158.15 mhz, 1/4 f osc = 39.5375 mhz. divider interference is measured with the application board (see chapter 3 on page 27). all ground pins are connected to a single ground plane under the ic. the lowin input must be left open (i.e. not connected to any load or cable). the midin and highin inputs are connected to a hybrid. the measured level of divider interference are influenced by layout, grounding and port decoupling. the measurement results between various applications and the reference board could vary as much as 10 db. 18) crystal oscillator interference means the 4 mhz sidebands caused by the crystal oscillator. the rejection has to be greater than 60 db for an if output of 100 dbv. 19) the reference frequency rejection is the level of reference frequency sidebands (e.g. 62.5 khz) related to the carrier. the rejection has to be greater than 60 db for an if output of 100 dbv.
tua6034, tua6036 reference specification 46 v 2.5, 2004-04-28 4.2 programming table 8 bit allocation read/write table 9 description of symbols name byte bits ack msbbit6bit5bit4bit3bit2bit1 lsb write data address byte adb 1 1 0 0 0 ma1 ma0 r/w=0 a divider byte 1 db1 0 n14 n13 n12 n11 n10 n9 n8 a divider byte 2 db2 n7 n6 n5 n4 n3 n2 n1 n0 a control byte cb 1 cp t2 t1 t0 rsa rsb os a bandswitch byte bb p4 p3 p2 p1 p0 a auxiliary byte 1) 1) ab replaces bb when t2, t1, t0 = 0, 1, 1, see table 11 test modes on page 47. ab atc al2 al1 al0 0 0 0 0 a read data address byte adb 1 1 0 0 0 ma1 ma0 r/w=1 a status byte sb por fl 1 1 agc a2 a1 a0 a symbol description a acknowledge ma0, ma1 address selection bits, see table 10 address selection on page 47 n14 to n0 programmable divider bits: n = 2 14 x n14 + 2 13 x n13 + ... + 2 3 x n3 + 2 2 x n2 + 2 1 xn1 + n0 cp charge pump current bit: bit = 0: charge pump current = 50 a or 125 a bit = 1: charge pump current = 250 a (default) or 650 a, see table 15 charge pump current on page 49 t0, t1, t2 test bits, see table 11 test modes on page 47 rsa, rsb reference divider bits, see table 12 reference divider ratios on page 48 os tuning amplifier control bit: bit = 0: enable v t ; bit = 1: disable v t (default) p0, p1, p2, p3 pnp ports control bits bit = 0: port is inactive, high impedance state (default) bit = 1: port is active, v out = v cc -v cesat
specification 47 v 2.5, 2004-04-28 tua6034, tua6036 reference table 10 address selection table 11 test modes p4 npn port control bit bit = 0: port is inactive, high impedance state (default) bit = 1: port is active, v out = v cesat atc agc time constant bit bit = 0: i agc =300 na; ? t=2s with c=160 nf (default) bit = 1: i agc =9 a; ? t=50ms with c=160 nf al0, al1, al2 agc take-over point bits, see table 13 agc take-over point on page 48 por power-on reset flag; por =1 at power-on fl pll lock flag; bit = 1: loop is locked agc internal agc flag. agc=1 when internal agc is active (level below 3v) a0, a1, a2 digital output of the 5-level adc voltage at as ma1 ma0 (0 to 0.1) x v cc 00 open circuit or (0.2 to 0.3) x v cc 01 (0.4 to 0.6) x v cc 10 (0.9 to 1) x v cc 11 mode t2 t1 t0 normal mode, charge pump currents 50 and 250 a selectable 0 0 0 normal mode, charge pump currents 50 and 250 a selectable(default) 001 cp is in high-impedance state 0 1 0 byte ab will follow (otherwise byte bb will follow) 0 1 1 p0 = f div output, p1 = f ref output 1 0 0 not in use 1 0 1 extended mode, charge pump currents 50 and 250 a selectable 1 1 0 extended mode, charge pump currents 125 and 650 a selectable 1 1 1
tua6034, tua6036 reference specification 48 v 2.5, 2004-04-28 table 12 reference divider ratios table 13 agc take-over point reference divider ratio f ref 1) 1) with a 4 mhz quartz. mode t2 t1 rsa rsb 80 50 khz normal 0 0 0 0 128 31.25 khz normal 0 0 0 1 24 166.67 khz x x x 1 0 64 62.5 khz x x x 1 1 32 125 khz extended 1 1 0 0 28 142.86 khz extended 1 1 0 1 if output level, symmetrical mode remark al2 al1 al0 115 dbv 0 0 0 115 dbv 0 0 1 112 dbv default mode at por 0 1 0 109 dbv 0 1 1 106 dbv 1 0 0 103 dbv 1 0 1 i agc = 0 external agc 1) 1) the agc detector is disabled. both the sinking and sourcing current from the ic is disabled. the agc output goes into a high impedance state and an external agc source can be connected in parallel and will not be influenced. 110 3.8 v disabled 2) 2) the agc detector is disabled and i agc = 9 a. 111
specification 49 v 2.5, 2004-04-28 tua6034, tua6036 reference table 14 a to d converter levels 1) no erratic codes in the transition. table 15 charge pump current table 16 internal band selection voltage at adc a2 a1 a0 (0 to 0.15) * v cc 000 (0.15 to 0.3) * v cc 001 (0.3 to 0.45) * v cc 010 (0.45 to 0.6) * v cc 011 (0.6 to 1) * v cc 100 charge pump current mode cp t2 t1 t0 50 a normal 0 00 x 1) 1) x = don?t care. 250 a (default) 1 x 50 a extended 0 11 0 125 a 0 1 250 a 1 0 650 a 1 1 band mixer oscillator low p0.p1 1) 1) means: (p0 and not p1); that is: low mixer is switched on if (p0=1 and p1=0). p0.p1 mid p1.p0 p1.p0 high (default) p0 .p1 p0 .p1 stand-by mode p0, p1 p0, p1
tua6034, tua6036 reference specification 50 v 2.5, 2004-04-28 table 17 defaults at power-on reset table 18 description of modes name byte bits msb bit6 bit5 bit4 bit3 bit2 bit1 lsb write data address byte adb11000ma1ma0r/w=0 divider byte 1 db1 0 x 1) 1) x = don?t care. xxxxx x divider byte 2 db2xxxxxxx x control byte cb11001xx 1 bandswitch bytebb0000000 0 auxiliary byte ab0010 mode description normal reference divider ratios 24, 64, 80 , 128 selectable. charge pump currents 50, 250 a selectable. auxiliary byte to follow control byte (t2=0, t1=1, t0=1), otherwise bandswitch byte to follow control byte. extended reference divider ratios 24, 28 , 32 , 64 selectable. charge pump currents 50, 125 , 250, 650 a selectable. auxiliary byte to follow control byte (t2=0, t1=1, t0=1), otherwise bandswitch byte to follow control byte.
specification 51 v 2.5, 2004-04-28 tua6034, tua6036 reference 4.3 i 2 c bus timing diagram m r/ ma note : scl ack . ack . 2nd 1st 3rd ack . ack . ack . addressi ng 4th 1 1 star t stop telegram examples: start-adb-db1-db2-cb-bb-stop start-adb-db1-db2-cb-ab-stop start-adb-cb-bb-db1-db2-stop start-adb-cb-ab-db1-db2-stop start-adb-db1-db2-stop start-adb-cb-bb-stop start-adb-cb-ab-stop abbreviations: start= start condition adb= address byte db1= prog. divider byte 1 db2= prog. divider byte 2 cb= control byte bb= bandswitch byte ab= auxiliary byte stop= stop condition
tua6034, tua6036 reference specification 52 v 2.5, 2004-04-28 4.4 electrical diagrams 4.4.1 input admittance (s11) of the low band mixer (40 to 150 mhz) y 0 = 20ms 4.4.2 input impedance (s11) of the mid band mixer (150 to 455 mhz) z 0 = 50 ? 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0.3 0.3 0.4 0.4 0 .5 0 .5 0 .6 0 .6 0 .7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 150mhz 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0 .3 0 .3 0.4 0.4 0.5 0.5 0 .6 0.6 0.7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 150 mhz 455 mhz
specification 53 v 2.5, 2004-04-28 tua6034, tua6036 reference 4.4.3 input impedance (s11) of the high band mixer (450 to 865 mhz) z 0 = 50 ? 4.4.4 output admittance (s22) of the of the mixers (30 to 50 mhz) y 0 = 20ms 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0 .3 0 .3 0.4 0.4 0.5 0.5 0 .6 0.6 0.7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 450 mhz 865 mhz 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0 .3 0 .3 0.4 0.4 0.5 0.5 0 .6 0.6 0.7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 38.9 mhz
tua6034, tua6036 reference specification 54 v 2.5, 2004-04-28 4.4.5 input impedance (s11) of the if amplifier (30 to 50 mhz) z 0 = 50 ? 4.4.6 output impedance (s22) of the if amplifier (30 to 50 mhz) z 0 = 50 ? 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0 .3 0 .3 0.4 0.4 0.5 0.5 0.6 0 .6 0.7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 38.9 mhz 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 1.5 2 3 4 5 10 20 0 0 .1 0 .1 0.2 0.2 0 .3 0.3 0.4 0.4 0 .5 0 .5 0 .6 0 .6 0.7 0.7 0.8 0.8 0.9 0.9 1 1 1.5 1.5 2 2 3 3 4 4 5 5 1 0 1 0 20 20 38.9 mhz
specification 55 v 2.5, 2004-04-28 tua6034, tua6036 reference 4.5 measurement circuits 4.5.1 gain (g v ) measurement in low band figure 10 gain (g v ) measurement in low band z i >> 50 ? => v i = 2 x v meas = 80 dbv v i = v meas + 6db = 80 dbv v 0 = v? meas + 16 db (transformer ratio n1:n2 and transformer loss) g v = 20 log(v 0 / v i ) 4.5.2 gain (g v ) measurement in mid and high bands figure 11 gain (g v ) measurement in mid and high bands v i = v meas = 70 dbv v 0 = v? meas + 16 db (transformer ratio n1:n2 and transformer loss g v = 20 log(v 0 / v i ) + 1 db (1 db = insertion loss of balun) 50 ? spectrum analyser device under test ifout lowin ifout v' meas v 0 v i 50 ? c transformer n1 : n2 = 10 : 2 turns n1 n2 50 ? v v meas rms voltmeter 50 ? spectrum analyser device under test ifout midin highin ifout v' meas v 0 v i 50 ? c transformer n1 : n2 = 10 : 2 turns n1 n2 50 ? v v meas rms voltmeter balun 1:1 midin highin
tua6034, tua6036 reference specification 56 v 2.5, 2004-04-28 4.5.3 matching circuit for optimum noise figure in low band figure 12 matching circuit for optimum noise figure in low band for f rf = 50 mhz for f rf = 150 mhz loss = 0 db loss = 1.3 db image suppression = 16 db image suppression = 13 db 4.5.4 noise figure (nf) measurement in low band figure 13 noise figure (nf) measurement in low band 22p 22p 7 turns wire 0.5 mm coil 5.5 mm 1n in out 15p 1n 50 ? semi rigid cable 300 mm long 96 pf/m 33db/100m in out 22p device under test ifout lowin ifout c transformer n1 : n2 = 10 : 2 turns n1 n2 noise source noise figure meter nf = nfmeas - loss of matching circuit (db) matching circuit in out
specification 57 v 2.5, 2004-04-28 tua6034, tua6036 reference 4.5.5 noise figure (nf) measurement in mid and high bands figure 14 noise figure (nf) measurement in mid and high bands 4.5.6 cross modulation measurement in low band figure 15 cross modulation measurement in low band z i >> 50 ? => v i = 2 x v meas v? meas = v 0 - 16 db (transformer ratio n1:n2 and transformer loss) wanted output signal at f pix , v o = 100 dbv unwanted output signal at f snd device under test ifout midin highin ifout c transformer n1 : n2 = 10 : 2 turns n1 n2 midin highin balun 1:1 noise source noise figure meter loss of balun = 1 db nf = nfmeas - loss of balun (db) v 38.9 mhz 50 ? modulation analyser hybrid a b c d device under test ifout lowin ifout v' meas v 0 v i 50 ? 50 ? 50 ? rms votmeter c transformer n1 : n2 = 10 : 2 turns n1 n2 unwanted signal source am = 80 %, 1 khz wanted signal source 18 db attenuator 50 ? v v meas rms voltmeter
tua6034, tua6036 reference specification 58 v 2.5, 2004-04-28 4.5.7 cross modulation measurement in mid and high bands figure 16 cross modulation measurement in mid and high bands v? meas = v 0 - 16 db (transformer ratio n1:n2 and transformer loss) wanted output signal at f pix , v o = 100 dbv unwanted output signal at f snd 4.5.8 ripple susceptibility measurement figure 17 ripple susceptibility measurement v 38.9 mhz 50 ? modulation analyser hybrid a b c d device under test ifout midin highin ifout v' meas balun 1:1 v 0 v i 50 ? 50 ? 50 ? rms votmeter c transformer n1 : n2 = 10 : 2 turns n1 n2 unwanted signal source am = 80 %, 1 khz wanted signal source 50 ? v v meas rms voltmeter 18 db attenuator midin highin circuit to superimpose a 500 khz ripple on v cc 500 khz sine 10 f 50 ? 6k8 10 f to application board 50 ? v ripple v cc + v ripple v supply bc847b
specification 59 v 2.5, 2004-04-28 tua6034, tua6036 package outlines 5 package outlines 5.1 tssop-38 figure 18 tssop-38 vignette figure 19 tssop-38 outline drawing
tua6034, tua6036 package outlines specification 60 v 2.5, 2004-04-28 5.2 vqfn-48 figure 20 vqfn-48 vignette figure 21 vqfn-48 outline drawing y ou can find all of our packages, sorts of packing and others in our infineon internet page ?products?: http://www.infineon.com/products . dimensions in mm smd = surface mounted device
www.infineon.com published by infineon technologies ag

▲Up To Search▲

Price & Availability of TUA6034-V

	To Download TUA6034-V Datasheet File
If you can't view the Datasheet, Please click here to try to view without PDF Reader .