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| 1/15 TDA7375V july 2008 1features high output power capability: ? 2 x 40w max./4 ?2 x 35w/4 eiaj ?2 x 35w/4 eiaj ?2 x 25w/4 @14.4v, 1khz, 10% ?4 x 7w/4 @14.4v,1khz, 10% ?4 x 12w/2 @14.4v, 1khz, 10% minimum external components count: ? no bootstrap capacitors ? no boucherot cells ? internally fixed gain (26db btl) st-by function (cmos compatible) no audible pop during st-by operations diagnostics facility for: ? clipping ? out to gnd short ?out to v s short ? soft short at turn-on ? thermal shutdown proximity 2 protections: ouput ac/dc short circuit ? to gnd ?to v s ? across the load soft short at turn-on overrating chip temperature with soft thermal limiter load dump voltagesurge very inductive loads fortuitous open gnd reversed battery esd 2 x 35w dual/quad power amplifier for car radio figure 2. block diagram rev. 4 fi gure 1 . p ac k age table 1. order codes part number package TDA7375V multiwatt 15 (vertical) multiwatt15
TDA7375V 2/15 3description the TDA7375V is a new technology class ab car radio amplifier able to work either in dual bridge or quad single ended configuration. the exclusive fully complementary structure of the output stage and the internally fixed gain guarantees the highest possible power performances with extremely reduced component count. the on-board clip detector simplifies gain compression operation. the fault diagnostics makes it possible to detect mistakes during car radio set assembly and wiring in the car. table 2. absolute maximum ratings table 3. thermal data figure 3. pin connection (top view) symbol parameter value unit v op operating supply voltage 18 v v s dc supply voltage 28 v v peak peak supply voltage (for t = 50ms) 50 v i o output peak current (not repetitive t = 100 s) 4.5 a i o output peak current (repetitive f > 10hz) 3.5 a p tot power dissipation (t case = 85c) 36 w t stg , t j storage and junction temperature -40 to 150 c symbol parameter value unit r th j-case thermal resistance junction-case max 1.8 c/w 3/15 TDA7375V table 4. electrical characteristcs (refer to the test circuit, v s = 14.4v; r l = 4 ; f = 1khz; t amb = 25c, unless otherwise specified) (*) see built-in s/c protection description (**) pin 10 pulled-up to 5v with 10k ; r l = 4 (***) saturated square wave output. symbol parameter test condition min. typ. max. unit v s supply voltage range 8 18 v i d total quiescent drain current r l = 150 ma v os output offset voltage 150 mv p o output power thd = 10%; r l = 4 bridge single ended single ended, r l = 2 23 6.5 25 7 12 w w w p o max max. output power (***) v s = 14.4v, bridge 36 40 w p o eiaj eiaj output power (***) v s = 13.7v, bridge 32 35 w thd distortion r l = 4 single ended, p o = 0.1 to 4w bridge, p o = 0.1 to 10w 0.02 0.03 0.3 % % ct cross talk f = 1khz single ended 70 db f = 10khz single ended 60 db f = 1khz bridge 55 db f = 10khz bridge 60 db r in input impedance single ended 20 30 k bridge 10 15 k g v voltage gain single ended 19 20 21 db bridge 25 26 27 db g v voltage gain match 0.5 db e in input noise voltage r g = 0; ?a? weighted, s.e. non inverting channels inverting channels 2 5 v v bridge rg = 0; 22hz to 22khz 3.5 v svr supply voltage rejection r g = 0; f = 300hz 50 db a sb stand-by attenuation p o = 1w 80 90 db i sb st-by current consumption v st-by = 0 to 1.5v 100 a v sb st-by in threshold voltage 1.5 v v sb st-by out threshold voltage 3.5 v i pin7 st-by pin current play mode v pin7 = 5v 50 a max driving curr. under fault (*) 5 ma i cd off clipping detector output average current d = 1% (**) 90 a i cd on clipping detector output average current d = 5% (**) 160 a v sat pin10 voltage saturation on pin 10 sink current at pin 10 = 1ma 0.7 v TDA7375V 4/15 4 standard test and application circuit figure 4. quad stereo figure 5. double bridge figure 6. stereo/bridge c1 0.22 f 1 diagnostics 4 7 c10 2200 f d94au063a c7 10 f 10k r1 st-by in fl c2 0.22 f in fr 5 c4 0.22 f 12 in rl c3 0.22 f in rr 11 c8 47 f 6 13 c5 1000 f c6 100nf 3 v s c9 2200 f 2 15 c11 2200 f c12 2200 f 14 out fl out fr out rl out rr 89 10 note: c9, c10, c11, c12 could be reduced if the 2w operation is not required. c1 0.47 f 1 diagnostics 4 7 d94au064a c5 10 f 10k r1 st-by in l c2 0.47 f 5 12 in r 11 c8 47 f 6 13 c3 1000 f c4 100nf 3 v s 2 15 14 out l 89 10 out r 0.22 f 1 diagnostics 4 7 d94au065a 10 f 10k st-by in l 0.47 f 5 in bridge 12 47 f 6 13 1000 f 100nf 3 v s 2 15 14 out l 89 10 out bridge 11 0.22 f in l out r 2200 f 2200 f 5/15 TDA7375V figure 7. p.c. board and component layout of the fig.4 figure 8. p.c. board and component layout of the fig.5 TDA7375V 6/15 figure 9. quiescent drain current vs. supply voltage (single ended and bridge). figure 10. quiescent output voltage vs. supply voltage (single ended and bridge). figure 11. output power vs. supply voltage figure 12. output power vs. supply voltage figure 13. outputpower vs. supply voltage figure 14. distortion vs. output power 7/15 TDA7375V figure 15. distortion vs. output power figure 16. distortion vs. output power figure 17. cross-talk vs. frequency figure 18. supply voltage rejection vs. frequency figure 19. supply voltage rejection vs. frequency figure 20. stand-by attenuation vs. threshold voltage TDA7375V 8/15 figure 21. total power dissipation and efficiency vs. output power figure 22. total power dissipation and efficiency vs. output power 5 general structure 5.1 high application flexibility the availability of 4 independent channels makes it possible to accomplish several kinds of applications ranging from 4 speakers stereo (f/r) to 2 speakers bridge solutions. in case of working in single ended conditions the polarity of the speakers driven by the inverting amplifier must be reversed respect to those driven by non inverting channels. this is to avoid phase inconveniences causing sound alterations especially during the reproduction of low frequencies. 5.2 easy single ended to bridge transition the change from single ended to bridge configurations is made simply by means of a short circuit across the inputs, that is no need of further external components. 5.3 gain internally fixed to 20db in single ended, 26db in bridge advantages of this design choice are in terms of: componentsand space saving output noise, supply voltage rejection and distortion optimization. 5.4 silent turn on/off and muting/stand-by function the stand-by can be easily activated by means of a cmos level applied to pin 7 through a rc filter. under stand-by condition the device is turned off completely (supply current = 1 a typ.; output attenuation = 80db min.). every on/off operation is virtually pop free. furthemore, at turn-on the device stays in muting condition for a time determined by the value assigned to the svr capacitor. while in muting the device outputs becomes insensitive to any kinds of signal that may be present at the input terminals. in other words every transient coming from previous stages produces no unplesantacous- tic effect to the speakers. 5.5 stand-by driving (pin 7) some precautions have to be taken in the definition of stand-by driving networks: pin 7 cannot be directly 9/15 TDA7375V driven by a voltage source whose current capability is higher than 5ma. in practical cases a series resis- tance has always to be inserted, having it the double purpose of limiting the current at pin 7 and to smooth down the stand-by on/off transitions - in combination with a capacitor - for output pop prevention. in any case, a capacitor of at least 100nf from pin 7 to s-gnd, with no resistance in between, is necessary to ensure correct turn-on. 5.6 output stage the fully complementary output stage was made possible by the development of a new component: the st exclusive power icv pnp. a novel design based upon the connection shown in fig. 23 has then allowed the full exploitation of its pos- sibilities. the clear advantagesthis new approach has over classical output stages are as follows: 5.6.1 rail-to-rail output voltage swing with no need of bootstrap capacitors. the output swing is limited only by the v cesat of the output transistors, which is in the range of 0.3 (r sat ) each. classical solutions adopting composite pnp-npn for the upper output stage have higher saturation loss on the top side of the waveform. this unbalanced saturation causes a significant power reduction. the only way to recover power consists of the addition of expensive bootstrap capacitors. 5.6.2 absolute stability without any external compensation. referring to the circuit of fig. 23 the gain v out /v in is greater than unity, approximately 1+r2/r1. the dc output (v cc /2) is fixed by an auxiliary amplifier common to all the channels. by controlling the amount of this local feedbackit is possible to force the loop gain (a* ) to less than unity at frequency for which the phase shift is 180. this means that the output buffer is intrinsically stableand not prone to oscillation. most remarkably, the above feature has been achieved in spite of the very low closed loop gain of the amplifier. in contrast, with the classical pnp-npn stage, the solution adopted for reducing the gain at high frequencies makes use of external rc networks, namely the boucherot cells. 5.7 built?in shortcircuit protection figure 23. the new output stage reliable and safe operation, in presence of all kinds of short circuit involving the outputs is assured by built-in protectors. additionally to the ac/dc short circuit to gnd, to v s , across the speaker, a soft short condition is signalled out during the turn-on ph ase so assuring correct operation for the de- TDA7375V 10/15 vice itself and for the loudspeaker. this particular kind of protection acts in a way to avoid that the device is turned on (by st-by) when a resistive path (less than 16 ohms) is present between the output and gnd. as the involved circuitry is nor- mally disabled when a current higher than 5ma is flowing into the st-by pin, it is important, in order not to disable it, to have the external current source driving the st-by pin limited to 5ma. this extra function becomes particularly attractive when, in the single ended configuration, one capacitor is shared between two outputs (see fig. 24). supposing that the output capacitor cout for anyreason is shorted, the loudspeaker will not be damaged being this soft short circuit condition revealed. figure 24. single ended configuaration circuit 5.7.1 diagnostics facility the tda7375 is equipped with a diagnostic circuitry able to detect the following events: clipping in the output signal thermal shutdown output fault: ? short to gnd ? short to vs ? soft short at turn on the information is available across an open collector output (pin 10) through a current sinking when the event is detected a current sinking at pin 10 is triggered when a certain distortion level is reached at any of the outputs. this function allows gain compression possibility whenever the amplifier is overdriven. 5.7.2 thermal shutdown in this case the output 10 will signal the proximity of the junction temperature to the shutdown threshold. typically current sinking at pin 10 will start ~10c before the shutdown threshold is reached. figure 25. clipping detection waveforms 11/15 TDA7375V figure 26. output fault waveforms (see fig. 27) figure 27. fault waveforms 5.8 handling of the diagnostics information as various kinds of information is available at the same pin (clipping detection, output fault, thermal prox- imity), this signal must be handled properly in order to discriminate each event. this could be done by taking into account the different timing of the diagnostic output during each case. normally the clip detector signalling produces a low level at pin 10 that is shorter than that present under faulty conditions; based on this assumption an interface circuitry to differentiate the information is repre- sented in the schematic of fig. 29. TDA7375V 12/15 figure 28. waveforms figure 29. interface circuitry to differentiate the information schematic 5.9 pcb-layout grounding (general rules) the device has 2 distinct ground leads, p-gnd (power ground) and s-gnd (signal ground) which are practically disconnected from each other at chip level. proper operation requires that p-gnd and s-gnd leads be connected together on the pcb-layout by means of reasonably low-resistance tracks. as for the pcb-ground configuration, a star-like arrangement whose center is represented by the supply- filtering electrolytic capacitor ground is highly advisable. in such context, at least 2 separate paths have to be provided, one for p-gnd and one for s-gnd. the correct ground assignments are as follows: standby capacitor, pin 7 (or any other standby driving networks): on s-gnd svr capacitor (pin 6): on s-gnd and to be placed as close as possible to the device. input signal ground (from active/passive signal processor stages): on s-gnd. supply filtering capacitors (pins 3,13): on p-gnd. the (-) terminal of the electrolytic capacitor has to be directly tied to the battery (-) line and this should represent the starting point for all the ground paths. 13/15 TDA7375V 6 package information in order to meet environmental requirements, st (also) offers these devices in ecopack? packages. ecopack? packages are lead-free. the category of second level interconnect is marked on the pack- age and on the inner box label, in compliance with jedec standard jesd97. the maximum ratings re- lated to soldering conditions are also marked on the inner box label. ecopack is an st trademark. ecopack spec ifications are available at: www.st.com. figure 30. multiwatt 15 mechanical data & package dimensions outline and mechanical data 0016036 j dim. mm inch min. typ. max. min. typ. max. a5 0.197 b 2.65 0.104 c 1.6 0.063 d 1 0.039 e 0.49 0.55 0.019 0.022 f 0.66 0.75 0.026 0.030 g 1.02 1.27 1.52 0.040 0.050 0.060 g1 17.53 17.78 18.03 0.690 0.700 0.710 h1 19.6 0.772 h2 20.2 0.795 l 21.9 22.2 22.5 0.862 0.874 0.886 l1 21.7 22.1 22.5 0.854 0.87 0.886 l2 17.65 18.1 0.695 0.713 l3 17.25 17.5 17.75 0.679 0.689 0.699 l4 10.3 10.7 10.9 0.406 0.421 0.429 l7 2.65 2.9 0.104 0.114 m 4.25 4.55 4.85 0.167 0.179 0.191 m1 4.73 5.08 5.43 0.186 0.200 0.214 s 1.9 2.6 0.075 0.102 s1 1.9 2.6 0.075 0.102 dia1 3.65 3.85 0.144 0.152 multiwatt15 (vertical) TDA7375V 14/15 7 revision history table 5. revision history date revision description of changes july 2004 2 first issue in edocs march 2005 3 changed the style-sheet in compliance to the new ?corporate technical pubblications design guide?. deleted package multiwatt15 horizontal. 01-jul-2008 4 updated the root part number in the title of the cover page. added ecopack information in ?package information? section. 15/15 TDA7375V please read carefully: information in this document is provided solely in connection with st products. stmicroelectronics nv and its subsidiaries (?st ?) reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described he rein at any time, without notice. all st products are sold pursuant to st?s terms and conditions of sale. purchasers are solely responsible for the choice, selection and use of the st products and services described herein, and st as sumes no liability whatsoever relating to the choice, selection or use of the st products and services described herein. no license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted under this document. i f any part of this document refers to any third party products or services it shall not be deemed a license grant by st for the use of such third party products or services, or any intellectual property contained therein or considered as a warranty covering the use in any manner whatsoev er of such third party products or services or any intellectual property contained therein. unless otherwise set forth in st?s terms and conditions of sale st disclaims any express or implied war- ranty with respect to the use and/or sale of st products including without limitation implied warranties of merchantability, fitness for a particular purpose (and their equivalents under the laws of any juris- diction), or infringement of any patent, copyright or other intellectual property right. unless expressly approved in writing by an authorized st representative, st products are not recom- mended, authorized or warranted for use in military, air craft, space, life saving, or life sustaining ap- plications, nor in products or systems where failure or malfunction may result in personal injury, death, or severe property or environmental damage. st products which are not specified as "automotive grade" may only be used in automotive applications at user?s own risk. resale of st products with provisions different from the statements and/or technical features set forth in this document shall immediately void any warranty granted by st for the st product or service described herein and shall not create or extend in any manner whatsoev er, any liability of st. st and the st logo are trademarks or registered trademarks of st in various countries. information in this document supersedes and replaces all information previously supplied. the st logo is a registered trademark of stmicroelectronics. all other names are the property of their respective owners. ? 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