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TDA7370B quad power amplifier for car radio minimum external component count high current capability no bootstrap capacitors no boucherot cells clip detector output high output power high application flexibility fixed gain very low stand-by current (1 m a typ) no switch on/off noise protections: output ac/dc short circuit to gnd and to v s very inductive loads overrating chip temperature load dump voltage fortuitous open gnd reverse battery esd description the TDA7370B is a new technology class ab quad channels audio power amplifier in multiwatt package designed for car radio applications. thanks to the fully complementary pnp/npn out- put configuration the high power performances of the TDA7370B are obtained without bootstrap ca- pacitors. september 2003 ? block diagram multiwatt15v ordering number: TDA7370B 1/17 obsolete product(s) - obsolete product(s)
pin connection (top view) absolute maximum ratings symbol parameter value unit v s dc supply voltage 28 v v op operating supply voltage 18 v v peak peak supply voltage (t = 50ms) 50 v i o output peak current (not rep. t = 100 m s) 4.5 a i o output peak current (rep. f > 10hz) 3.5 a p tot power dissipation (t case = 85 c) 36 w t stg , t j storage and junction temperature -40 to 150 c thermal data symbol description value unit r th j-case thermal resistance junction-case max 1.8 c/w TDA7370B 2/17 obsolete product(s) - obsolete product(s)
electrical characteristics (refer to the test circuit; v s = 14.4v; r l = 4 w , t amb = 25c, f = 1khz, unless otherwise specified) symbol parameter test condition min. typ. max. unit v s supply range 8 18 v i d total quiescent drain current r l = 150 ma p o output power r l = 4 w ; thd = 10% single ended bridge 5.5 6.5 20 w w d distortion r l = 4 w ; single ended, p o = 0.1 to 4w bridge, p o = 0.1 to 10w 0.03 0.5 % % ct cross talk f = 1khz bridge f = 10khz bridge f = 1khz single ended f = 10khz single ended 65 55 60 50 db db db db r in input impedance single ended bridge 20 15 k w k w g v voltage gain single ended bridge 20 26 db db g v voltage gain match. 1 db e in input noise voltage (*) single ended non inv. ch., r g = 10k w inv. ch., r g = 10k w bridge (r g = 0 to 10k w) 3.0 5 3.5 m v m v m v svr supply voltage rejection r g = 0; f = 100hz to 10khz 50 db asb stand-by attenuation 60 db i sb st-by current 1 m a v sb on st-by on threshold voltage 1.5 v v sb off st-by off threshold voltage 3.5 v v os output offset voltage 200 mv i cd off clipping detector "off" output average current thd = 1% (**) 100 m a i cd on clipping detector "on" output average current thd = 10% (**) 190 m a (*) weighted a (**) pin 10 pulled-up to 5v with 10k w ; TDA7370B 3/17 obsolete product(s) - obsolete product(s)
application circuit (quad stereo) quad stereo p.c. board and component layout (1:1 scale) b TDA7370B 4/17 obsolete product(s) - obsolete product(s)
application circuit (double bridge) double bridge p.c. board and component layout (1:1 scale) b TDA7370B 5/17 obsolete product(s) - obsolete product(s)
application circuit (stereo/bridge) figure 1: quiescent drain current vs. supply voltage (bridge/single ended) figure 2: quiescent output voltage vs. supply voltage (bridge/single ended) TDA7370B 6/17 obsolete product(s) - obsolete product(s)
figure 3: output power vs. supply voltage (single ended) figure 4: output power vs. supply voltage (bridge) figure 5: distortion vs. output power (single ended) figure 6: distortion vs. output power (bridge) figure 7: output power vs. frequency (single ended) figure 8: output power vs. frequency (bridge) TDA7370B 7/17 obsolete product(s) - obsolete product(s)
figure 9: supply voltage rejection vs. frequency (single ended) for different values of pin 6 capacitor. figure 10: supply voltage rejection vs. frequency (bridge) for different values of pin 6 capacitor. figure 11: cross-talk vs. frequency (bridge) figure 12: stand-by attenuation vs. threshold voltage (single ended/bridge) figure 14: en input vs. r s (single ended) figure 13: clipping detector average current (pin 10) vs.distortion (single ended) r g r g r g TDA7370B 8/17 obsolete product(s) - obsolete product(s)
figure 17: total power dissipation and efficiency vs. ouput power (single ended) figure 18: total power dissipation and efficiency vs. ouput power (bridge) figure 16: en input vs. r s (bridge) figure 15: en input vs. r s (single ended) r g r g TDA7370B 9/17 obsolete product(s) - obsolete product(s)
output stage the fully complementary output stage was made possible by the development of a new compo- nent: the st exclusive power icv pnp. a novel design based upon the connection shown in fig. 19 has then allowed the full exploitation of its possibilities. the clear advantages this new approach has over classical output stages are as follows: 1 - rail-to-rail output voltage swing with no need of bootstrap capacitors. the output swing is limited only by the vcesat of the output transistors, which are in the range of 0.6 ohm (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 unbal- anced saturation causes a significant power re- duction. the only way to recover power consists of the addition of expensive bootstrap capacitors. 2 - absolute stability without any external compensation. referring to the circuit of fig. 19 the gain v out /v in is greater than unity, approximately 1 + r2/r1. the dc output (v cc /2) is fixed by an aux- iliary amplifier common to all the channels). by controlling the amount of this local feedback it is possible to force the loop gain (a * b ) to less than unity at frequency for which the phase shift is 180 deg. this means that the output buffer is intrinsically stable and not prone to oscillation. most remarkably, the above feature has been achieved in spite of the very low closed loop gain of the amplifier (20 db). 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. other outstanding characteristics: clipping detector output the TDA7370B is equipped with an internal cir- cuit able to detect the output stage saturation pro- viding a current sinking into a open collector out- put (pin 10) when a certain distortion level is reached at each output. this particular function allows gain compression facility whenever the amplifier is overdriven, thus obtaining high quality sound at all listening levels. figure 19: the new output stage figure 20: clipping detection waveforms TDA7370B 10/17 obsolete product(s) - obsolete product(s)
offset control the quiescent output voltage must be as close as possible to its nominal value, so that less undis- torted power would be available. for this reason an input bias current compensa- tion is implemented to reduce the voltage drop across the input resistors, which appears ampli- fied at the outputs. gain internally fixed to 20db in single ended, 26db in bridge advantages of this design choice are in terms of: components and space saving output noise, supply voltage rejection and dis- tortion optimization. silent turn on/off and muting/stand-by func- tion 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 m a typ ; output at- tenuation= 90 db typ). every on/off operation is virtually pop free. furthermore, at turn-on the device stays in muting condition for a time determined by the value as- signed to the svr capacitor (t= csvr * 7,000). while in muting the device outputs becomes in- sensitive to any kinds of signal that may be pre- sent at the input terminals. in other words every transient coming from previous stages produces no unpleasant acoustic effect to the speakers. another situation under which the device is totally muted is whenever the supply voltage drops lower than 7v. this is helpful to pop suppression during the turn-off by battery switch. easy single ended to bridge transition. the change from single ended to bridge configu- rations is made simply by means of a short circuit across the inputs, that is no need of further exter- nal components. high application flexibility the availability of 4 independent channels makes it possible to accomplish several kinds of applica- tions 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 reproduc- tion of low frequencies. built-in protection systems full protection of device and loudspeakers against ac/dc short circuits (to gnd, to vs, across the speakers) . reliable and safe operation in presence of all kinds of short circuit involving the outputs is as- sured by a built-in protection system that operates in the following way: in case of overload, a scr is activated as soon as the current flowing through the output transis- tors overcomes a preset threshold value depend- ing on the chip temperature. the scr causes an interruption of the supply current of the power transistor. the normal working is restored by a re- start circuit going into action as soon as the short circuit is removed. load dump voltage surge the TDA7370B has a circuit which enables it to withstand a voltage pulse train on pins 3 and 13, of the type shown in fig. 22. if the supply voltage peaks to more than 50v, then an lc filter must be inserted between the supply and pins 3 and 13, in order to assure that the pulses at pins 3 and 13 will be held within the limits shown. a suggested lc network is shown in fig. 21. with this network, a train of pulses with amplitude up to 120v and width of 2ms can be applied at point a. this type of protection is on when the supply voltage (pulse or dc) exceeds 18v. for this reason the maximum operating supply volt- age is 18v. figure 21 figure 22 TDA7370B 11/17 obsolete product(s) - obsolete product(s)
polarity inversion high current (up to 10a) can be handled by the device with no damage for a longer period than the blow-out time of a quick 2a fuse (normally connected in series with the supply). this fea- tures is added to avoid destruction, if during fitting to the car, a mistake on the connection of the supply is made. open ground when the radio is in the on condition and the ground is accidentally opened, a standard audio amplifier will be damaged. on the TDA7370B pro- tection diodes are included to avoid any damage. inductive load a protection diode is provided to allow use of the TDA7370B with inductive loads. dc voltage the maximum operating dc voltage for the TDA7370B is 18v. however the device can withstand a dc voltage up to 28v with no damage. this could occur dur- ing winter if two batteries are series connected to crank the engine. thermal shut-down the presence of a thermal limiting circuit offers the following advantages: 1)an overload on the output (even if it is perma- nent), or an excessive ambient temperature can be easily withstood. 2)the heatsink can have a smaller factor of safety compared with that of a conventional circuit. there is no device damage in case of excessive junction temperature: all happens is that p o (and therefore p tot ) and i d are re- duced. the maximum allowable power dissipation de- pends upon the size of the external heatsink (i.e. its thermal resistance); fig. 23 shows the dissi- pable power as a function of ambient temperature for different thermal resistance. loudspeaker protection the TDA7370B guarantees safe operations even for the loudspeaker in case of accidental shortcircuit. whenever a single out to gnd, out to v s short circuit occurs both the outputs are switched off so limiting dangerous dc current flowing through the loudspeaker. figure 23: maximum allowable power dissipation vs. ambient temperature TDA7370B 12/17 obsolete product(s) - obsolete product(s)
clipping detector figures 25 and 26 show an application using the TDA7370B in combination with the sgs-thom- son audioprocessor tda7302. the output clipping is recognized by the microproc- essor (in this application it is simulated by a pc). the detailed way to operate of the system is rep- resented by the flow-chart of fig.24 the controller detects when the clipping is active (minimun detection width fixed by a c29 = 12 nf external capacitor), and reduces the volume (or bass ) by steps of 2 db (with a programmable waiting time), until no more clipping is detected. then the controller waits for a programmable time before increasing the volume again by step of 2 db until clipping is again detected or the panel se- lected volume is reached. practical advantages of this application is a better sound quality deriving from operation under no clipping conditions, which also means the avail- ability of higher undistorted power. what is needed for a demonstration - a xt or at ibm compatible pc, supplied with ega card - a sgs-thomson audioprocessor application disk - a tda 7302 + TDA7370B board - a connector from audioprocessor board to pc parallel port general information in the application shown in figures 25 and 26 the tda7302 audioprocessor works on pc xt or at ibm compatible. control is accomplished by serial bus ( s-bus or i 2 c-bus or spi bus) sent to the test board through the pc parallel port. the pc simulates the behaviour of the microproc- essor in a real application (for example in a car radio) and the buffer is necessary only in this ap- plication for protecting the pc. figure 24: clipping detector control routine TDA7370B 13/17 obsolete product(s) - obsolete product(s)
figure 25: application with tda7302 + TDA7370B (quad stereo) TDA7370B TDA7370B 14/17 obsolete product(s) - obsolete product(s)
figure 26: application wiyh tda7302 + TDA7370B (double bridge) TDA7370B TDA7370B 15/17 obsolete product(s) - obsolete product(s)
multiwatt15 v dim. mm inch min. typ. max. min. typ. max. a 5 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 0.870 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 4.63 5.08 5.53 0.182 0.200 0.218 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 outline and mechanical data TDA7370B 16/17 obsolete product(s) - obsolete product(s)
information furnished is believed to be accurate and reliable. however, stmicroelectronics assumes no responsib ility for the cons equences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. no license is granted by implication or otherwise under any patent or patent rights of stmicroelectronics. specifications mentioned in this p ublication are subject to change without notice. this publication supersedes and replaces all information previously supplied. stmicroelectron ics products are not authorized for use as critical components in life support devices or systems without express written approval of stmicr oelectronics. the st logo is a registered trademark of stmicroelectronics. all other names are the property of their respective owners ? 2003 stmicroelectronics - all rights reserved stmicroelectronics group of companies australia C belgium - brazil - canada - china C czech republic - finland - france - germany - hong kong - india - israel - ital y - japan - malaysia - malta - morocco - singapore - spain - sweden - switzerland - united kingdom - united states www.st.com TDA7370B 17/17 obsolete product(s) - obsolete product(s)

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