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| d a t a sh eet product speci?cation file under integrated circuits, ic01 april 1991 integrated circuits TDA1596 if amplifier/demodulator for fm radio receivers
april 1991 2 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 general description the TDA1596 provides if amplification, symmetrical quadrature demodulation and level detection for quality home and car fm radio receivers and is suitable for both mono and stereo reception. it may also be applied to common front-ends, stereo decoders and am receiver circuits. features simulates behaviour of a ratio detector (internal field strength and detuning-dependent voltage for dynamic af signal muting) mono/stereo blend and field strength indication control voltage three-state mode switch for fm, mute-on / fm, mute-off / fm-off internal compensation of af signal total harmonic distortion (thd) two open collector stop pulse outputs for microcomputer tuning control (can be one stop pulse output by wired-anding) internal reference voltage source built-in hum and ripple rejection circuits quick reference data see also data sheet for TDA1596t package outline 18-lead dil; plastic (sot102); sot102-1; 1996 august 06. parameter conditions symbol min. typ. max. unit supply voltage (pin 1) v p 7.5 8.5 12.0 v supply current (pin 1) v p = 8.5 v; i 2 = i 7 = 0 ma i p - 20 26 ma af output voltage (rms value) v 18(rms) = 10 mv v 4(rms) 180 200 220 mv signal-to-noise ratio v 18(rms) = 10 mv; f m = 400 hz; d f = 75 khz s/n - 82 - db total harmonic distortion v 18(rms) = 10 mv; f m = 1 khz; i 7 = 0 ma; d f = 75 khz; fm mute on; without de-emphasis; without detuning thd - 0.1 0.3 % operating ambient temperature range t amb - 40 -+ 85 c april 1991 3 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.1 block diagram and application circuit. (1) connecting pin 11 to ground is only allowed for measuring the current at pin 14. it is not for use in application. (2) in the fm, mute-on condition the unweighted level detector output is available from pin 3. in the fm, mute-off condition the variable resistor at pin 3 can be adjusted for minimum 2nd harmonic distortion at pin 4. april 1991 4 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 pinning fig.2 pinning diagram. 1v p supply voltage 2 lva level voltage adjustment 3 ulv unweighted level output/k2 adjustment 4 afo af output 5v ref reference voltage output 6 wlv weighted level voltage output 7 msw mode switch 8 ddv detune detector voltage 9 dmi1 demodulator input 1 10 dmi2 demodulator input 2 11 tsw tau switch 12 st1 stop pulse output 1 13 st0 stop pulse output 0 14 mtv mute voltage 15 gnd ground 16 lfd1 if limiter feedback 1 17 lfd2 if limiter feedback 2 18 ifi if input april 1991 5 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 functional description limiter-ampli?er this has five stages of if amplification using balanced differential limiter-amplifiers with emitter-follower coupling. decoupling of the stages from the voltage supply lines and an internal high-ohmic dc feed-back loop give a very stable if performance. the amplifier gain is virtually independent from temperature changes. fm demodulator the demodulator is fully balanced and comprises two cross-coupled differential amplifiers. quadrature detection of the fm signal is performed by feeding one differential amplifier directly from the limiter-amplifier output, and the other via an external 90 phase-shifting network. the demodulator has good stability and its zero cross-over shift is small. the bandwidth of the demodulator output is restricted to approximately 1 mhz by an internal low-pass filter. thd compensation this circuit compensates non-linearities introduced by demodulation. for this to operate correctly the demodulator circuit between pins 9 and 10 must have a loaded q-factor of 19. consequently there is no need for the demodulator tuned circuit to be adjusted for minimum thd, instead the adjustment criterium is for a symmetrical stop pulse. mute attenuator and af output the control voltage for the mute attenuator at pin 14 is generated from the values of the level detector and the detuning detector outputs. the mute attenuator has a fast attack and a slow decay which is determined by the capacitor at pin 14. the af signal is passed via the mute attenuator to the output at pin 4. a weighted control voltage, available from pin 6, is obtained from the mute attenuator control voltage via a buffer-amplifier which introduces an additional voltage shift and gain. level detector the level detector generates a voltage output which is proportional to the field strength of the input signal. the unweighted level detector output is available when the mode switch is operating in the fm, mute-on condition. tuning-stop outputs the open collector outputs stop-0 and stop-1 (from pins 13 and 12 respectively) are voltages derived from the detuning level and the field strength of the input signal. if only one tuning-stop output is required, pins 12 and 13 may be tied together. april 1991 6 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 ratings limiting values in accordance with the absolute maximum system (iec 134) * equivalent to discharging a 100 pf capacitor through a 1.5 k w series resistor. parameter symbol min. max. unit supply voltage (pin 1) v p = v 1-15 - 0.3 + 16 v reference voltage range (pin 5) v 5-15 - 0.3 + 10 v level adjustment range (pin 2) v 2-15 - 0.3 + 10 v mode switch voltage range (pin 7) v 7-15 - 0.3 + 16 v control input voltage range (pin 11) v 11-15 - 0.3 + 6v thd compensation/unweighted ?eld strength voltage range (pin 3) v 3-15 - 0.3 + 16 v tuning-stop output voltage range stop-0 (pin 13) v 13-15 - 0.3 + 16 v stop-1 (pin 12) v 12-15 - 0.3 + 16 v tuning-stop output current stop-0 (pin 13) i 13 - 2ma stop-1 (pin 12) i 12 - 2ma storage temperature range t stg - 55 + 150 c operating ambient temperature range t amb - 40 + 85 c electrostatic handling * all pins except pins 5 and 6 v es - 2000 + 2000 v pin 5 v es - 2000 + 900 v pin 6 v es - 2000 + 1600 v april 1991 7 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 characteristics f = 10.7 mhz; v p = v 1-15 = 8.5 v; v i = v 18(rms) = 1 mv; t amb = 25 c; measured in the circuit of fig.3; tuned circuit at pins 9, 10 aligned for symmetrical stop pulses; all voltages are referred to ground (pin 15); unless otherwise speci?ed parameter symbol min. typ. max. unit supplies supply voltage v p = v 1 7.5 8.5 12.0 v supply current at i 2 = i 7 = 0 ma i 1 - 20 26 ma fm demodulator input impedance r 9-10 25 40 55 k w c 9-10 - 6 - pf dc output voltage (no-signal condition) at v 9, 10(p-p) 100 m v; v 18(rms) 5 m vv 4 2.75 3.10 3.45 v output impedance r 4-15 - 400 -w mute attenuator control voltage control voltage (pin 14) at v 18(rms) 5 m vv 14 - 2.0 - v at v 18(rms) = 1 mv v 14 - 3.45 - v output impedance (pin 14) r 14-15 -- 2.0 m w level shift input (pin 2) internal bias voltage at i 2 = 0 ma v 2 - 1.4 - v input impedance r 2-15 15 -- k w internal muting (fig.4) internal attenuation of signals 22.5 khz detuning 80 khz a = 20log[ d v 4 (fm mute-off)/ d v 4 (fm)] at v 14 3 1 v 5 a - 0 - db at v 14 = 0.77 v 5 a 1.5 3.0 4.5 db at v 14 = 0.55 v 5 a - 20 - db attack and decay (pin 14) pin 11 connected to ground * charge current + i 14 - 8 -m a discharge current - i 14 - 120 -m a pin 11 connected to v ref charge current + i 14 - 100 -m a discharge current - i 14 - 120 -m a april 1991 8 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 level detector dependence of output voltage on temperature - 3.3 - mv/vk output impedance r 6 -- 500 w dependence of output voltage (pin 6) on input voltage (pin 18) (fig.5): v 18(rms) 5 m v; i 2 = i 7 = 0 ma v 6 0.1 0.7 1.3 v v 18(rms) = 1 mv; i 2 = i 7 = 0 ma v 6 3.0 3.6 4.2 v slope of output voltage (pin 6) for input voltage range v 18(rms) 3 50 m v to v 18(rms) 50 mv 1.4 1.7 2.0 v/20 db dependence of output voltage (pin 6) on detuning (fig.6) at input voltage v 18(rms) = 10 mv: detuning 45 khz d v 6 -- 0.2 v detuning = for v 6 = 1.8 v d f90 - 160 khz detuning = 200 khz v 6 0.5 0.7 0.9 v slope of output voltage with detuning = 125 20 khz at v 18(rms) = 10 mv | d v 6 / d f| - 35 - mv/khz level shift control (pin 2) (fig.7) adjustment range d v 6 1.6 2.0 - v adjustment gain - ( d v 6 / d v 2 ) - 1.7 - v output voltage at v 2 = v 5; v 18(rms) 5 m vv 6 -- 0.3 v low-pass ?lter at pin 8 output voltage at i 7 = 0 ma; v 18(rms) 5 m vv 8 - 2.2 - v internal resistance r 8(int) 12 25 50 k w parameter symbol min. typ. max. unit d v 6 v 6 d t -------------- - d v 6 20 d v 18 log ---------------------------- - april 1991 9 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 * connecting pin 11 to ground is only allowed for measuring the current at pin 14. it is not for use in application. ** without input voltage. tuning-stop detector (figs 8 and 9) stop-0: detuning at v 18(rms) = 10 mv for v 13 3 3.5 v + d f -- 10 khz for v 13 0.3 v + d f18 -- khz stop-1: detuning at v 18(rms) = 10 mv for v 12 3 3.5 v -d f -- 10 khz for v 12 0.3 v -d f18 -- khz dependence of stop-0, stop-1 on input voltage (pin 18) input voltage (rms value) for v 12 = v 13 3 3.5 v v 18(rms) 250 --m v input voltage (rms value) for v 12 = v 13 0.3 v v 18(rms) -- 50 m v output voltage when i 12 = i 13 = 1 ma v 12, 13 -- 0.3 v mode switch and pin 3 (fig.10) fm-off position control voltage for 60 db muting depth v 7 -- 1.4 v fm, mute-on position (pin 3 = output) internal bias voltage at r 7-15 3 10 m w v 7 - 2.8 - v input current |i 7 | -- 2.5 m a output voltage with r 3-15 = 10 k w ; c 3-15 3 1 nf ** v 3 - 2 - v output impedance for v 18 = 5 m v; i 3 = 500 m ar 3-15 -- 100 w fm, mute-off position (pin 3 = input) control voltage v 7 0.9 v 5 -- v input current at v 7 = v 5 i 7 -- 15 m a input resistance r 3-15 1 -- m w reference voltage source output voltage at i 5 = - 1 ma v 5 3.3 3.7 4.1 v output impedance at i 5 = - 1 ma d v 5 / d i 5 - 40 80 w temperature coef?cient tc - 3.3 - mv/k parameter symbol min. typ. max. unit april 1991 10 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 operating characteristics f = 10.7 mhz; v 18(rms) = 1 mv; deviation ( d f) = 22.5 khz; modulation frequency (f m ) = 400 hz; de-emphasis (pin 4) = 50 m s; test circuit as per fig.3; tuned circuit (q l = 19) aligned for symmetrical stop pulses; t amb = +25 c; unless otherwise speci?ed parameter symbol min. typ. max. unit af output voltage (rms value) at v 18(rms) = 10 mv v 4(rms) 180 200 220 mv start of limiting (fm, mute-off); (rms value) (fig.11) v 18(rms) 14 22 35 m v dependence of signal-to-noise ratio (in noise frequency band 250 hz to 15 khz, unweighted) on input voltage for s/n = 26 db v 18(rms) - 15 -m v for s/n = 46 db v 18(rms) - 60 -m v at v 18(rms) = 10 mv; d f = 75 khz s/n - 82 - db thd (fm, mute-on) at v 18(rms) = 10 mv; d f = 75 khz; f m = 1 khz; without detuning; without de-emphasis; i 7 = 0 ma thd - 0.1 0.3 % dynamic mute attenuation (fig.12) with f m = 100 khz; d f = 75 khz a d - 16 - db slope of attenuation curve a d d f - 0.8 - db/khz thd (fm, mute-on) at v 18(rms) = 10 mv; d f = 75 khz; f m = 1 khz; detuning 25 khz without de-emphasis; i 7 = 0 ma (fig.13) thd -- 0.6 % thd (fm, mute-off and compensated via pin 3) at v 18(rms) = 10 mv; d f = 75 khz; f m = 1 khz; v 7 = v 5 thd - 0.07 0.25 % voltage range at pin 3 for thd compensation v 3 0 - v 5 v am suppression (fm, mute-off) with amplitude modulation at 30%; input voltage range v 18 = 300 m v to 100 mv (fig.14) - 65 - db power supply ripple rejection = 20log [ d v 1 / d v 4 ]3336 - db mute attenuation (fm-off) = 20log [v 4(fm-on /v 4(fm-off) ]60 -- db a d 20 v 4 fmmute off C () v 4 fm mute , on C () ----------------------------------------------------- - log = april 1991 11 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.3 test circuit. april 1991 12 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.4 typical curve of internal attenuation showing the relationship between the mute attenuator control voltage (pin 14) and mute attenuation, i 2 = i 7 = 0 ma. fig.5 weighted field strength output voltage (pin 6) as a function of input voltage (pin 18); r 6-15 3 10 k w ; i 2 = i 7 = 0 ma. april 1991 13 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.6 weighted field strength output voltage (pin 6) as a function of detuning; r 6-15 3 10 k w ; i 2 = i 7 = 0 ma; v 18 = 10 mv. fig.7 adjustment range of weighted field strength output voltage (pin 6) with level shift control (pin 2); r 6-15 3 10 k w ; i 7 = 0 ma. april 1991 14 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.8 stop-0 and stop-1 output voltages as a function of detuning, measured at v 18 = 10 mv. (b) stop-1 (a) stop-0. april 1991 15 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.9 stop-0 or stop-1 output voltages as a function of input voltage at pin 18. fig.10 switch levels at pin 7. april 1991 16 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.11 audio signal ( d f = 22.5 khz; f m = 1 khz) and noise as functions of input voltage at pin 18; measured with 50 m s de-emphasis. (b) mode switch at fm, mute-off (a) mode switch at fm, mute-on april 1991 17 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.12 dynamic mute attenuation as a function of frequency deviation for modulation frequencies of 40, 60, 80 and 100 khz. fig.13 thd as a function of detuning; mode switch at fm, mute-on position; d f = 75 khz; f m = 1 khz; v 18(rms) = 10 mv. april 1991 18 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 fig.14 typical curves showing am suppression for an input signal having frequency modulation at d f = 22.5 khz and f m = 1 khz, and amplitude modulation of 30% at a frequency of 400 hz; de-emphasis time = 50 m s and bandwidth = 250 hz to 15 khz. (b) mode switch at fm, mute-off (a) mode switch at fm, mute-on. april 1991 19 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 package outline references outline version european projection issue date iec jedec eiaj sot102-1 93-10-14 95-01-23 unit a max. 12 b 1 (1) (1) (1) b 2 cd e e m z h l mm dimensions (inch dimensions are derived from the original mm dimensions) a min. a max. b max. w m e e 1 1.40 1.14 0.53 0.38 0.32 0.23 21.8 21.4 6.48 6.20 3.9 3.4 0.254 2.54 7.62 8.25 7.80 9.5 8.3 0.85 4.7 0.51 3.7 inches 0.055 0.044 0.021 0.015 0.013 0.009 1.40 1.14 0.055 0.044 0.86 0.84 0.26 0.24 0.15 0.13 0.01 0.10 0.30 0.32 0.31 0.37 0.33 0.033 0.19 0.020 0.15 m h c (e ) 1 m e a l seating plane a 1 w m b 1 b 2 e d a 2 z 18 1 10 9 b e pin 1 index 0 5 10 mm scale note 1. plastic or metal protrusions of 0.25 mm maximum per side are not included. dip18: plastic dual in-line package; 18 leads (300 mil) sot102-1 april 1991 20 philips semiconductors product speci?cation if ampli?er/demodulator for fm radio receivers TDA1596 soldering introduction there is no soldering method that is ideal for all ic packages. wave soldering is often preferred when through-hole and surface mounted components are mixed on one printed-circuit board. however, wave soldering is not always suitable for surface mounted ics, or for printed-circuits with high population densities. in these situations reflow soldering is often used. this text gives a very brief insight to a complex technology. a more in-depth account of soldering ics can be found in our ic package databook (order code 9398 652 90011). soldering by dipping or by wave the maximum permissible temperature of the solder is 260 c; solder at this temperature must not be in contact with the joint for more than 5 seconds. the total contact time of successive solder waves must not exceed 5 seconds. the device may be mounted up to the seating plane, but the temperature of the plastic body must not exceed the specified maximum storage temperature (t stg max ). if the printed-circuit board has been pre-heated, forced cooling may be necessary immediately after soldering to keep the temperature within the permissible limit. repairing soldered joints apply a low voltage soldering iron (less than 24 v) to the lead(s) of the package, below the seating plane or not more than 2 mm above it. if the temperature of the soldering iron bit is less than 300 c it may remain in contact for up to 10 seconds. if the bit temperature is between 300 and 400 c, contact may be up to 5 seconds. definitions life support applications these products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. philips customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify philips for any damages resulting from such improper use or sale. data sheet status objective speci?cation this data sheet contains target or goal speci?cations for product development. preliminary speci?cation this data sheet contains preliminary data; supplementary data may be published later. product speci?cation this data sheet contains ?nal product speci?cations. limiting values limiting values given are in accordance with the absolute maximum rating system (iec 134). stress above one or more of the limiting values may cause permanent damage to the device. these are stress ratings only and operation of the device at these or at any other conditions above those given in the characteristics sections of the speci?cation is not implied. exposure to limiting values for extended periods may affect device reliability. application information where application information is given, it is advisory and does not form part of the speci?cation. |
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