TDA738 DIGITAL CONTROLLED STEREO AUDIO PROCESSOR INPUT MULTIPLEXER: - 4 STEREO INPUTS - SELECTABLE INPUT GAIN FOR OPTIMAL ADAPTION TO DIFFERENT SOURCES INPUT AND OUTPUT FOR EXTERNAL EQUALIZER OR NOISE REDUCTION SYS- TEM VOLUME CONTROL IN.25dB STEPS TREBLE AND BASS CONTROL FOUR SPEAKER ATTENUATORS: - 4 INDEPENDENT SPEAKERS CONTROL IN.25dB STEPS FOR BALANCE AND FADER FACILITIES - INDEPENDENT MUTE FUNCTION ALL FUNCTIONS PROGRAMMABLE VIA SE- RIALI 2 CBUS DESCRIPTION The TDA738 is a volume, tone (bass and treble) balance (Left/Right) and fader (front/rear) processor for quality audio applications in car radio and Hi-Fi systems. DIP28 SO28 ORDERING NUMBERS: TDA738 TDA738D Selectable input gain is provided. Control is accomplishedby serial I 2 C bus microprocessor interface. The AC signal setting is obtained by resistor networks andswitches combined with operationalamplifiers. Thanks to the used BIPOLAR/CMOS Tecnology, Low Distortion, Low Noise and Low DC stepping are obtained. PIN CONNECTION (Top view) November 999 /4
TDA738 TEST CIRCUIT THERMAL DATA Symbol Description SO28 DIP28 Unit R th j-pins Thermal Resistance Junction-pins max 85 65 C/W ABSOLUTE MAXIMUM RATINGS Symbol Parameter Value Unit V S Operating Supply Voltage.2 V T amb Operating Ambient Temperature -4 to 85 C T stg Storage Temperature Range -55 to +5 C QUICK REFERENCE DATA Symbol Parameter Min. Typ. Max. Unit V S Supply Voltage 6 9 V V CL Max. input signal handling 2 Vrms THD Total Harmonic Distortion V = Vrms f = KHz.. % S/N Signal to Noise Ratio 6 db S C Channel Separation f = KHz 3 db Volume Control.25dB step -78.75 db Bass and Treble Control 2db step -4 +4 db Fader and Balance Control.25dB step -38.75 db Input Gain 6.25dB step 8.75 db Mute Attenuation db 2/4
TDA738 BLOCK DIAGRAM LEFT INPUTS RIGHT INPUTS C C2 C3 C4 C5 C6 C7 C8 4x 2.2µF 4x 2.2µF C 2.2µF OUT(L) IN(L) 7 6 L 5 L L2 4 L2 L3 3 L3 L4 2 L4 INPUT SELECTOR + GAIN R4 8 R4 R3 9 R3 R2 R2 R R SUPPLY 2 3 7 6 VCC AGND CREF OUT(R) IN(R) C9 22µF C 2.2µF nf C4 BOUT(L) 5.6K R2 nf C5 BIN(L) C7 2.7nF TREBLE(L) 9 8 4 RB VOL BASS TREBLE I 2 C BUS DECODER + LATCHES VOL BASS TREBLE RB 2 2 5 BOUT(R) BIN(R) TREBLE(R) nf C2 nf C3 5.6K R 2.7nF C6 SPKR ATT MUTE SPKR ATT MUTE SPKR ATT MUTE SPKR ATT MUTE 25 23 28 27 26 24 22 D95AU265 OUT LEFT FRONT OUT LEFT REAR SCL SDA BUS DIGGND OUT RIGHT FRONT OUT RIGHT REAR 3/4
TDA738 ELECTRICAL CHARACTERISTICS (refer to the test circuit Tamb = 25 C, VS = 9V, RL = KΩ, RG = 6Ω, all controls flat (G = ), f = KHz unless otherwise specified) Symbol Parameter Test Condition Min. Typ. Max. Unit SUPPLY V S Supply Voltage 6 9 V IS Supply Current 4 8 ma SVR Ripple Rejection 6 85 db INPUT SELECTORS R II Input Resistance Input, 2, 3, 4 35 5 7 KΩ V CL Clipping Level 2 2.5 Vrms SIN Input Separation (2) 8 db R L Output Load resistance pin 7, 7 2 KΩ G INmin Min. Input Gain - db G INmax Max. Input Gain 7 8.75 2 db G STEP Step Resolution 5 6.25 7.5 db e IN Input Noise G = 8.75dB 2 µv V DC DC Steps adjacent gain steps 4 2 mv G = 8.75 to Mute 4 mv VOLUME CONTROL R IV Input Resistance 2 33 5 kω C RANGE Control Range 7 75 8 db A VMIN Min. Attenuation - db AVMAX Max. Attenuation 7 75 8 db A STEP Step Resolution.5.25.75 db E A Attenuation Set Error Av = to -2dB Av = -2 to -6dB -.25-3.25 2 E T Tracking Error 2 db V DC DC Steps adjacent attenuation steps From db to Av max SPEAKER ATTENUATORS C range Control Range 35 37.5 4 db S STEP Step Resolution.5.25.75 db E A Attenuation set error.5 db A MUTE Output Mute Attenuation 8 db VDC DC Steps adjacent att. steps from to mute BASS CONTROL () Gb Control Range Max. Boost/cut +2 +4 +6 db B STEP Step Resolution 2 3 db RB Internal Feedback Resistance 34 44 58 KΩ TREBLE CONTROL () Gt Control Range Max. Boost/cut +3 +4 +5 db T STEP Step Resolution 2 3 db.5 3 7.5 3 db db mv mv mv mv 4/4
TDA738 ELECTRICAL CHARACTERISTICS (continued) Symbol Parameter Test Condition Min. Typ. Max. Unit AUDIO OUTPUTS V OCL Clipping Level d =.3% 2 2.5 Vrms R L Output Load Resistance 2 KΩ C L Output Load Capacitance nf R OUT Output resistance 3 75 2 Ω V OUT DC Voltage Level 4.2 4.5 4.8 V GENERAL e NO Output Noise BW = 2-2KHz, flat output muted all gains = db 2.5 5 5 A curve all gains = db 3 µv S/N Signal to Noise Ratio all gains = db; VO = Vrms 6 db d Distortion A V =,V IN = Vrms A V = -2dB V IN = Vrms V IN =.3Vrms Sc Channel Separation left/right 8 3 db Total Tracking error A V = to -2dB -2 to -6 db 2 db db BUS INPUTS Notes: V IL Input Low Voltage V V IH Input High Voltage 3 V I IN Input Current -5 +5 µa V O Output Voltage SDA Acknowledge I O =.6mA.4 V () Bass and Treble response see attached diagram (fig.9). The center frequency and quality of the resonance behaviour can be choosen by the external circuitry. A standard first order bass response can be realized by a standard feedback network (2) The selected input is grounded thru the 2.2µF capacitor...9.4..3 µv µv % % % Figure : Noise vs. Volume/Gain Settings Figure 2: Signal to Noise Ratio vs. Volume Setting 5/4
TDA738 Figure 3: Distortion & Noise vs. Frequency Figure 4: Distortion & Noise vs. Frequency Figure 5: Distortion vs. Load Resistance Figure 6: Channel Separation (L R) vs. Frequency Figure 7: Input Separation (L L2, L3, L4) vs. Frequency Figure 8: Supply Voltage Rejection vs. Frequency 6/4
TDA738 Figure 9: Output Clipping Level vs. Supply Voltage Figure : Quiescent Current vs. Supply Voltage Figure : Supply Current vs. Temperature Figure 2: Bass Resistance vs. Temperature Figure 3: Typical Tone Response (with the ext. components indicated in the test circuit) 7/4
TDA738 I 2 C BUS INTERFACE Data transmission from microprocessor to the TDA738 and viceversa takes place thru the 2 wires I 2 C BUS interface, consisting of the two lines SDA and SCL (pull-up resistors to positive supply voltage must be connected). Data Validity As shown in fig. 4, the data on the SDA line must be stable during the high period of the clock. The HIGH and LOW state of the data line can only change when the clock signal on the SCL line is LOW. Start and Stop Conditions As shown in fig.5 a start condition is a HIGH to LOW transition of the SDA line while SCL is HIGH. The stop condition is a LOW to HIGH transition of the SDA line while SCL is HIGH. Figure 4: Data Validity on the I 2 CBUS Byte Format Every byte transferred on the SDA line must contain 8 bits. Each byte must be followed by an acknowledge bit. The MSB is transferred first. Acknowledge The master (µp) puts a resistive HIGH level on the SDA line during the acknowledge clock pulse (see fig. 6). The peripheral (audioprocessor) that acknowledges has to pull-down (LOW) the SDA line during the acknowledge clock pulse, so that the SDA line is stable LOW during this clock pulse. The audioprocessor which has been addressed has to generate an acknowledge after the reception of each byte, otherwise the SDA line remains at the HIGH level during the ninth clock pulse time. In this case the master transmitter can generate the STOP information in order to abort the transfer. Transmission without Acknowledge Avoiding to detect the acknowledge of the audioprocessor, the µp can use a simplier transmission: simply it waits one clock without checking the slave acknowledging, and sends the new data. This approach of course is less protected from misworking and decreases the noise immunity. Figure 5: Timing Diagram of I 2 CBUS Figure 6: Acknowledge on the I 2 CBUS 8/4
TDA738 SOFTWARE SPECIFICATION Interface Protocol The interface protocol comprises: A start condition (s) A chip address byte, containing the TDA738 address (the 8th bit of the byte must be ). The TDA738 must always acknowledge at the end of each transmitted byte. A sequence of data (N-bytes + acknowledge) A stop condition (P) TDA738 ADDRESS MSB first byte LSB MSB LSB MSB LSB S ACK DATA ACK DATA ACK P ACK = Acknowledge S = Start P = Stop MAX CLOCK SPEED kbits/s Data Transferred (N-bytes + Acknowledge) SOFTWARE SPECIFICATION Chip address MSB LSB DATA BYTES MSB LSB FUNCTION B2 B B B B B G B B B B B G C3 C3 S2 C2 C2 Ax =.25dB steps; Bx = db steps; Cx = 2dB steps; Gx = 6.25dB steps A A A A A S C C A A A A A S C C Volume control Speaker ATT LR Speaker ATT RR Speaker ATT LF Speaker ATT RF Audio switch Bass control Treble control 9/4
TDA738 SOFTWARE SPECIFICATION (continued) DATA BYTES (detailed description) Volume MSB LSB FUNCTION B2 B B A A Volume.25dB steps -.25-2.5-3.75-5 -6.25-7.5-8.75 B2 B B A A Volume db steps For example a volume of -45dB is given by: - -2-3 -4-5 -6-7 Speaker Attenuators MSB LSB FUNCTION B B B B B B B B For example attenuation of 25dB on speaker RF is given by: A A A A A A A A Speaker LF Speaker RF Speaker LR Speaker RR -.25-2.5-3.75-5 -6.25-7.5-8.75 - -2-3 Mute /4
TDA738 Audio Switch MSB LSB FUNCTION G G S2 S S Audio Switch For example to select the stereo 2 input with a gain of +2.5dB the 8bit string is: Stereo Stereo 2 Stereo 3 Stereo 4 Not allowed Not allowed Not allowed Not allowed +8.75dB +2.5dB +6.25dB db Bass and Treble C3 C3 C2 C2 C C C C Bass Treble -4-2 - -8-6 -4-2 2 4 6 8 2 4 C3 = Sign For example Bass at -db is obtained by the following 8 bit string: /4
TDA738 DIM. mm inch MIN. TYP. MAX. MIN. TYP. MAX. OUTLINE AND MECHANICAL DATA A 2.65.4 a..3.4.2 b.35.49.4.9 b.23.32.9.3 C.5.2 c 45 (typ.) D 7.7 8..697.73 E.65.394.49 e.27.5 e3 6.5.65 F 7.4 7.6.29.299 L.4.27.6.5 S 8 (max.) SO28 2/4
TDA738 DIM. mm inch MIN. TYP. MAX. MIN. TYP. MAX. OUTLINE AND MECHANICAL DATA a.63.25 b.45.8 b.23.3.9.2 b2.27.5 D 37.34.47 E 5.2 6.68.598.657 e 2.54. e3 33.2.3 F 4..555 I 4.445.75 L 3.3.3 DIP28 3/4
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