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TDA7439STMN/a50avaiTHREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSOR
TDA7439BST ?N/a94avaiTHREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSOR
TDA7439DSTN/a6048avaiTHREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSOR


TDA7439D ,THREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSORELECTRICAL CHARACTERISTICS (refer to the test circuit T = 25°C, V = 9V, R = 10KΩ,amb S LRG = 600Ω, ..
TDA7439DS ,THREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSORELECTRICAL CHARACTERISTICS (refer to the test circuit T = 25°C, V = 9V, R = 10KΩ,amb S LRG = 600Ω, ..
TDA7439DS13TR ,THREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSORBlock DiagramMUXOUTL TREBLE(L) MIN(L) MOUT(L) BIN(L) BOUT(L)4 8 181716 1415L-IN1100KR RM B5L-IN2100 ..
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THS10064CDA ,10-Bit, 6 MSPS ADC Quad Ch. (Config.), DSP/uP Interface, Integ. 16x FIFO, Ch. AutoScan, Low PowerMAXIMUM RATINGS(1)over operating free-air temperature range unless otherwise notedTHS10064DGND to D ..
THS10064CDAR ,10-Bit, 6 MSPS ADC Quad Ch. (Config.), DSP/uP Interface, Integ. 16x FIFO, Ch. AutoScan, Low PowerELECTRICAL CHARACTERISTICS over recommended operating conditions, AV = 5 V, DV = BV = 3.3 V, f = ..
THS10064IDA ,10-Bit, 6 MSPS ADC Quad Ch. (Config.), DSP/uP Interface, Integ. 16x FIFO, Ch. AutoScan, Low Powermaximum ratings” may cause permanent damage to the device. These are stress ratings only, andfuncti ..


TDA7439-TDA7439B-TDA7439D
THREE BANDS DIGITALLY CONTROLLED AUDIO PROCESSOR
TDA7439
THREE BANDS
DIGITALLY CONTROLLED AUDIO PROCESSOR
INPUT MULTIPLEXER
- 4 STEREO INPUTS
- SELECTABLE INPUT GAIN FOR OPTIMAL
ADAPTATION TO DIFFERENT SOURCES
ONE STEREO OUTPUT
TREBLE, MIDDLE AND BASS CONTROL IN
2.0dB STEPS
VOLUME CONTROL IN 1.0dB STEPS
TWO SPEAKER ATTENUATORS:
- TWO INDEPENDENT SPEAKER CONTROL
IN 1.0dB STEPS FOR BALANCE FACILITY
- INDEPENDENT MUTE FUNCTION
ALL FUNCTION ARE PROGRAMMABLE VIA
SERIAL BUS
DESCRIPTION

The TDA7439 is a volume tone (bass, middle and
treble) balance (Left/Right) processor for quality
audio applications in car-radio and Hi-Fi systems.
Selectable input gain is provided. Control of all
the functions is accomplished by serial bus.
The AC signal setting is obtained by resistor net-
works and switches combined with operational
amplifiers.
Thanks to the used BIPOLAR/CMOS Technology,
Low Distortion, Low Noise and DC stepping are
obtained
BLOCK DIAGRAM

ABSOLUTE MAXIMUM RATINGS
THERMAL DATA
QUICK REFERENCE DATA
PIN CONNECTION (Top view)
TDA7439

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ELECTRICAL CHARACTERISTICS (refer to the test circuit Tamb = 25°C, VS = 9V, RL= 10KΩ,
RG = 600Ω, all controls flat (G = 0dB), unless otherwise specified)
SUPPLY
NOTE1:
1) The device is functionally good at Vs = 5V. a step down, on Vs, to 4V does’t reset the device.
2) BASS, MIDDLE and TREBLE response: The center frequency and the response quality can be chosen by the external circuitry.
TDA7439

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ELECTRICAL CHARACTERISTICS (continued.)
TEST CIRCUIT
TDA7439

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APPLICATION SUGGESTIONS
The first and the last stages are volume control
blocks. The control range is 0 to -47dB (mute) for
the first one, 0 to -79dB (mute) for the last one.
Both of them have 1dB step resolution.
The very high resolution allows the implementation
of systems free from any noisy acoustical effect.
The TDA7439 audioprocessor provides 3 bands
tones control.
Bass, Middle Stages

The Bass and the middle cells have the same
structure.
The Bass cell has an internal resistor Ri = 44KΩ
typical.
The Middle cell has an internal resistor Ri = 25KΩ
typical.
Several filter types can be implemented, connect-
ing external components to the Bass/Middle IN
and OUT pins.
The fig.1 refers to basic T Type Bandpass Filter
starting from the filter component values (R1 in-
ternal and R2,C1,C2 external) the centre fre-
quency Fc, the gain Av at max. boost and the fil-
ter Q factor are computed as follows:
FC = 1
2 ⋅ π ⋅√  R1 ⋅ R2 ⋅ C1 ⋅ C2
AV = R2 C2 + R2 C1 + Ri C1
R2 C1 + R2 C2
Q = √ R1 ⋅ R2 ⋅ C1 ⋅ C2
R2 C1 + R2 C2
Viceversa, once Fc, Av, and Ri internal value are
fixed, the external components values will be:
C1 = AV − 1
2 ⋅ π ⋅ FC ⋅ Ri ⋅ Q C2 = Q2 ⋅ C1
AV − 1 − Q2
R2 = AV − 1 − Q2
2 ⋅ π ⋅ C1 ⋅ FC ⋅ (AV − 1) ⋅Q
Treble Stage

The treble stage is a high pass filter whose time
constant is fixed by an internal resistor (25KΩ
typical) and an external capacitor connected be-
tween treble pins and ground
Typical responses are reported in Figg. 10 to 13.
CREF

The suggested 10μF reference capacitor (CREF)
value can be reduced to 4.7μF if the application
requires faster power ON.
Figure 1.
Figure 2: THD vs. frequency Figure 3: THD vs. RLOAD
TDA7439

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Figure 4: Channel separation vs. frequency
Figure 7: Treble response
Figure 8: Typical tone response
Figure 5: Bass response
Figure 6: Middle response
TDA7439

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2 C BUS INTERFACEData transmission from microprocessor to the
TDA7439 and vice versa takes place through the
2 wires I2 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. 9, 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.10 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 tran-
sition of the SDA line while SCL is HIGH.
Byte Format

Every byte transferred on the SDA line must con-
tain 8 bits. Each byte must be followed by an ac-
knowledge 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. 11). The peripheral (audio processor) that ac-
knowledges has to pull-down (LOW) the SDA line
during this clock pulse.
The audio processor which has been addressed
has to generate an acknowledge after the recep-
tion 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 gen-
erate the STOP information in order to abort the
transfer.
Transmission without Acknowledge

Avoiding to detect the acknowledge of the audio
processor, the μP can use a simpler 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.
Figure 9: Data Validity on the I
2 CBUS
Figure 10: Timing Diagram of I
2 CBUS
Figure 11: Acknowledge on the I2 CBUS
TDA7439

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SOFTWARE SPECIFICATION
Interface Protocol
The interface protocol comprises:
A start condition (S)
A chip address byte, containing the TDA7439
address
A subaddress bytes
A sequence of data (N byte + acknowledge)
A stop condition (P)
ACK = Acknowledge
S = Start
P = Stop
A = Address
B = Auto Increment
MSB LSB MSB LSB MSB LSB
CHIP ADDRESS
D96AU420
SUBADDRESS DATA 1 to DATA n
EXAMPLES
No Incremental Bus

The TDA7439 receives a start condition, the cor-
rect chip address, a subaddress with the B = 0
(no incremental bus), N-data (all these data con-
cern the subaddress selected), a stop condition.
MSB LSB MSB LSB MSB LSB
CHIP ADDRESS
D96AU421
SUBADDRESS DATA
Incremental Bus

The TDA7439 receive a start conditions, the cor-
rect chip address, a subaddress with the B = 1
(incremental bus): now it is in a loop condition
with an autoincrease of the subaddress whereas
SUBADDRESS from "XXX1000" to "XXX1111" of
DATA are ignored.
The DATA 1 concern the subaddress sent, and
the DATA 2 concern the subaddress sent plus
one in the loop etc, and at the end it receivers the
stop condition.
MSB LSB MSB LSB MSB LSB
CHIP ADDRESS
D96AU422
SUBADDRESS DATA 1 to DATA n
TDA7439

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