STMICROELECTRONICS TDA7461N_03

TDA7461N
®
CAR RADIO SIGNAL PROCESSOR
HIGH PERFORMANCE SIGNAL PROCESSOR FOR CAR RADIO SYSTEMS
DEVICE INCLUDES AUDIO PROCESSOR,
STEREO DECODER, NOISEBLANKER AND
MULTIPATH DETECTOR
NO EXTERNAL COMPONENTS REQUIRED
FULLY PROGRAMMABLE VIA I2C BUS
LOW DISTORTION
LOW NOISE
SO28
DIP28
ORDERING NUMBERS:
TDA7461ND
DESCRIPTION
The TDA7461N is a high performance signal
processor specifically designed for car radio applications.
The device includes a complete audioprocessor
and a stereo decoder with noiseblanker,
stereoblend and all signal processing functions
necessary for state-of-the-art as well as future car
radio systems.
Switched-capacitors design technique allows to
obtain all these features without external compo-
TDA7461N
nents or adjustments. This means that higher
quality and reliability walks alongside an overall
cost saving.
The CSP is fully programmable by I2C bus interface allowing to customize key device parameters
and especially filter characteristics.
The BICMOS process combined with the optimized signal processing assure low noise and
low distortion performances.
AM
CASS R
CASS L
PHONE
PH GND
10
17
MIXING
STAGE
LOUDNESS
28
SOFT
MUTE
VOLUME
TREBLE
ACINR
SMUTE
CDR
5
ACINL
CDG
6
ACOUTR
CDL
7
ACOUTL
BLOCK DIAGRAM
27
1
2
OUT LF
BASS
OUT RR
3
4
9
OUT LR
OUT RF
INPUT
MULTIPLEXER
+
AUTO ZERO
PHONE
23
25
22
24
18
BEEP
I2C BUS
DIGITAL CONTROL
8
19
16
15
MPX
VS
11
21
PILOT
CANCELLATION
80KHz
LP
SUPPLY
20
GND
October 2003
PLL
26
CREF
DEMODULATOR
+ STEREO ADJUST
+ STEREO BLEND
25KHz
LP
S&H
OUT LR
OUT LF
OUT RR
OUT RF
SCL
SDA
MUX R
MUX L
HIGH
CUT
CONTROL
D
PIL
DET
MULTIPATHDETECTOR
13
MPIN
NOISE
BLANKER
14
MPOUT
PULSE
FORMER
A
12
LEVEL
D97AU646A
1/32
TDA7461N
ABSOLUTE MAXIMUM RATINGS
Symbol
VS
Tamb
Tstg
Parameter
Value
Operating Supply Voltage
Unit
10.5
V
Operating Ambient Temperature Range
-40 to 85
°C
Storage Temperature Range
-55 to 150
°C
SUPPLY
Symbol
VS
IS
SVRR
Parameter
Test Condition
Min.
Typ.
Max.
Unit
7.5
9
10
V
25
30
35
mA
Supply Voltage
Supply Current
VS = 9V
Ripple Rejection @ 1KHz
Audioprocessor (all filters flat)
60
dB
Stereodecoder + Audioprocessor
45
dB
ESD
All pins are protected against ESD according to the MIL883 standard.
PIN CONNECTION
ACINL
1
28
ACOUTL
ACINR
2
27
ACOUTR
CASSR
3
26
CREF
CASSL
4
25
OUTLF
CDR
5
24
OUTRF
CDGND
6
23
OUTLR
CDL
7
22
OUTRR
PH GND
8
21
VS
PHONE
9
20
GND
AM
10
19
SDA
MPX
11
18
SCL
LEVEL
12
17
SMUTE
MPIN
13
16
MUXR
MPOUT
14
15
MUXL
D97AU647
THERMAL DATA
Symbol
Rth-j pins
2/32
Parameter
Thermal Resistance Junction-pins
Max
DIP28
SO28
Unit
65
85
°C/W
TDA7461N
PIN DESCRIPTION
N.
Name
1
ACINL
Speaker Stage Input Left
Function
Type
I
2
ACINR
Speaker Stage Input Right
I
3
CASSR
Cassette Input Right
I
4
CASSL
Cassette Input Left
I
5
CDR
CD Right Channel Input
I
6
CDGND
Ground reference CD
I
7
CDL
CD Left Channel Input
I
8
PHGND
Phone Ground
I
9
PHONE
10
AM
11
MPX
12
LEVEL
13
MPIN
14
MPOUT
Multipath Detector Output
O
15
MUXL
Multiplexer Output Left Channel (Stereodecoder Output left selectable 1)
O
16
MUXR
Multiplexer Output Right Channel (Stereodecoder Output right selectable 1)
O
17
SMUTE
Soft Mute Drive
I
18
SCL
Phone Input
I
AM Input
I
FM Input (MPX)
I
Level Input Stereodecoder
I
Multipath Detector Input
I
2
I/O
2
I/O
I C Clock Line
19
SDA
I C Data Line
20
GND
Supply Ground
S
21
VS
Supply Voltage
S
22
OUTRR
Right Rear Speaker Output
O
23
OUTLR
Left Rear Speaker Output
O
24
OUTRF
Right Front Spaeaker Output
O
25
OUTLF
Left Front Speaker Output
O
26
CREF
Reference Capacitor Pin
S
27
ACOUTR
Pre-speaker AC Output Right Channel
O
28
ACOUTL
Pre-speaker AC Output Left Channel
O
(1) See databyte specification - speaker attenuators
Pin type legenda:
I = Input
O = Output
I/O = Input/Output
S = Supply
3/32
TDA7461N
AUDIO PROCESSOR PART
Input Multiplexer
Fully differential or quasi-differential CD and
cassette stereo input
AM mono or stereo input
Phone differential or single ended input
Internal beep with 2 frequencies (selectable)
Mixable phone and beep signals
Bass Control
2nd order frequency response
Center frequency programmable in 4(5) steps
DC gain programmable
7 x 2dB steps
Treble Control
2nd order frequency response
Center frequency programmable in 4 steps
7 x 2dB steps
Loudness
Second order frequency response
Programmable center frequency and quality factor
15 x 1dB steps
Selectable flat-mode (constant attenuation)
Speaker Control
4 independent speaker controls (1dB steps
control range 50dB)
Volume control
1dB attenuator
Max. gain 20dB
Max. attenuation 79dB
Soft-step gain control
Mute Functions
Direct mute
Digitally controlled softmute with 4 programmable time constants
ELECTRICAL CHARACTERISTICS (VS = 9V; Tamb = 25°C; RL = 10KΩ; all gains = 0dB; f = 1KHz;
unless otherwise specified).
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
70
100
130
KΩ
INPUT SELECTOR
Rin
Input Resistance
VCL
Clipping Level
2.2
2.6
SIN
Input Separation
Min. Input Gain
80
-1
100
0
1
dB
dB
Max. Input Gain
13
14
15
dB
Adjacent Gain Step
GMIN to GMAX
1
-5
-5
2
0
1
3
+5
+5
dB
mV
mV
70
20
45
100
30
70
130
40
Common Mode Rejection Ratio
Differential
Common Mode
VCM = 1VRMS @ 1KHz
KΩ
KΩ
dB
VCM = 1VRMS @ 10KHz
20Hz to 20KHz flat; all stages
0dB
45
Output Noise @ Speaker
Output
60
9
GIN MIN
GIN MAX
GSTEP
VDC
Step Resolution
DC Steps
all inputs except Phone
VRMS
DIFFERENTIAL CD STEREO INPUT
Rin
CMRR
eN
Input Resistance
15
dB
µV
DIFFERENTIAL PHONE INPUT
Rin
CMRR
Input Resistance
Differential
10
15
20
KΩ
20
30
40
KΩ
Common Mode Rejection Ratio
Common Mode
VCM = 1VRMS @ 1KHz
45
45
70
60
VCM = 1VRMS @ 10KHz
4/32
dB
dB
TDA7461N
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
BEEP CONTROL
VRMS
fBMIN
Beep Level
Lower Beep Frequency
250
570
350
600
500
630
mV
Hz
fBMAX
Higher Beep Frequency
1.15
1.2
1.25
KHz
Source
-1
0
1
dB
Source
Source
-5
-10
-6
-12
-7
-14
dB
dB
Beep/Phone
-1
0
1
dB
MIXING CONTROL
MLEVEL
Mixing Level
VOLUME CONTROL
GMAX
Max Gain
19
20
21
dB
AMAX
Max Attenuation
-83
-79
-75
dB
ASTEP
EA
Step Resolution
Attenuation Set Error
G = -20 to 20dB
0.5
-1.25
1
0
1.5
1.25
dB
dB
G = -60 to 20dB
-4
0
3
2
dB
dB
Adjacent Attenuation Steps
From 0dB to GMIN
-3
-7
0.1
0.5
3
+7
mV
mV
0.5
-16
1
-15
1.5
-14
dB
dB
ET
VDC
Tracking Error
DC Steps
LOUDNESS CONTROL
ASTEP
AMAX
Step Resolution
Max. Attenuation
fCMIN
fCMAX
Lower Center Frequency
180
200
220
Hz
Higher Center Frequency
360
400
440
Hz
60
100
0.48
0.96
40.4
324
1
2
60
600
dB
ms
ms
ms
ms
SOFT MUTE
AMUTE
TD
VTHlow
VTHhigh
RPU
VPU
Mute Attenuation
Delay Time
Low Threshold for SM Pin1
High Threshold for SM Pin
Internal Pull-up Resistor
Pull-up Voltage
T1
T2
T3
T4
20
200
1
2.5
70
100
4.7
130
10
15
V
V
KΩ
V
SOFT STEP
TSW
Switch Time
5
ms
1) The SM pin is active low (Mute = 0)
5/32
TDA7461N
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
fC1
fC2
fC3
fC4
Q1
Q2
Q3
Q4
DC = off
DC = on
±13
1
54
63
72
90
0.9
1.1
1.3
1.8
-1
4
±14
2
60
70
80
100(2)
1
1.25
1.5
2
0
4.4
±15
3
66
77
88
110
1.1
1.4
1.7
2.2
+1
6
dB
dB
Hz
Hz
Hz
Hz
fC1
fC2
fC3
fC4
±13
1
8
10
12
14
±14
2
10
12.5
15
17.5
±15
3
12
15
18
21
dB
dB
KHz
KHz
KHz
KHz
-53
0.5
80
-2
-50
1
90
-47
2
2
5
dB
dB
dB
dB
mV
30
3.8
10
100
4.0
VRMS
KΩ
nF
Ω
V
3
15
µV
6.5
15
µV
BASS CONTROL
CRANGE
ASTEP
fC
Control Range
Step Resolution
Center Frequency
QBASS
Quality Factor
DCGAIN
Bass-Dc-Gain
dB
dB
TREBLE CONTROL
CRANGE
ASTEP
fC
Control Range
Step Resolution
Center Frequency
SPEAKER ATTENUATORS
CRANGE
ASTEP
AMUTE
EE
VDC
Control Range
Step Resolution
Output Mute Attenuation
Attenuation Set Error
DC Steps
Adjacent Attenuation Steps
0.1
AUDIO OUTPUTS
VCLIP
RL
CL
ROUT
VDC
Clipping Level
Output Load Resistance
Output Load Capacitance
Output Impedance
DC Voltage Level
d = 0.3%
Output Noise
BW = 20 Hz to 20 KHz
output muted
BW = 20 Hz to 20 KHz
all gain = 0dB
all gain = 0dB flat; VO = 2VRMS
bass treble at 12dB; VO =
2.6VRMS
VIN = 1VRMS; all stages 0dB
VIN = 1VRMS; Bass & Treble = 12dB
2.2
2
3.6
2.6
GENERAL
eNO
S/N
d
SC
ET
Signal to Noise Ratio
Distortion
Channel separation Left/Right
Total Tracking Error
AV = 0 to -20dB
AV = -20 to -60dB
2) See description of Audioprocessor Part - Bass & Treble filter characteristics programming
6/32
106
100
80
-1
-2
0.002
0.05
100
0
0
dB
dB
0.1
0.1
1
2
%
%
dB
dB
dB
TDA7461N
DESCRIPTION OF THE AUDIOPROCESSOR
PART
Programmable Input Matrix
The programmable input matrix of the TDA7461N
offers several possibilities to adapt the audioprocessor to the desired application. In to the standard application we have:
CD quasi differential
Cassette stereo
Phone differential
AM mono
Stereodecoder input.
The input matrix can be configured by only 2 bits:
bits 3 and 4 of subaddress 0. Basically the bit of
subaddress 13 is fixed by the application and has to
be programmed only once at the startup of the IC.
For many configurations the two bits are also fixed
during one application (e.g. the standard application) and a change of the input source can be done
by loading the first three bits of subaddress 0.
In other configurations for some sources a programming of bit 3 and 4 of subaddress 0 is necessary in addition to the three source selection
bits. In every case only the subaddress 0 has to
be changed to switch from one source to another.
The following picture shows the input and source
programming flow:
Figure 1. Input Configuration Tree
TDA7461
CD QD
CD FD
APPL. 1
APPL. 2
APPL. 3
APPL. 4
APPL. 5
APPL. 6
CD QD
CASSETTE
FM STD
AM MONO
PHONE (D)
CD QD
CASSETTE
FM STD
AM STEREO
PHONE (SE)
CD QD
CASSETTE
FM STD
AM STD
PHONE (D)
CD FD
CASSETTE
FM STD
AM MONO
PHONE (SE)
CD FD
CASSETTE
FM STD
AM STEREO
CD FD
CASSETTE
FM STD
AM STD
PHONE (SE)
D97AU632B
Note: in AMSTD configuration the AM mono signal is lead through the FM stereodecoder part to use its additional filters and high-cut function.
PIN NUMBER
Appl. No
1)
6
1
2
CDGND
CDGND
8
PhoneGND
PhoneGND
9
Phone
AMRIGHT
10
AMMONO
AMLEFT
3
CDGND
PhoneGND
Phone
AMSTD
4
5
CDRGND
CDRGND
CDLGND
CDLGND
Phone
AMRIGHT
AMMONO
AMLEFT
6
CDRGND
CDLGND
Phone
AMSTD
Startup:
Startup:
FM
AM
Phone
Startup:
FM
AM
Phone
Startup:
Startup:
FM
AM
Startup:
FM
AM
Phone
Programming 1)
0/xxx11xxx
0/xxxx1xxx
0/xxx11100
0/xxx01011
0/xxx11010
0/xxxx1xxx
0/xxx11100
0/xxx01100
0/xxx11010
0/xxxx0xxx
0/xxxx0xxx
0/xxx10100
0/xxx00011
0/xxxx0xxx
0/xxx10100
0/xxx00100
0/xxx10010
Syntax 0/xxx11100 means: SUBADDRESS = 0 - DATA BYTE = xxx11100 (x - don’t care)
7/32
TDA7461N
How to find the right input configuration
The best way to come to the desired configuration may be to go through the application tree
from the top to the bottom while making the specific decisions.
This way will lead to one of the six possible applications. Then take the number of the application
and go into the pinning table. Here you will find
the special pinout as well as the special programming codes for selecting sources.
For example in Appl. 6 the TDA7461N has to be
configured while startup with the databyte
0/xxxx0xxx.
To select the FM, AM or phone source the last
five significant bits of subaddress 0 have to be
changed, for any other source the last three bits
are sufficient (see data byte specification).
Input stages
Most of the input circuits are the same as in preceeding ST audioprocessors with exception of
the CD inputs (see figure 2).
In the meantime there are some CD players in
the market having a significant high source impedance which affects strongly the commonmode rejection of the normal differential input
stage. The additional buffer of the CD input
avoids this drawback and offers the full commonmode rejection even with those CD players.
The TDA7461N can be configured with an additional input; if the AC coupling before the speaker
stage is not used (bit 7 in subaddress 5 set to "1")
ACINL and ACINR pins can be used as an additional stereo input.
AutoZero
In order to reduce the number of pins there is no
AC coupling between the In-Gain and the following stage, so that any offset generated by or before the In-Gain stage would be transferred or
even amplified to the output.
8/32
To avoid that effect a special offset cancellation
stage called AutoZero is implemented.
To avoid audible clicks the audioprocessor is
muted before the loudness stage during this time.
In some cases, for example if the µP is executing
a refresh cycle of the I2C bus programming, it is
not useful to start a new AutoZero action because
no new source is selected and an undesired mute
would appear at the outputs. For such applications the TDA7461N could be switched in the
"Auto Zero Remain" mode (Bit 6 of the subaddress byte). If this bit is set to high, the DATABYTE 0 could be loaded without invoking the
AutoZero and the old adjustment value remains.
MUX OUTPUT
The MUX_L and MUX_R outputs can provide selectively the output of the input multiplexer
(Speaker RF register, Byte 8, bit 6=1) or the output of the stereodecoder (Speaker RF register
Byte 8 bit 6=0).
If bit D3 byte 10 (Stdec Register) is set to 1, then
the stdec signal is automatically muted, when another source is selected at the input multiplexer.
If bit D3 byte 10 (Stdec Register) is set to 0, then
the stdec signal will be always available at the
Mux out pins, no matter which is the selected
source.
The selection of the stereodecoder input, via a
special procedure, is recommended.
1)Soft Mute or Mute the signal path
2)Temporary deselect the stereodec
3) Wait 100-200ms to allow the stdec internal
filters to settle
4) Select sterodec input (with automatic autozero)
This procedure guarantees an optimum offsetcancellation, avoiding big DC offsets due to the
autozero circuitry, which otherwise could try to
compensate the signal sourced at the MPX input
instead of the stereodecoder intrinsic offset.
TDA7461N
Figure 2. Input stages
15K
15K
CD
-
100K
+
15K
15K
CDGND
15K
15K
PHONE
+
15K
15K
IN GAIN
PH_GND
CASSETTE
100K
AM
100K
STEREODECODER
MPX
100K
D97AU633A
Mixing Stage
This stage offers the possibility to mix the internal
beep or the phone signal to any other source.
Due to the fact that the mixing stage is also located behind the In-Gain stage fine adjustments
of the main source level can be done in this way.
Loudness
There are four parameters programmable in the
loudness stage (see fig. 3, 4, 5):
Figure 3. Loudness Attenuation @ fc = 400Hz
(second order)
0.0
-5.0
-10.0
-15.0
- Attenuation
- Center Frequency
- Loudness Q
- Flat Mode: in this mode the loudness stage works
as a 0 - 15dB attenuator.
Softmute
The digitally controlled softmute stage allows
muting/demuting the signal with a I2C bus programmable slope. The mute process can either
be activated by the softmute pin or by the I2C
bus. The slope is realized in a special S shaped
curve to mute slow in the critical regions (see figure 6).
For timing purposes the Bit 3 of the I2C bus output register is set to 1 from the start of muting until the end of demuting.
-20.0
10.0
100.0
1.0K
10.0K
Figure 4. Loudness Center frequency @ Attn.
= 15dB (second order)
0.0
-5.0
-10.0
-15.0
-20.0
10.0
100.0
1.0K
10.0K
9/32
TDA7461N
Figure 5. Loudness @ Attn. = 15dB, fc = 400Hz
Figure 6. Softmute Timing
D98AU844
(dB)
EXT.
MUTE
1
-5
+SIGNAL
-10
REF
-SIGNAL
-15
1
-20
10
I2C BUS
OUT
100
1,000
Bass
There are three parameters programmable in the
bass stage (see figs 8, 9, 10, 11):
- Attenuation
- Center Frequency (60, 70, 80 and 100Hz)
- Quality Factors (1, 1.25, 1.5 and 2)
Time
D97AU634
Hz
Softstep Volume
When volume level is changed often an audible
click appears at the output. The root cause of
those clicks could be either a DC offset before
the volume stage or the sudden change of the
envelope of the audio signal. With the Softstep
feature both kinds of clicks could be reduced to a
minimum and are no more audible (see figure 7).
Note: Please notice that a started Mute action is always terminated
and could not be interrupted by a change of the mute signal.
Figure 7. Soft Step Timing
VOUT
2dB
1dB
Time
10ms
-1dB
-2dB
D97AU635
DC Mode
In this mode the DC gain is increased by 4.4dB.
In addition the programmed center frequency and
quality factor is decreased by 25% which can be
used to reach alternative center frequencies or
quality factors.
Treble
There are two parameters programmable in the
treble stage (see figs 12, 13):
- Attenuation
- Center Frequency (10, 12.5, 15 and 17.5kHz).
Speaker Attenuator
Due to practical aspects the steps in the speaker
attenuators are not linear over the full range. At
attenuations more than 24dB the steps increase
from 1.5dB to 10dB (please see data byte specification).
10/32
Note: For steps more than 1dB the softstep mode should be
deactivated because it could generate a 1dB error during the
blend-time
TDA7461N
Figure 8. Bass Control @ fc = 80Hz, Q = 1
Figure 9. Bass Center @ Gain = 14dB, Q = 1
15.0
15.0
10.0
12.5
5.0
10.0
7.5
0.0
5.0
-5.0
2.5
-10.0
0.0
-15.0
10.0
100.0
1.0K
10.0K
10.0
100.0
1.0K
10.0K
Figure 10. Bass Quality factors @ Gain =
14dB, fc = 80Hz
Figure 11. Bass normal and DC Mode @ Gain
= 14dB, fc = 80Hz
15.0
15.0
12.5
12.5
10.0
10.0
7.5
7.5
5.0
5.0
2.5
2.5
0.0
10.0
0.0
10.0
100.0
1.0K
10.0K
100.0
1.0K
10.0K
Note: In general the center frequency, Q and DC-mode can be set
independently. The exception from this rule is the mode (5/xx1111xx)
where the center frequency is set to 150Hz instead of 100Hz.
Figure 12. Treble Control @ fc = 17.5KHz
Figure 13. Treble Center Frequencies
@ Gain = 14dB
15.0
15.0
10.0
12.5
5.0
10.0
7.5
0.0
5.0
-5.0
2.5
-10.0
0.0
-15.0
10.0
100.0
1.0K
10.0K
10.0
100.0
1.0K
10.0K
11/32
TDA7461N
STEREODECODER PART
No external components necessary
PLL with adjustment free fully integrated VCO
Automatic pilot dependent MONO/STEREO
switching
Very high suppression of intermodulation and
interference
Programmable Roll-Off compensation
Dedicated RDS Softmute
Highcut and Stereoblend characterisctics programmable in a wide range
Internal Noiseblanker with threshold controls
Multipath detector with programmable internal/external influence
I2C bus control of all necessary functions
ELECTRICAL CHARACTERISTICS (VS = 9V; deemphasis time constant = 50µs, VMPX = 500mV,
75KHz deviation, f = 1KHz. GI = 6dB, Tamb = 25°C; unless otherwise specified).
Symbol
VIN
Rin
Gmin
Gmax
GSTEP
SVRR
α
THD
S+N
N
Parameter
MPX Input Level
Input Resistance
Minimum Input Gain
Max Input Gain
Step Resolution
Supply Voltage Ripple Rejection
Max Channel Separation
Total Harmonic Distortion
Signal plus Noise to Noise Ratio
Test Condition
Input Gain = 3.5dB
Min.
S = 2Vrms
80
Typ.
0.5
100
3.5
11
2.5
55
50
0.02
91
for Stereo, PTH = 1
for Stereo, PTH = 0
for Mono, PTH = 1
for Stereo, PTH = 0
10
15
7
10
15
25
12
19
70
1.5
8.5
1.75
Vripple = 100mv, f = 1khz
30
Max.
1.25
130
4.5
12.5
3.25
25
35
17
25
0.3
Unit
VRMS
KΩ
dB
dB
dB
dB
dB
%
dB
MONO/STEREO SWITCH
VPTHST1
VPTHST0
VPTHMO1
VPTHMO0
Pilot Threshold Voltage
Pilot Threshold Voltage
Pilot Threshold Voltage
Pilot Threshold Voltage
mV
mV
mV
mV
PLL
∆f/f
Capture Range
0.5
%
DEEMPHASIS and HIGHCUT (5)
τHC50
Deemphasis Time Constant
τHC75
Deemphasis Time Constant
τHC50
Highcut Time Constant
τHC75
Highcut Time Constant
Bit = 7, Subadr. 10 = 0
VLEVEL >> VHCH
Bit = 7, Subadr. 10 = 1
VLEVEL >> VHCH
Bit = 7, Subadr. 10 = 0
VLEVEL >> VHCL
Bit = 7, Subadr. 10 = 1
VLEVEL >> VHCL
25
50
75
µs
50
75
100
µs
100
150
200
µs
150
225
300
µs
4.7
5
3300
0
10
0.67
33
58
8.4
5.3
V
ppm
dB
dB
dB
%REF5V
%REF5V
%REF5V
STEREOBLEND and HIGHCUT-CONTROL
REF5V
TCREF5V
LGmin
LGmax
LGstep
VSBLmin
VSBLmax
VSBLstep
12/32
Internal Reference Voltage
Temperature Coefficient
Min. LEVEL Gain
Max. LEVEL Gain
LEVEL Gain Step Resolution
Min.Voltage for Mono
Max. Voltage for Mono
Step Resolution
-1
8
0.3
29
54
5.0
+1
12
1.0
37
62
12
TDA7461N
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
36
62
5
13
29
42
66
8.4
17
33
46
70
12
21
37
%REF5V
%REF5V
%REF5V
%VHCH
%VHCH
40
50
75
62
90
dB
dB
dB
dB
fmod = 10KHz; fspur = 1KHz;
fmod = 13KHz; fspur = 1KHz;
65
75
dB
dB
f = 57KHz
70
dB
75
dB
95
84
dB
dB
STEREOBLEND and HIGHCUT CONTROL
VHCHmin
VHCHmax
VHCHstep
VHCLmin
VHCLmax
Min.Voltage for NO Highcut
Max. Voltage for NO Highcut
Step Resolution
Min. Voltage for FULL High cut
Max. Voltage for FULL High cut
Carrier and harmonic suppression at the output
α19
α38
α57
α76
Pilot Signal
Subcarrier
Subcarrier
Subcarrier
f = 19KHz
f = 38KHz
f = 57KHz
f = 76KHz
Intermodulation (Note1)
α2
α3
Pilot Signal
Traffic Radio (Note 2)
α57
Signal
SCA - Subsidiary Communications Authorization (Note 3)
α67
Signal
f = 67KHz
ACI - Adjacent Channel Interference (Note 4)
α114
α190
Signal
Signal
f = 114KHz
f = 190KHz
Notes to the characteristics:
1. Intermodulation Suppression: measured with: 91% pilot signal; fm = 10kHz or 13kHz.
2. Traffic Radio (V.F.) Suppression: measured with: 91% stereo signal; 9% pilot signal; fm=1kHz; 5% subcarrier (f = 57kHz,
fm = 23Hz AM, m = 60%)
3. SCA ( Subsidiary Communications Authorization ) measured with: 81% mono signal; 9% pilot signal; fm = 1kHz; 10%SCA - subcarrier
( fs = 67kHz, unmodulated ).
4. ACI ( Adjacent Channel Interference ) measured with: 90% mono signal; 9% pilot signal; fm =1kHz; 1% spurious signal
( fs = 110kHz or 186kHz, unmodulated).
5. By Design/Characterization but functionally guaranteed through dedicated test mode structure
13/32
TDA7461N
NOISE BLANKER PART
internal 2nd order 140kHz high pass filter
programmable trigger threshold
additional circuits for trigger adjustment (devia-
tion, field-strenght)
very low offset current during hold time
four selectable pulse suppression times
ELECTRICAL CHARACTERISTICS (continued)
Symbol
VTR
Parameter
Trigger Threshold 0) 1)
Test Condition
meas. with VPEAK = 0.9V
VTRNOISE
Noise Controlled Trigger
Threshold 2)
meas. with VPEAK = 1.5V
Rectifier Voltage
VMPX = 0mV
VMPX = 50mV; f = 150KHz
VMPX = 100mV; f = 150KHz
means. with
OVD = 11
VMPX = 800mV
OVD = 10
(75KHz dev.)
OVD = 01
OVD = 00
FSC = 11
means. with
VMPX = 0mV
FSC = 10
VLEVEL << VSBL
FSC = 01
(fully mono)
FSC = 00
VRECT
VRECT DEV
deviation dependent
rectifier Voltage 3)
VRECT FS
Fieldstrength Controlled
Rectifier Voltage 4)
Min.
NBT = 111
NBT = 110
NBT = 101
NBT = 100
NBT = 011
NBT = 010
NBT = 001
NBT = 000
NCT = 00
NCT = 01
NCT = 10
NCT = 11
0.5
1.5
2.2
0.5
0.9
1.7
2.5
0.5
1.0
1.5
2.0
0) All thresholds are measured using a pulse with TR = 2 µs, THIGH = 2 µs and TF = 10 µs.
1) NBT represents the Noiseblanker-Byte bits D2; D0 for the noise blanker trigger threshold
2) NAT represents the Noiseblanker-Byte bit pair D4,D3 for the noise controlled trigger adjustment
3) OVD represents the Noiseblanker-Byte bit pair D7,D6 for the over deviation detector
4) FSC represents the Fieldstrength-Byte bit pair D1,D0 for the fieldstrength control
VIN
VOP
DC
D97AU636
14/32
TR
THIGH
TF
Time
Typ.
30
35
40
45
50
55
60
65
260
220
180
140
0.9
1.7
2.5
0.9(off)
1.2
2.0
2.8
0.9(off)
1.3
1.8
2.3
Max.
1.3
2.1
2.9
1.3
1.5
2.3
3.1
1.3
1.6
2.1
2.6
Unit
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
mVOP
V
V
V
VOP
VOP
VOP
VOP
V
V
V
V
TDA7461N
Figure 14. Trigger Threshold vs. VPEAK
VTH
260mV(00)
220mV(01)
180mV(10)
140mV(11)
MIN. TRIG. THRESHOLD
NOISE CONTROLLED
TRIG. THRESHOLD
65mV
8 STEPS
30mV
0.9V
D97AU648
VPEAK(V)
1.5V
Figure 15. Deviation Controlled Trigger Adjustment
VPEAK
(VOP)
00
2.8
01
2.0
10
1.2
0.9
D97AU649
DETECTOR OFF (11)
20
32.5
45
DEVIATION(KHz)
75
Figure 16. Fieldstrength Controlled Trigger Adjustment
VPEAK
MONO
STEREO
»3V
2.3V(00)
1.8V(01)
1.3V(10)
NOISE
noisy signal
0.9V
ATC_SB OFF (11)
D98AU863
good signal
E'
15/32
TDA7461N
MULTIPATH DETECTOR
Internal 19kHz bandpass filter
Programmable bandpass and rectifier gain
Two pin solution fully independent usable for
external programming
Selectable internal influence on Stereoblend
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
fCMP
Center frequency of MultipathBandpass
GBPMP
GRECTMP
ICHMP
IDISMP
Test Condition
Min.
Typ.
stereodecoder locked on pilot
tone
Bandpass Gain
Rectifier Gain
Max.
19
Unit
KHz
bits D2, D1 configuration byte = 00
6
dB
bits D2, D1 configuration byte = 01
bits D2, D1 configuration byte = 10
bits D2, D1 configuration byte = 11
16
dB
12
18
dB
dB
bits D7, D6 configuration byte = 00
7.6
dB
bits D7, D6 configuration byte = 01
bits D7, D6 configuration byte = 10
4.6
0
dB
dB
1
1.5
µA
mA
Rectifier Charge Current
Rectifier Discharge Current
Figure 17. Block diagram of the stereodecoder
DEMODULATOR
MPX
INGAIN
INFILTER
3.5 ... 11dB
STEP 2.5dB
LP 80KHz
4.th ORDER
DEEMPHASIS
+ HIGHCUT
- PLOT CANC
- ROLL-OFF COMP.
- LP 25KHz
t=50 or 75µs
FM_L
FM_R
100K
PLL +
PILOT-DET.
F19
SB CONTROL
REF 5V
VSBL
HC
CONTROL
D
F38
A
VHCCH
VHCCL
STEREO
NOISE BLANKER
HOLDN
MPINFL
-
LEVEL INTERN
MULTIPATH
DETECTOR
LEVEL INPUT
LP 2.2KHZ
1.th ORDER
GAIN 0..10dB
LEVEL
MPIN
MPOUT
D97AU762
16/32
TDA7461N
DESCRIPTION OF STEREODECODER
The stereodecoder part of the TDA7461N (see
Fig. 17) contains all functions necessary to demodulate the MPX signal like pilot tone dependent MONO/STEREO switching as well as
"stereoblend" and "highcut" functions.
Adaptations like programmable input gain, roll-off
compensation, selectable deemphasis time constant and a programmable fieldstrength input allow to use different IF devices.
Figure 18. Signals during stereodecoder’s
softmute
SOFTMUTE
COMMAND
t
STD MUTE
t
Stereodecoder Mute
The TDA7461N has a fast and easy to control
RDS mute function which is a combination of the
audioprocessor softmute and the high-ohmic
mute of the stereodecoder. If the stereodecoder
is selected and a softmute command is sent (or
activated through the SM pin) the stereodecoder
will be set automatically to the high-ohmic mute
condition after the audio signal has been softmuted.
Hence a checking of alternate frequencies could
be performed. To release the system from the
mute condition simply the unmute command must
be sent: the stereodecoder is unmuted immediately and the audioprocessor is softly unmuted.
Fig. 18 shows the output signal VO as well as the
internal stereodecoder mute signal. This influence of Softmute on the stereodecoder mute can
be switched off by setting bit 3 of the Softmute
byte to "0". A stereodecoder mute command (bit
0, stereodecoder byte set to "1") will set the
stereodecoder in any case independently to the
high-ohmic mute state.
If any other source than the stereodecoder is selected the decoder remains muted and the MPX
pin is connected to Vref to avoid any discharge of
the coupling capacitor through leakage currents.
Input Stages
The Ingain stage allows to adjust the MPX signal
to a magnitude of about 1Vrms internally which is
the recommended value. The 4.th order input filter has a corner frequency of 80kHz and is used
to attenuate spikes and noise and acts as an antialiasing filter for the following switch capacitor filters.
Demodulator
In the demodulator block the left and the right
channel are separated from the MPX signal. In
this stage also the 19 kHz pilot tone is cancelled.
For reaching a high channel separation the
TDA7461N offers an I2C bus programmable rolloff adjustment which is able to compensate the
VO
D97AU638
t
lowpass behaviour of the tuner section. If the
tuner attenuation at 38kHz is in a range from
20.2% to 31% the TDA7461N needs no external
network before the MPX pin. Within this range an
adjustment to obtain at least 40dB channel separation is possible.
The bits for this adjustment are located together
with the fieldstrength adjustment in one byte. This
gives the possibility to perform an optimization
step during the production of the carradio where
the channel separation and the fieldstrength control are trimmed.
Deemphasis and Highcut.
The lowpass filter for the deemphasis allows to
choose between a time constant of 50µs and
75µs (bit D7, Stereodecoder byte).
The highcut control range will be in both cases
tHC = 2 ⋅ tDeemp. Inside the highcut control range
(between VHCH and VHCL) the LEVEL signal
is converted into a 5 bit word which controls the
lowpass time constant between t Deemp...3 ⋅ tDeemp.
There by the resolution will remain always 5 bits
independently of the absolute voltage range between the VHCH and VHCL values.
The highcut function can be switched off by I2C
bus (bit D7, Fieldstrength byte set to "0").
PLL and Pilot Tone Detector
The PLL has the task to lock on the 19kHz pilotone during a stereo transmission to allow a correct demodulation. The included detector enables
the demodulation if the pilot tone reaches the selected pilottone threshold VPTHST. Two different
thresholds are available. The detector output (signal STEREO, see block diagram) can be checked
17/32
TDA7461N
by reading the status byte of the TDA7461N via
I2C bus.
Figure 19. Internal stereoblend characteristics
Fieldstrength Control
The fieldstrength input is used to control the high
cut and the stereoblend function. In addition the
signal can be also used to control the noiseblanker thresholds.
LEVEL Input and Gain
To suppress undesired high frequency modulation on the highcut and stereoblend function the
LEVEL signal is lowpass filtered firstly. The filter
is a combination of a 1st order RC lowpass at
53kHz (working as anti-aliasing filter) and a 1storder switched capacitor lowpass at 2.2kHz. The
second stage is a programmable gain stage to
adapt the LEVEL signal internally to different IF.
The gain is widely programmable in 16 steps
from 0dB to 10dB (step = 0.67dB). These 4 bits
are located together with the Roll-Off bits in the
"Stereodecoder Adjustment" byte to simplify a
possible adaptation during the production of the
carradio.
gain LG and VSBL. To adjust the voltage where
the full channel separation is reached (VST) the
LEVEL gain LG has to be defined. The following
equation can be used to estimate the gain:
LG =
REF5V
Field strength voltage [STEREO]
The gain can be programmed through 4 bits in
the "Stereodecoder-Adjustment" byte.
The MONO voltage VMO (0dB channel separation) can be choosen selecting 33, 42, 50 or 58%
of REF5V.
All necessary internal reference voltages like
REF5V are derived from a bandgap circuit.
Therefore they have a temperature coefficient
near zero. This is useful if the fieldstrength signal
is also temperature compensated.
But most IF devices apply a LEVEL voltage with a
TC of 3300ppm. The TDA7461N offers this TC
for the reference voltages, too. The TC is selectable with bit D7 of the "stereodecoder adjustment" byte.
Stereoblend Control
The stereoblend control block converts the internal LEVEL voltage (LEVEL INTERN) into an demodulator compatible analog signal which is used
to control the channel separation between 0dB
and the maximum separation. Internally this control range has a fixed upper limit which is the internal reference voltage REF5V. The lower limit
can be programmed to be 33%, 42%, 50% or
58% of REF5V (see fig. 20).
To adjust the external LEVEL voltage to the internal range two values must be defined: the LEVEL
Figure 20. Relation between internal and external LEVEL voltage and setup of Stereoblend
INTERNAL
VOLTAGES
INTERNAL
VOLTAGES
SETUP OF VST
SETUP OF VMO
LEVEL INTERN
REF 5V
REF 5V
58%
50%
VSBL 42%
33%
LEVEL
VSBL
VMO
18/32
LEVEL INTERN
VST
t
FIELDSTRENGHT VOLTAGE
D97AU639
VMO
VST
t
FIELDSTRENGHT VOLTAGE
TDA7461N
Highcut Control
The highcut control setup is similar to the
stereoblend control setup : the starting point
VHCH can be set with 2 bits to be 42, 50, 58 or
66% of REF5V whereas the range can be set to
be 17 or 33% of VHCH (see fig. 21).
supplied by his own biasing circuit.
Trigger Path
The incoming MPX signal is highpass filtered,
amplified and rectified. This second order highpass-filter has a corner frequency of 140kHz. The
rectified signal, RECT, is lowpass filtered to generate a signal called PEAK. Also noise with a frequency 140kHz increases the PEAK voltage. The
PEAK voltage is fed to a threshold generator,
which adds to the PEAK voltage a DC dependent threshold VTH. Both signals, RECT and
PEAK+VTH are fed to a comparator which triggers a re-triggerable monoflop. The monoflop’s
output activates the sample-and-hold circuits in
the signalpath for 40µs.
Figure 21. Highcut characteristics
LOWPASS
TIME CONSTANT
3•τDeemp
The block diagram of the noiseblanker is given in
fig.22.
τDeemp
D97AU640
Automatic Noise Controlled Threshold Adjustment (ATC)
There are mainly two independent possibilities for
programming the trigger threshold:
FUNCTIONAL DESCRIPTION OF THE NOISEBLANKER
In the automotive environment the MPX signal is
disturbed by spikes produced by the ignition and
for example the wiper motor. The aim of the
noiseblanker part is to cancel the audible influence of the spikes. Therefore the output of the
stereodecoder is held at the actual voltage for
40µs.
In a first stage the spikes must be detected but to
avoid a wrong triggering on high frequency
(white) noise a complex trigger control is implemented. Behind the triggerstage a pulse former
generates the "blanking" pulse. To avoid any
crosstalk to the signalpath the noiseblanker is
a the low threshold in 8 steps (bits D0 to D2 of
the noiseblanker byte)
b the noise adjusted threshold in 4 steps
(bits D3 and D4 of the noiseblanker byte,
see fig. 14).
The low threshold is active in combination with a
good MPX signal without any noise; the PEAK
voltage is less than 1V. The sensitivity in this operation is high.
If the MPX signal is noisy the PEAK voltage increases due to the higher noise, which is also
rectified. With increasing of the PEAK voltage the
trigger threshold increases, too. This particular
gain is programmable in 4 steps (see fig. 14).
VHCL
VHCH
FIELDSTRENGHT
Figure 22. Block diagram of the noiseblanker
MPX
HIGH PASS
RECTIFIER
RECT
+
-
+
HOLDN
VTH
PEAK
LOWPASS
MONOFLOP
THRESHOLD
GENERATOR
+
ADDITIONAL
THRESHOLD
CONTROL
D98AU861
19/32
TDA7461N
Automatic Threshold Control
Besides the noise controlled threshold adjustment there is an additional possibility for influencing the trigger threshold. It is depending on the
stereoblend control.
The point where the MPX signal starts to become
noisy is fixed by the RF part. Therefore also the
starting point of the normal noise-controlled trigger adjustment is fixed (fig. 16). In some cases
the behaviour of the noiseblanker can be improved by increasing the threshold even in a region of higher fieldstrength. Sometimes a wrong
triggering occures for the MPX signal often shows
distortion in this range which can be avoided
even if using a low threshold.
Because of the overlap of this range and the
range of the stereo/mono transition it can be controlled by stereoblend. This threshold increase is
programmable in 3 steps or switched off with bits
D0 and D1 of the fieldstrength control byte.
used to increase the PEAK voltage. Offset and
gain of this circuit are programmable in 3 steps
with the bits D6 and D7 of the stereodecoder byte
(the first step turns off the detector, see fig. 15).
Over Deviation Detector
If the system is tuned to stations with a high deviation the noiseblanker can trigger on the higher
frequencies of the modulation. To avoid this
wrong behaviour, which causes noise in the output signal, the noiseblanker offers a deviation dependent threshold adjustment.
By rectifying the MPX signal a further signal representing the actual deviation is obtained. It is
TEST MODE
During the test mode which can be activated by
setting bit D0 of the testing byte and bit D5 of the
subaddress byte to "1" several internal signals
are available at the CASSR pin. During this
mode the input resistance of 100kOhm is disconnected from the pin. The internal signals available
are shown in the software specification.
FUNCTIONAL DESCRIPTION OF THE MULTIPATH DETECTOR
Using the internal detector the audible effects of a
multipath condition can be minimized. A multipath
condition is detected by rectifying the 19kHz
spectrum in the fieldstrength signal.
Selecting the "internal influence" in the configuration byte, the channel separation is automatically
reduced during a multipath condition according to
the voltage appearing at the MPOUT pin.
To obtain a optimal performance an adaptation is
necessary. Therefore the gain of the 19kHz bandpass is programmable in four steps as well as the
rectifier gain. The attack and decay times can be
set by the external capacitor value.
Figure 23. Block diagram of the Multipath Detector
LEVEL
to SB
VDD
int. INFLUENCE
DC=1µA
MPIN
BANDPASS
19KHz
RECTIFIER
MPOUT
GAIN
2 BITS
20/32
GAIN
2 BITS
220nF
D97AU880
TDA7461N
Figure 24. Application Example 1
SOUND
EFFECTS
ACOUTL
ACOUTR
ACINR
ACINL
CREF
VS
10µF
+VCC
=
100nF
OUTLF
OUTLF
9V
OUTRF
100nF
OUTRF
CASS R
CASS R
OUTLR
100nF
OUTLR
CASS L
CASS L
100nF
TDA7461
CDR
CDR
OUTRR
MPX
22µF
CDG
CDG
AM
100nF
CDL
CDL
220nF
220nF
AM
SDA
SCL
SCL
SMUTE
SMUTE
LEVEL
PHONE
PHONE
MPX
220nF
SDA
PHONE_GND
PHGND
OUTRR
220nF
LEVEL
GND
D97AU763A
MPIN
MPOUT
MUXR
UNWEIGHTED
LEVEL
MUXL
220nF
Note: Bit D7 of "Bass and Treble Filter characteristics" set to 1
Figure 25. Application Example 2
PRE-SPEAKER
OUTPUT
ADDITIONAL
INPUT
100nF
ACOUTL
ACOUTR
100nF
ACINR
VS
ACINL
CREF
10µF
+VCC
100nF
=
OUTLF
OUTLF
9V
100nF
CASS R
100nF
CASS L
100nF
CDR
22µF
CDG
100nF
CDL
220nF
PHGND
220nF
PHONE
OUTRF
OUTRF
CASS R
OUTLR
OUTLR
CASS L
CDR
TDA7461
OUTRR
MPX
CDG
AM
CDL
OUTRR
220nF
MPX
220nF
AM
SDA
SDA
SCL
PHONE_GND
SCL
SMUTE
SMUTE
LEVEL
PHONE
LEVEL
GND
D97AU764
MPIN
MPOUT
UNWEIGHTED
LEVEL
MUXR
MUXL
220nF
Note: Bit D7 of "Bass and Treble Filter characteristics" set to 0
21/32
TDA7461N
I2C BUS INTERFACE DESCRIPTION
Interface Protocol
The interface protocol comprises:
-a start condition (S)
-a chip address byte (the LSB bit determines read
CHIP ADDRESS
MSB
S
1
SUBADDRESS
LSB
0
0
0
1
1
/ write transmission)
-a subaddress byte
-a sequence of data (N-bytes + acknowledge)
-a stop condition (P)
DATA 1 to DATA n
MSB
0 R/W ACK
LSB
X AZ T
I
A3 A2 A1 A0
MSB
LSB
DATA
ACK
ACK
P
D97AU627
S = Start
ACK = Acknowledge
AZ = AutoZero-Remain
T = Testing
I = Autoincrement
P = Stop
MAX CLOCK SPEED 500kbits/s
Auto increment
If bit I in the subaddress byte is set to "1", the
autoincrement of the subaddress is enabled.
The transmitted data is automatically updated after each ACK.
Transmission can be repeated without new chip
address.
SM = Soft mute activated
ST = Stereo
X = Not Used
TRANSMITTED DATA (send mode)
MSB
X
LSB
X
X
X
ST
SM
X
SUBADDRESS (receive mode)
MSB
X
LSB
AZ
T
T = Testmode
I = Autoincrement
AZ = Auto Zero Remain
X = not used
22/32
I
A3
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
A2
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
A1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
A0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
FUNCTION
Input selector
Loudness / Auto-Zero
Volume
Softmute / Beep
Bass / Treble Attenuator
Bass / Treble Configuration
Speaker attenuator LF
Speaker attenuator LR
Speaker attenuator RF
Speaker attenuator RR / Blanktime adjust
Stereodecoder
Noiseblanker
Fieldstrength Control
Configuration
Stereodecoder Adjustment
Testing
X
TDA7461N
DATA BYTE SPECIFICATION
Input Selector
MSB
D7
FUNCTION
LSB
D6
D5
D4
D3
D2
D1
D0
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0
0
1
1
1
1
0
0
1
1
0
0
0
1
1
0
0
1
0
0
:
1
1
0
0
:
1
1
0
1
:
0
1
Source Selector
CD
Cassette
Phone
AM
Stereo Decoder
Input FM
Mute
AC inputs
CD Mode
CD Full-differential
CD Quasi-diff
AM/FM Mode
AM mono
AM stereo
AM through Stereodecoder
FM- Stereodecoder
In-Gain
14dB
12dB
:
2 dB
0 dB
For example to select the CD input in quasi-differential mode with gain of 8dB the Data Byte is: 0/01111000
Loudness
MSB
D7
D6
D5
D4
0
1
0
1
0
1
1
LOUDNESS
LSB
D3
D2
D1
D0
0
0
:
1
1
0
0
:
1
1
0
0
:
1
1
0
1
:
0
1
Attenuation
0dB
-1dB
:
-14dB
-15dB
Filter
on
off (flat)
Center Frequency
200Hz
400Hz
Loudness Q
low (1st order)
normal (2nd order)
must be "1"
Note: The attenuation is specified at high frequencies. Around the center frequency the value is different depending on the programmed
attenuation (see Loudness frequency response).
23/32
TDA7461N
Mute, Beep and Mixing
MSB
D7
LSB
D6
D5
D4
D3
D2
D1
0
1
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
0
1
1
MUTE/BEEP/MIXING
D0
0
1
0
1
Mute
Enable Softmute
Disable Softmute
Mute time =0.48 ms
Mute time =0.96 ms
Mute time =40.4 ms
Mute time =324 ms
Stereo Decoder Softmute Influence = off
Stereo Decoder Softmute Influence = on
Beep
Beep Frequency = 600Hz
Beep Frequency = 1.2KHz
Mixing
Mix-Source = Beep
Mix-Source = Phone
Full Mix Signal
Source -12dB + Mix-Signal -2.5dB
Source -6dB + Mix-Signal -6dB
Full Source
Note: for more information to the Stereodecoder-Softmute-Influence please refer to the stereodecoder description.
Volume
MSB
D7
0
1
LSB
D6
D5
D4
D3
D2
D1
D0
0
0
:
0
0
0
:
0
0
0
:
1
1
0
0
:
0
0
0
:
0
1
1
:
1
1
0
0
:
0
0
0
:
1
0
0
:
0
0
0
0
:
1
1
1
:
1
0
0
:
1
1
0
0
:
1
1
1
:
1
0
0
:
1
1
0
0
:
0
0
1
:
1
0
0
:
1
1
0
1
:
0
1
0
:
1
0
1
:
0
1
ATTENUATION
Gain/Attenuation
+32dB
+31dB
:
+20dB
+19dB
+18dB
:
+1dB
0dB
- 1dB
:
-78dB
-79dB
Softstep
Softstep Volume = off
Softstep Volume = on
Note: It is not recommended to use a gain more than 20dB for system performance reason. In general, the max. gain should be limited by
software to the maximum value, which is needed for the system.
24/32
TDA7461N
Bass & Treble Attenuation
MSB
D7
0
0
:
0
0
1
1
:
1
1
LSB
D6
0
0
:
1
1
1
1
:
0
0
D5
0
0
:
1
1
1
1
:
0
0
D4
D3
D2
D1
D0
0
0
:
0
0
1
1
:
1
1
0
0
:
1
1
1
1
:
0
0
0
0
:
1
1
1
1
:
0
0
0
1
:
0
1
1
0
:
1
0
BASS & TREBLE ATTENUATION
Treble Steps
-14dB
-12dB
:
-2dB
0dB
0dB
+2dB
:
+12dB
+14dB
Bass Steps
-14dB
-12dB
:
-2dB
0dB
0dB
+2dB
:
+12dB
+14dB
0
1
:
0
1
1
0
:
1
0
For example 12dB Treble and -8dB Bass give the following DATA BYTE : 0 0 1 1 1 0 0 1.
Bass & Treble Filter Characteristics
MSB
D7
LSB
D6
D5
1
0
0
1
1
D4
1
0
1
0
1
D3
0
0
1
1
1
D2
D1
D0
0
0
1
1
0
1
0
1
0
1
0
1
1
0
1
0
1
BASS & TREBLE FILTER
Treble
Center Frequency = 10 KHz
Center Frequency = 12.5 KHz
Center Frequency = 15 KHz
Center Frequency = 17.5 KHz
Bass
Center Frequency = 60 Hz
Center Frequency = 70 Hz
Center Frequency = 80 Hz
Center Frequency = 100Hz
Center Frequency = 150Hz
Quality factor = 1
Quality factor = 1.25
Quality factor = 1.5
Quality factor = 2
DC-Gain = 0dB
DC-Gain = ±4.4dB
AC Coupling (*)
For External Connection
Internally connected
For example Treble center frequency = 15kHz, Bass center frequency = 100Hz, Bass Q = 1 and DC = 0dB give the following DATA BYTE: 1
0001110
(*) For deeper information see application examples fig. 24 and fig. 25.
25/32
TDA7461N
Speaker Attenuation (LF, LR, RF, RR)
MSB
D7
LSB
D6
1
1
0
0
1
1
0
1
0
1
0
1
26/32
D5
D4
D3
D2
D1
D0
0
0
:
0
0
0
0
0
0
0
0
0
1
0
0
:
1
1
1
1
1
1
1
1
1
0
0
:
0
1
1
1
1
1
1
1
1
0
0
:
1
0
0
0
0
1
1
1
1
0
0
:
1
0
0
1
1
0
0
1
1
0
1
:
1
0
1
0
1
0
1
0
1
Attenuation
0dB
-1dB
:
-23dB
-24.5dB
-26dB
-28dB
-30
-32dB
-35dB
-40dB
-50dB
Speaker Mute
Must be "1" (except RF, RR speaker; see below)
Blank Time adj. (subaddress speaker RR)
38µs
25.5µs
32µs
22µs
Output selector for pins 15 and 16.
(subaddress spaeaker RF)
Stereodecoder output selected
Input multiplexer output selected
TDA7461N
Stereodecoder
MSB
D7
FUNCTION
LSB
D6
D5
D4
D3
D2
D1
D0
0
1
0
0
1
1
IN-Gain 11dB
IN-Gain 8.5dB
IN-Gain 6dB
IN-Gain 3.5dB
0
1
0
1
1
Stereodec Unmuted with Stdec Input selected
and automatically Muted at the selection of any
other source.
Stereodec Unmuted whichever is the selected
source.
0
1
1
STD Unmuted
STD Muted
0
1
Forced MONO
MONO/STEREO switch automatically
0
1
Pilot Threshold HIGH
Pilot Threshold LOW
0
1
Deemphasis 50µs
Deemphasis 75µs
Noiseblanker
MSB
D7
LSB
D6
D5
D4
0
0
1
1
0
1
0
0
1
1
0
1
0
1
D3
0
1
0
1
D2
0
0
0
0
1
1
1
1
D1
0
0
1
1
0
0
1
1
D0
0
1
0
1
0
1
0
1
FUNCTION
Low Threshold 65mV
Low Threshold 60mV
Low Threshold 55mV
Low Threshold 50mV
Low Threshold 45mV
Low Threshold 40mV
Low Threshold 35mV
Low Threshold 30mV
Noise Controlled Threshold 320mV
Noise Controlled Threshold 260mV
Noise Controlled Threshold 200mV
Noise Controlled Threshold 140mV
Noise blanker OFF
Noise blanker ON
Over deviation Adjust 2.8V
Over deviation Adjust 2.0V
Over deviation Adjust 1.2V
Over deviation Detector OFF
27/32
TDA7461N
Fieldstrength Control
MSB
D7
FUNCTION
LSB
D6
D5
D4
D3
0
0
1
1
0
0
1
1
D2
D1
D0
0
0
1
1
0
1
0
1
Noiseblanker Field strength Adj 2.3V
Noiseblanker Field strength Adj 1.8V
Noiseblanker Field strength Adj 1.3V
Noiseblanker Field strength Adj OFF
VSBL at 33% REF 5V
VSBL at 42% REF 5V
VSBL at 50% REF 5V
VSBL at 58% REF 5V
0
1
0
1
VHCH at 42% REF 5V
VHCH at 50% REF 5V
VHCH at 58% REF 5V
VHCH at 66% REF 5V
0
1
0
1
1
0
VHCL at 17% VHCH
VHCL at 33% VHCH
0
1
High cut OFF
High cut ON
Configuration
MSB
D7
LSB
D6
D5
D4
D3
0
0
1
1
0
1
1
0
0
1
1
28/32
0
1
0
1
D2
0
1
0
1
D1
D0
0
0
1
1
0
1
0
1
FUNCTION
Noise Rectifier Discharge Resistor
R = infinite
R = 56kΩ
R = 33kΩ
R =18kΩ
Multipath Detector Bandpass Gain
6dB
16dB
12dB
18dB
Multipath Detector internal influence
ON
OFF
Must be "1"
Multipath Detector Reflection Gain
Gain = 7.6dB
Gain = 4.6dB
Gain = 0dB
OFF
TDA7461N
Stereodecoder Adjustment
MSB
D7
LSB
D6
D5
D4
D3
0
0
0
:
1
0
0
0
:
1
0
0
1
:
1
0
1
0
:
1
D6
D5
D4
D3
D2
D1
D0
0
0
0
:
1
:
1
0
0
1
:
0
:
1
0
1
0
:
0
:
1
D2
D1
0
1
FUNCTION
Roll-Off Compensation
not allowed
20.2%
21.9%
:
25.5%
:
31.0%
LEVEL Gain
0dB
0.66dB
1.33dB
:
10dB
Temperature compensation at LEVEL input
TC = 0
TC = 16.7mV/K (3300ppm)
Testing
MSB
D7
LSB
0
1
0
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
1
0
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
FUNCTION
D0
Stereodecoder test signals
OFF
Test signals enabled if bit D5 of the subaddress
(test mode bit) is set to "1", too
External Clock
Internal Clock
Testsignals at CASS_R
VHCCH
Level intern
Pilot magnitude
VCOCON; VCO Control Voltage
Pilot threshold
HOLDN
NB threshold
F228
VHCCL
VSBL
not used
not used
PEAK
not used
REF5V
not used
VCO
OFF
ON
Audioprocessor test mode
only if bit D5 of the subaddress
(test mode bit) is set to "1"
OFF
Note : This byte is used for testing or evaluation purposes only and must not be set to other values than the default "11111110" in the application!
29/32
TDA7461N
mm
DIM.
MIN.
TYP.
A
inch
MAX.
MIN.
TYP.
2.65
MAX.
0.104
a1
0.1
0.3
0.004
0.012
b
0.35
0.49
0.014
0.019
b1
0.23
0.32
0.009
0.013
C
0.5
c1
0.020
45° (typ.)
D
17.7
18.1
0.697
0.713
E
10
10.65
0.394
0.419
e
1.27
0.050
e3
16.51
0.65
F
7.4
7.6
0.291
0.299
L
0.4
1.27
0.016
0.050
S
30/32
OUTLINE AND
MECHANICAL DATA
8 ° (max.)
SO28
TDA7461N
mm
inch
DIM.
MIN.
TYP.
MAX.
MIN.
TYP.
a1
0.63
0.025
b
0.45
0.018
b1
0.23
b2
0.31
1.27
D
E
0.009
0.012
0.050
37.34
15.2
16.68
1.470
0.598
0.657
e
2.54
0.100
e3
33.02
1.300
F
MAX.
OUTLINE AND
MECHANICAL DATA
14.1
0.555
I
4.445
0.175
L
3.3
0.130
DIP28
31/32
TDA7461N
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
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 publication are
subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products
are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.
The ST logo is a registered trademark of STMicroelectronics.
All other names are the property of their respective owners
© 2003 STMicroelectronics - All rights reserved
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32/32