SONY CXD2724AQ-1

CXD2724AQ-1
Single-Chip Dolby Pro Logic Surround Decoder
For the availability of this product, please contact the sales office.
Description
The CXD2724AQ-1 is a CMOS LSI developed for
Dolby Pro Logic Surround. A SRAM for short delay
and AD/DA converters are built in, and all functions
necessary for Dolby Pro Logic Surround such as an
adaptive matrix, a passive decoder including BNR,
auto input balance, a noise sequencer and center
channel mode control are contained on a single
chip. Further, this LSI also supports Dolby 3 Stereo
and Virtual Dolby Surround.
Features
• Dolby Pro Logic Surround decoding with a single
chip
• 2-channel 1-bit AD converter, decimation filter and
prefilter operational amplifier
• 4-channel 1-bit DA converter, oversampling filter
and post filter
• Analog switch for DSP bypass
• Analog electronic attenuator (+1.5 to –29.5dB) for
center/surround channel trim
• 24K-bit SRAM for short delay
• No separation or other variance for digital
processing
• External parts reduced by incorporating analog
circuits
80 pin QFP (Plastic)
Absolute Maximum Ratings (Ta = 25°C, VSS = 0V)
• Supply voltage
VDD
VSS – 0.5 to +7.0
V
• Input voltage
VI VSS – 0.5 to VDD + 0.5 V
• Output voltage
VO VSS – 0.5 to VDD + 0.5 V
• Operating temperature
Topr
–20 to +70
°C
• Storage temperature
Tstg
–55 to +150
*C
Recommended Operating Conditions
• Supply voltage
VDD
Analog system
4.75 to 5.25 (5.0 typ.) V
Digital system
4.50 to 5.25 (5.0 typ.) V
• Operating temperature
Ta
–20 to +70
°C
Functions
• Adaptive matrix
• Center channel mode control
(Normal/Phantom/Wide)
• Dolby 3 Stereo
• Auto input balance control (ON/OFF)
• Noise sequencer
• Variable delay time (0 to 34.8ms)
• 7 kHz low-pass filter (12dB/Oct)
• Modified Dolby B-type NR
• Simple SFC function
• Virtual Dolby Surround
• SFC mode
• DSP bypass mode (L, R-channel through)
Input/Output Capacitance
• Input capacitance CIN
9 (max.)
pF
• Output capacitance COUT
11 (max.)
pF
• Input/output capacitance
CI/O
11 (max.)
pF
∗ Measurement conditions: VDD = VI = 0V, F = 1MHz
Maximum Current Consumption
(Ta = 25°C, VDD = 5.25V)
• Digital/analog block total: 166.7mA
Dolby level
• During analog input: 200 to 300mVrms
• During digital input: –20dBFS
Analog characteristics
Pro Logic ON: Dolby level = 300mVrms
Prefilter gain = –3.52dB
• S/N: L, Rch = 80dB, C, Sch = 72dB
• THD + N: L, Rch = 0.015%, C, Sch = 0.03%
∗ All values for typ.
Structure
Silicon gate CMOS
Applications
Equipment having Dolby Pro Logic Surround
function such as AV amplifiers, receivers and
compact music systems
This device is available only to arties obtaining the license from Dolby Laboratories Licensing Cor oration.
"Dolby", the double-D symbol
and "Pro Logic" are trademarks of Dolby Laboratories Licensing Corporation.
Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by
any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the
operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.
–1–
E98829A8X-PS
CXD2724AQ-1
Block Diagram
24K bit DELAY RAM
27 LIN
26 LO1
ADC1
RVDT 50
38 RIN
MICROCOMPUTER
I/F
SCK 46
XLAT 49
39 LO2
ADC2
REDY 47
DSP
23 LOUT
DAC1
LRCK 58
Analog SW
BCK 57
SI 55
42 ROUT
DAC2
SERIAL
DATA
I/F
Analog SW
XMST 60
CLOCK GENERATOR
/TIMING CIRCUIT
DAC3
Trim Vol
30 XCOUT
(Phase Inverted Output)
DAC4
Trim Vol
35 XSOUT
32
17
XTLO
BFOT
T.P
XTLI
33
T.P
(Phase Inverted Output)
AVD2
AVD4
ROUT
AVS4
VSS3
SCK
REDY
XLAT
T.P
RVDT
XS24
VDD1
VSS4
SI
BCK
LRCK
XMST
VSS5
T.P
T.P
T.P
VSS6
Pin Configuration
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41
T.P 65
40 AVS2
T.P 66
39 LO2
T.P 67
38 RIN
T.P 68
37 AVD6
T.P 69
36 AVS6
T.P 70
35 XSOUT
T.P 71
34 AVSX
T.P 72
33 XTLI
32 XTLO
VDD2 73
31 AVDX
VSS7 74
T.P 75
30 XCOUT
T.P 76
29 AVS5
AVD1
LOUT
AVD3
AVS3
TST0
VSS2
T.P
CSL2
T.P
–2–
CSL1
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
BFOT
8
TST4
7
XRST
6
TST3
5
TST2
4
TST1
3
VSS1
2
VDD0
1
T.P
25 AVS1
T.P
26 LO1
T.P 80
VSS0
T.P 79
T.P
27 LIN
T.P
28 AVD5
T.P 78
T.P
T.P 77
CXD2724AQ-1
Pin Description
Pin No.
Symbol
Notations in parentheses indicate the fixed pin connection status.
I/O
Description
T.P
O
Test monitor. Normally outputs Low.
VSS0
—
Digital GND.
T.P
O
Test monitor. Normally outputs Low.
9
TST0
I
Test. Normally fixed Low.
(VSS)
10
VDD0
—
Digital power supply.
(VDD)
11
VSS1
—
Digital GND.
(VSS)
12
TST1
I
Test. Normally fixed Low.
(VSS)
13
TST2
I
Test. Normally fixed Low.
(VSS)
14
TST3
I
Test. Normally fixed Low.
(VSS)
15
TST4
I
Test. Normally fixed Low.
(VSS)
16
XRST
I
System reset input. Reset when Low.
17
BFOT
O
Clock, frequency-division output. [384/768/256/512fs]
18
CSL1
I
Test. Normally fixed High.
(VDD)
19
CSL2
I
Test. Normally fixed Low.
(VSS)
20
VSS2
—
Digital GND.
(VSS)
21
AVS3
—
L-ch DA converter GND.
(AVSS)
22
AVD3
—
L-ch DA converter power supply.
(AVDD)
23
LOUT
O
L-ch DA converter output.
24
AVD1
—
L-ch AD converter power supply.
(AVDD)
25
AVS1
—
L-ch AD converter GND.
(AVSS)
26
LO1
O
L-ch AD converter LPF operational amplifier inverted output.
27
LIN
I
L-ch AD converter analog input.
28
AVD5
—
C-ch DA converter power supply.
(AVDD)
29
AVS5
—
C-ch DA converter GND.
(AVSS)
30
XCOUT
O
C-ch DA converter output.
31
AVDX
—
Analog power supply for master clock.
32
XTLO
O
Crystal oscillator circuit output.
33
XTLI
I
Crystal oscillator circuit input.
34
AVSX
—
Analog GND for master clock.
35
XSOUT
O
S-ch DA converter output.
36
AVS6
—
S-ch DA converter GND.
(AVSS)
37
AVD6
—
S-ch DA converter power supply.
(AVDD)
1 to 3
4
5 to 8
(OPEN)
(VSS)
(OPEN): Open, (VDD): +5V digital power supply, (AVDD): +5V analog power supply,
(VSS): Digital GND, (AVSS): Analog GND
–3–
(OPEN)
(AVDD)
(AVSS)
CXD2724AQ-1
Notations in parentheses indicate the fixed pin connection status.
Pin No.
Symbol
Description
I/O
38
RIN
I
R-ch AD converter analog input.
39
LO2
O
R-ch AD converter LPF operational amplifier inverted output.
40
AVS2
—
R-ch AD converter GND.
(AVSS)
41
AVD2
—
R-ch AD converter power supply.
(AVDD)
42
ROUT
O
R-ch DA converter output.
43
AVD4
—
R-ch DA converter power supply.
(AVDD)
44
AVS4
—
R-ch DA converter GND.
(AVSS)
45
VSS3
—
Digital GND.
46
SCK
I
Shift clock input for microcomputer interface.
47
REDY
O
Transfer enabling signal output for microcomputer interface. Transfer prohibited when Low.
48
T.P
O
Test monitor. Normally outputs Hi-Z.
49
XLAT
I
Latch input for microcomputer interface.
50
RVDT
I
Data input for microcomputer interface.
51
XS24
I
Serial data 24-/32-bit slot selection. 24-bit slot when Low. (valid for slave mode)
52
VDD1
—
Digital power supply.
(VDD)
53
VSS4
—
Digital GND.
(VSS)
54
T.P
O
Test monitor. Normally outputs Low.
55
SI
I
1-sampling 2-channel serial data input.
56
T.P
I
Test input. Normally inputs Low.
57
BCK
I/O
Serial bit transfer clock for serial I/O data SI and SO.
58
LRCK
I/O
Sampling frequency clock for serial I/O data SI and SO.
59
VSS5
—
Digital GND.
60
XMST
61 to 63 T.P
64
VSS6
65 to 72 T.P
(VSS)
(OPEN)
(OPEN)
(VSS)
(VSS)
I
BCK, LRCK master/slave mode switching input. Master mode when Low.
O
Test monitor. Normally outputs Low.
—
Digital GND.
O
Test monitor. Normally outputs Low.
(OPEN)
(VSS)
(OPEN)
73
VDD2
—
Digital power supply.
(VDD)
74
VSS7
—
Digital GND.
(VSS)
O
Test monitor. Normally outputs Low.
75 to 80 T.P
(OPEN)
(OPEN): Open, (VDD): +5V digital power supply, (AVDD): +5V analog power supply,
(VSS): Digital GND, (AVSS): Analog GND
∗ There are three digital and seven analog power supplies, but the power-on sequence is not specified.
–4–
CXD2724AQ-1
DC Characteristics
(AVD1 to 6 = AVDX = VDD0 to 2 = 5V ± 5%, AVS1 to 6 = AVSX = VSS0 to 7 = 0V, Ta = –20 to +70°C)
Item
Symbol
Input voltage
(1)
High level VIH
Input voltage
(2)
High level VIH
Input voltage
(3)
High level VIH
Low level
Low level
Low level
Input voltage (4)
VIL
VIL
VIL
Min.
Typ.
Max.
∗1, ∗2, ∗7
V
∗1, ∗2, ∗7
V
∗5
V
∗5
V
∗3, ∗6
0.8
V
∗3, ∗6
VDD
V
∗4
V
∗8, ∗9
V
∗8, ∗9, ∗10
V
∗11
VDD/2
V
∗11
0.3VDD
0.8VDD
Schmitt input
0.2VDD
2.2
TTL input
Applicable pins
V
0.7VDD
CMOS input
Unit
Analog input
VSS
Output voltage High level VOH
(1)
Low level VOL
IOH = –2.0mA
VDD – 0.8
Output voltage High level VOH
(2)
Low level VOL
IOH = –12.0mA
IOL = 12.0mA
Input leak current (1)
II
VIH = VDD, VSS
–10
10
µA
∗1, ∗5, ∗7
Input leak current (2)
II
VIH = VDD, VSS
–40
40
µA
∗2, ∗3, ∗6
Output leak current
IOZ
VIH = VDD, VSS
–40
40
µA
∗9, ∗10
Feedback resistance
RFB
2.5M
Ω
Resistance between ∗7 and ∗11
∗1
∗2
∗3
∗4
∗5
∗6
∗7
∗8
∗9
∗10
∗11
VIN
Conditions
IOL = 4.0mA
0.4
VDD/2
250k
CSL2, CSL1, TST0 to TST4, XMST
XLAT, RVDT, XS24, SCK
SI
LIN, RIN
XRST
During input to bidirectional pins BCK, LRCK
XTLI
During output from bidirectional pins BCK, LRCK
BFOT
REDY
XTLO
–5–
1M
CXD2724AQ-1
AC Characteristics
(AVD1 to 6 = AVDX = VDD0 to 2 = 5V ± 5%, AVS1 to 6 = AVDX = VSS0 to 7 = 0V, Ta = –20 to +70°C)
Input Timing from Power-on to Input Pin
VDD
Determined by the crystal and other external circuit conditions
XTLI
Stable (clock applied correctly)
•••••
0.95VDD
1/fs or more
0.8VDD
0.2VDD
XRST
1/fs or more
Input pins
0.7VDD
0.3VDD
First input
Serial Audio Interface Timing
[Slave mode]
0.7VDD
0.3VDD
BCK
tSSI
tHSI
0.7VDD
0.3VDD
SI
tHLR
tSLR
0.7VDD
0.3VDD
LRCK
[Master mode]
BCK
tDLR
LRCK
Item
SI setup time
SI hold time
LRCK setup time
LRCK hold time
LRCK delay time
Symbol
tSSI
tHSI
tSLR
tHLR
tDLR
Conditions
Min.
Max.
Unit
Slave mode
20
ns
Slave mode
40
ns
Slave mode
20
ns
Slave mode
40
ns
Master mode, CL = 120pF
–6–
50
ns
CXD2724AQ-1
Microcomputer Interface Timing
Transfer timing for address section, transfer mode section and data section LSB
RVDT
Address LSB
Mode MSB
tSWL
tDS
tSWH
0.7VDD
0.3VDD
Data LSB
Data MSB
tDH
SCK
tSLP
0.7VDD
0.3VDD
XLAT
tLWL
tLSD
0.7VDD
0.3VDD
REDY
Transfer timing from data section MSB to address section and transfer mode section
RVDT Data MSB
Mode MSB
Address LSB
0.7VDD
0.3VDD
tSS
0.7VDD
0.3VDD
SCK
tSLD
XLAT
0.7VDD
0.3VDD
tLDR
tSBD
tRLP
tBSP
REDY
Item
Symbol
Min.
RVDT data setup time relative to SCK rise
tDS
20
ns
RVDT data hold time from SCK rise
tDH
1t + 20
ns
SCK Low level width
tSWL
1t + 20
ns
SCK High level width
tSWH
1t + 20
ns
XLAT Low level width
tLWL
1t + 20
ns
XLAT High level width
tLWH
1t + 20
ns
SCK rise preceding time relative to XLAT rise
tSLP
20
ns
SCK rise wait time relative to XLAT rise
tLSD
3t + 20
ns
Delay time to REDY fall relative to SCK rise
tSBD
REDY fall preceding time relative to SCK rise
tBSP
20
ns
REDY rise preceding time relative to XLAT rise
tRLP
20
ns
tRSDP
20
ns
XLAT fall wait time relative to SCK rise
tSLD
3t + 20
ns
XLAT fall delay time relative to REDY fall
tLDR
20
ns
tSS
2t + 40
ns
REDY rise preceding time relative to SCK fall
SCK rise wait time for next transfer
Notes) 1. t is the cycle of 2/3 the clock frequency applied to the XTLI pin. (512fs)
2. The REDY pin is the value for CL = 60pF.
–7–
Max.
4t + 50
Unit
ns
CXD2724AQ-1
Analog Characteristics
(AVD0 to 6 = VDD0 to 2 = AVDX = 5.0V, AVS0 to 6 = VSS0 to 7 = AVSX = 0.0V, fs = 44.1kHz, Ta = 25°C)
When Pro Logic mode is on, the input signal level while measuring the center (C) and surround (S) channels
should be –3dB smaller than the input level while measuring the left (L) and right (R) channels. Note that the C
channel is input in-phase to the L channel, and the S channel is input at reversed phase to the R channel.
The input level is the same for all measurement items when Pro Logic mode is off.
1. ADC + DAC Connection Total Characteristics
In addition to the ADC and DAC, the total characteristics include the prefilter with built-in operational amplifier,
built-in post filter, and trim volume. Use the analog I/O circuits in the Application Circuit for the measurement
circuit.
1-1. When Pro Logic mode is on
Unless otherwise specified, the measurement conditions are as given below.
• VIN (L, R) = 300mVrms, VIN (C, S) = 212mVrms (= 0dB)
• fIN = 1kHz
Item
Measurement conditions
CCIR/ARM filter
S/N ratio∗1
10Hz to 500kHz
10Hz to 20kHz
VIN = 16.5dB∗2
10Hz to 20kHz
VIN = 0dB∗3
THD + N
10Hz to 20kHz
VIN = –3.52dB∗4
10Hz to 500kHz
Head room
10Hz to 20kHz, THD + N = 1%
Matrix rejection
∗5
Channels
Min.
Typ.
L, R
70
80
C, S
65
72
L, R
60
C
56
S
64
L, R
0.04
C, S
0.007 1.00
L, R
0.015
C, S
0.03
L, R
0.02
C, S
0.04
L, R
0.12
C
0.18
S
0.04
25
60
C, S
25
40
Output level
(all)
250
280
Level difference between channels
(all)
Power supply rejection
ratio∗6
∗1
∗2
∗3
∗4
∗5
∗6
∗7
±0.2
Analog system (including oscillator circuit)
36
Digital system
91
1mVrms, 100Hz sine wave
L, R
C, S∗7
3.9
–13.2
Unit
dB
1.00
%
16.5
L, R
Current consumption
Max.
dB
dB
310
Vrms
dB
mA
dB
When VIN = 200mVrms (= –3.52dB), the S/N ratio is 3.52dB smaller than the values noted in the table above.
VIN (L, R) = 2.0Vrms, VIN (C, S) = 1.414Vrms
VIN (L, R) = 300mVrms, VIN (C, S) = 212mVrms
VIN (L, R) = 200mVrms, VIN (C, S) = 141mVrms
When the L and R channel gain deviation is 0.1dB or less for the ADC front-end prefilter output.
Includes the amplification (L/Rch...5.27dB, C/Sch...13.72dB) of the external amplifier.
The trim volume is set to 0dB.
–8–
CXD2724AQ-1
1-2. When Pro Logic mode is off
Unless otherwise specified, the measurement conditions are as given below.
• VIN (L, R, C, S) = 2.0Vrms (= 0dB)
• fIN = 1kHz
Item
Measurement conditions
S/N ratio
THD + N∗11
ADC maximum input level∗13
Output level∗14
Min.
Typ.
EIAJ
(with "A" weighting filter)
L, R
97
C, S
90
EIAJ (0dB)
(all)
0.03
L, R
0.004
C, S
0.01
L, R
93
C, S
83
(all)
1.33
EIAJ (–3dB)
Dynamic range∗12
Channels
EIAJ (–60dB)
(Full-scale output)
(all)
1.7
1.85
Max.
Unit
dB
1.00
%
dB
Vrms
2.0
Vrms
∗11 See Graphs 1a and 1b.
∗12 THD + N during –60 dB input
∗13 The analog input level at which the ADC outputs full scale varies according to supply voltage AVDn.
When supply voltage AVDn contains deviation, calculate the maximum input level from (Formula 1) below
and adjust the level with the ADC front-end prefilter, etc., so that the waveform is not clipped at the
minimum voltage.
ADC maximum input level [Vrms] = 1.33 [Vrms] ×
Minimum supply voltage [V]
5.0 [V]
(Formula 1)
∗14 Like the ADC, the DAC conversion gain also varies according to supply voltage AVDn. However, the DAC
has the reverse characteristics of the ADC, so the total gain between the ADC and DAC is constant.
10
10
0dB = 2Vrms
fin = 1kHz
0dB = 2Vrms
fin = 1kHz
1
THD + N [%]
THD + N [%]
1
0.1
0.01
0.001
–60
0.1
0.01
–50
–40
–30
–20
Analog input level [dB]
–10
0.001
–60
0
Graph 1a. L, R Channel Characteristics
–50
–40
–30
–20
Analog input level [dB]
–10
0
Graph 1b. C, S Channel Characteristics
–9–
CXD2724AQ-1
2. DAC Characteristics
In addition to the DAC, these characteristics include the built-in post filter and trim volume. Use the digital input
and analog output circuits in the Application Circuit for the measurement circuit.
2-1. When Pro Logic mode is on
Unless otherwise specified, the measurement conditions are as given below.
• Digital data = –20dBFS
• fIN = 3kHz
Item
Measurement conditions
CCIR/ARM filter
Data = –20dBFS
S/N ratio
10Hz to 500kHz
Data = –20dBFS
10Hz to 20kHz
Data = –20dBFS
THD + N
10Hz to 500kHz
Data = –20dBFS
Channels
Min.
L, R
77
C, S
68
L, R
60
C
52
S
65
L, R
0.05
C
0.08
S
0.06
L, R
0.15
C
0.3
S
0.08
Dolby level
Output level∗31
Matrix rejection
Data = –20dBFS
fIN = 3kHz
Level difference between
channels
Typ.
– 10 –
dB
%
dBFS
200
mVrms
L, R-in
62
C-in
87
S-in
79
(all)
±0.2
Supply voltage AVDn [V]
5.0 [V]
Unit
–20
∗31 The output level depends on supply voltage AVDn as shown in (Formula 2) below.
Output level [mVrms] = 285 [mVrms] ×
Max.
(Formula 2)
dB
dB
CXD2724AQ-1
2-2. When Pro Logic mode is off
Unless otherwise specified, the measurement conditions are as given below.
• Digital data = Full scale (0dBFS)
• fIN = 1kHz
Item
Measurement conditions
EIAJ
(with "A" weighting filter)
S/N ratio
EIAJ (0dB)
THD + N∗41
EIAJ (–3dB)
Dynamic range∗42
EIAJ (–60dB)
Output level∗43
Channels
Min.
Typ.
L, R
100
C, S
91
L, R
0.03
C, S
0.007
L, R
0.007
C, S
0.01
L, R
87
C, S
83
(all)
2.0
Max.
Unit
dB
%
dB
Vrms
∗41 See Graphs 2a and 2b.
∗42 THD + N during –60dB input
∗43 The output level depends on supply voltage AVDn as shown in (Formula 3) below.
Output level [Vrms] = 1.9 [Vrms] ×
Supply voltage AVDn [V]
5.0 [V]
10
(Formula 3)
10
0dB = Full scale
fin = 1kHz
0dB = Full scale
fin = 1kHz
1
THD + N [%]
THD + N [%]
1
0.1
0.01
0.001
–60
0.1
0.01
–50
–40
–30
–20
Digital input level [dB]
–10
0.001
–60
0
Graph 2a. L, R Channel Characteristics
–50
–40
–30
–20
Digital input level [dB]
–10
0
Graph 2b. C, S Channel Characteristics
– 11 –
CXD2724AQ-1
3. Bypass Mode Characteristics (L, R channels only)
These are the characteristics without passing through the DSP, and including the prefilter with built-in
operational amplifier and the built-in post filter. Use the analog I/O circuits in the Application Circuit for the
measurement circuit. Unless otherwise specified, the measurement conditions are as given below.
• fIN = 1kHz
• VIN (L, R) = 2.0Vrms (= 0dB)
Item
S/N ratio
THD + N
Measurement conditions
Min.
Typ.
CCIR/ARM filter
97
10Hz to 20kHz, "A" weighting filter
100
10Hz to 500kHz
80
10Hz to 500kHz
0.008
10Hz to 20kHz
0.005
Max.
Unit
dB
%
Dynamic range∗51
10Hz to 20kHz, VIN = –60dB
95
dB
Maximum input level
THD + N = 0.05%
2.5
Vrms
Output level
2.0
Vrms
Level difference between channels
±0.2
dB
Channel separation
105
dB
7.5
dB
Power supply rejection ratio∗52
1mVrms, 100Hz sine wave
∗51 THD + N during –60dB input
∗52 Includes the amplification (5.27dB) of the external amplifier.
4. Filter Characteristics
Item
Measurement conditions
Feedback resistance value
Prefilter
Min.
Typ.
10
Load resistance value
20
10
Cut-off frequency (= fc)
Unit
kΩ
Maximum amplification rate
(100kHz or less)
Post filter
Max.
dB
kΩ
104
kHz
5. Trim Volume Characteristics
Item
Symbol
Min.
Typ.
Max.
Unit
Maximum gain
TRIMmax
1.5
dB
Minimum gain
TRIMmin
–29.5
dB
Variable step
TRIMstep
1.0
dB
– 12 –
CXD2724AQ-1
Description of Functions
1. Master/Slave Modes
[Relevant pins] XMST, LRCK, BCK
When using the CXD2724AQ -1 alone without digital input, set the CXD2724AQ-1 to master mode.
When using digital input, the CXD2724AQ-1 may be set to either master mode or slave mode.
The clock applied to LRCK and BCK in slave mode must be synchronized to either the crystal oscillator clock
of the XTLI and XTLO pins or the external clock input from the XTLI pin.
XMST
Mode
LRCK, BCK I/O
H
Slave mode
Input
L
Master mode
Output
Table 1-1. LRCK, BCK Mode Setting
2. Master Clock System
[Relevant pins] XTLI, XTLO, BFOT
768fs (fs = 32 to 44.1kHz) is assumed for the master clock system, and the connection is as shown below.
BFOT outputs the clock obtained by frequency dividing the master clock. The frequency division ratio can be
changed by the setup register (SQC04, SQC05). (See "6. Setup Register".)
SQC05 SQC04
BFOT
0
0
384fs
0
1
256fs
1
0
512fs
1
1
768fs
(1) Master
(2) Slave
O
512fs
BFOT
256fs/384fs/512fs/768fs
I
XTLI
Frequency
divider
512fs
768fs
I
XTLI
Setup
Register
768fs
O
XTLO
Note) Oscillation circuits may differ according to peripheral circuit and
substrate. Consult with crystal oscillator manufacturers about the
selecting oscillation circuits.
Fig. 2-1.
– 13 –
Frequency
divider
O OPEN
XTLO
CXD2724AQ-1
3. Reset Circuit
[Relevant pins] XRST, XTLI, XTLO
This LSI must be reset after the power is turned on.
Reset is done by setting the XRST pin Low for 1/fs or more after the supply voltage satisfies the recommended
operating condition, and the crystal oscillator clock of the XTLI and XTLO pins or the external clock input from
the XTLI pin is correctly applied. (See "AC Characteristics".)
4. Serial Audio Interface (SIF)
[Relevant pins] SI, BCK, LRCK, XS24, XMST
Serial data is used for the external communication of the digital audio data. The CXD2724AQ-1 has only one
input system, and 2 channels of data are input each sampling cycle. Either the 32-bit clock mode or the 24-bit
clock mode can be selected. In master mode, the mode is fixed to the 32-bit clock mode.
(1) Pin Configuration (The pins shown in the table below are assigned to the SIF.)
Symbol
I
SI
Function
I/O
Serial input; taken with synchronized to BCK.
BCK
I/O
BCK I/O; either 32-bit clock mode (64fs) or 24-bit clock mode (48fs). BCK output supports
32-bit clock mode only.
LRCK
I/O
LRCK I/O (1fs).
XS24
I
SIO slot number (24/32) selection input. Low: 24-bit slot; High: 32-bit slot.
Valid only in slave mode. Set High in master mode.
Do not switch between High and Low during DSP operation.
XMST
I
BCK, LRCK master mode/slave mode switching input.
Low: master mode; High: slave mode.
Table 4-1. Pin Configuration
(2) Operation Modes
The LRCK/BCK mode can be selected by the setup register settings as follows. (See "6. Setup Register".)
LRCK/BCK Mode Setting
Contents
Function
Setup register
SQC15
LRCK format
"0": normal,
SQC14
LRCK polarity selection
"0": Lch "H", "1": Lch "L"
SQC13
BCK polarity selection relative to LRCK edge
Valid only in slave mode. Fix to "0" in master
mode.
"0": edge ↓,
Table 4-2. LRCK/BCK Mode Setting
– 14 –
"1": IIS
"1" : edge ↑
CXD2724AQ-1
(3) SIF Format
The serial audio interface has only one input system, and except for the slot number, the following formats can
be set by setting the setup register. The serial audio interface can also support IIS format to enable connection
to Philips and other company's devices.
The timing charts for each data format are given on the following page.
SQC12 SQC11 Data arrangement/Frontward or rearward truncation/Data word length
0
0
MSB first/Frontward truncation/24 bits
0
1
MSB first/Rearward truncation/16 bits
1
0
MSB first/Rearward truncation/18 bits
1
1
MSB first/Rearward truncation/20 bits
∗ All formats support either the 24- or 32-bit slot in slave mode.
Table 4-3. Setup Register Settings
– 15 –
– 16 –
SI
BCK
LRCK
24-bit slot
SI
BCK
LRCK
32-bit slot
MSB
21
20
19
18
17
16
15
14
13
12
Lch
11
10
09
08
07
14
13
12
11
10
09
08
07
16
15
14
13
12
11
10
09
08
07
Iavalid
MSB
19
18
17
16
15
14
13
12
11
10
09
08
07
Iavalid
MSB
• MSB first 20 bits rearward truncation (SQC12, 11 = 1, 1)
17
Iavalid
MSB
• MSB first 18 bits rearward truncation (SQC12, 11 = 1, 0)
15
MSB
• MSB first 16 bits rearward truncation (SQC12, 11 = 0, 1)
22
• MSB first 24 bits (SQC12, 11 = 0, 0)
23
LSB
LSB
06
06
06
06
05
05
05
05
04
04
04
04
03
03
03
03
02
02
02
02
00
23
22
01
01
01
LSB
00
LSB
00
LSB
00
19
MSB
19
Iavalid
20
18
18
17
17
16
16
17
16
MSB
Iavalid
Iavalid
Iavalid
Iavalid
21
Iavalid
LSB MSB
01
LSB
19 18 17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
Iavalid
MSB
• MSB first 20 bits rearward truncation (SQC12, 11 = 1, 1)
Rch
15
15
MSB
15
LSB
MSB
LSB
17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
MSB
14
14
14
14
13
13
13
13
12
12
12
12
11
11
11
11
Rch
10
10
10
10
09
09
09
09
08
08
08
08
07
07
07
07
06
06
06
06
05
05
05
05
04
04
04
04
03
03
03
03
02
02
02
02
01
01
01
01
LSB
00
LSB
00
LSB
00
LSB
00
LSB
19 18 17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
MSB
15
Iavalid
15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
LSB
23 22 21 20 19 18 17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
MSB
17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
Iavalid
MSB
• MSB first 18 bits rearward truncation (SQC12, 11 = 1, 0)
Iavalid
Iavalid
15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
MSB
LSB
• MSB first 16 bits rearward truncation (SQC12, 11 = 0, 1)
23 22 21 20 19 18 17 16 15 14 13 12 11 10 09 08 07 06 05 04 03 02 01 00
• MSB first 24 bits frontward truncation (SQC12, 11 = 0, 0)
Lch
Digital Audio Data Input Timing (with polarities: SQC15 = 0, SQC14 = 0, SQC13 = 0)
CXD2724AQ-1
CXD2724AQ-1
5. Microcomputer Interface
[Relevant pins] RVDT, SCK, XLAT, REDY
The CXD2724AQ-1 performs the serial audio interface format setting and the coefficient settings such as
volume and filter by serial data from the microcomputer.
(1) Pin Configuration
The four external pins indicated in the table below are assigned to the microcomputer interface.
Symbol
Function
I/O
RVDT
I
Serial data input from microcomputer.
SCK
I
Shift clock for serial data. Input data from RVDT is taken according to the SCK rise.
XLAT
I
Interprets the 8 bits of RVDT before this signal rises as transfer mode data, and the
bits before that as address data.
REDY
O
Transfer prohibited while at Low level. Transfer enabled at High. This pin is an open
drain, and must be pulled up externally.
Table 5-1. Microcomputer Interface External Pins
(2) Description of Communication Formats
The internal data transfer timing from the microcomputer interface to the coefficient RAM and setup register is
called the SV cycle, and is generated once per 1 LRCK.
The SV cycle is generated immediately preceding the signal processing program, so it has absolutely no effect
on signal processing, and there is no risk of the sound being cut.
Address section + Mode section + Data section
act as one package of data to transfer data from the microcomputer to the CXD2724AQ-1.
[Write] ∗ For coefficient RAM
Address section (8 bits) Mode section (8 bits)
RVDT
A0
A7
M0
M7
Data section (16 bits)
D0
SCK
XLAT
REDY
Fig. 5-1. Example of Communication
– 17 –
D15
CXD2724AQ-1
(3) Data Structure
The data structure is classified into three types, as shown in the table below. All data communication is done
with LSB first.
Symbol
Bit length
Contents
A0 to A7
8
Address section
M0 to M7
8
Transfer mode section
D0 to D15/SQ00 to SQ15
16
Data section
Remarks
Coefficient RAM and setup register are both 16 bits
Table 5-2. Data Structure
(3)-1. Transfer Mode Section
The transfer mode section is 8 bits and has the following functions.
Bit
Function
Symbol
Reserve
M7
M6
SU1
M5
SU0
M4
VS1
M3
VS0
Setup Reg.
type
Data type
Normally fixed to "0"
SU1
0
0
1
1
VS1
0
1
SU0
0
1
0
1
VS0
0
0
Field A
Field B
Field C
Field D
Setup register
Coefficient RAM
M2
M1
Reserve
Normally fixed to "0"
M0
Table 5-3. Transfer Mode Section
(3)-2. Address Section
The coefficient RAM has a 256-word structure, so the address section is 8 bits. The setup register has a 4word structure and the field (address) is specified by the mode section, so the address section data may be
optional.
(3)-3. Data Section
The coefficient RAM and setup register both have a 16-bit structure, so 16 SCK are required.
– 18 –
CXD2724AQ-1
(4) Details of Communication Methods
The definitions of signal timing required for control from the microcomputer are given below.
(4)-1. Initializing the Microcomputer Interface
The microcomputer interface must be initialized after resetting the IC.
After resetting the IC (t1 ≥ 1/fs), input 16 SCK rising edges. After that, REDY goes Low within 4t + 50ns (t2),
and initialization is completed when REDY goes High again. Set RVDT Low while inputting SCK.
Note that the REDY Low time (t3) is a maximum of 1/fs. See the following page for the SCK restrictions. The
same restrictions apply as during data transfer.
When REDY goes Low due to initialization:
• The SCK for the first transfer can rise.
• The XLAT for the first transfer can fall.
However, the XLAT for the first transfer must rise after REDY goes High.
RVDT
XRST
t1
16 rising edges
SCK
t2
t3
REDY
Microcomputer interface can be used
Fig. 5-2. Initialize Specifications
– 19 –
CXD2724AQ-1
(4)-2. Signal Timing
First, address section data and mode section data are sent from the microcomputer, synchronized to SCK, to
the RVDT pin.
The address section data is 8 bits for both the coefficient RAM and setup register, and the setup register has a
length of one word, so optional data can be transferred. Address section data is sent with LSB first.
Mode section data is fixed at 8 bits regardless of the transfer contents.
The phase relationship between SCK and RV data (data applied to the RVDT pin) has the following
restrictions:
• RV data must be established before SCK rises (tDS ≥ 20ns).
• RV data must be held for 1t + 20ns or more after SCK rises (tDH).
SCK itself has the following restrictions:
• SCK Low level must be 1t + 20ns or more (tSWL).
• SCK High level must be 1t + 20ns or more (tSWH).
After the SCK rise which corresponds to the mode section final data, XLAT rises (tSLP ≥ 20ns).
The XLAT Low level width must be maintained at 1t + 20ns or more (tLWL). The fall timing is restricted in that
even if REDY falls due to SCK during the preceding transfer, 3t + 20ns or more (tSLD) is required from the
SCK rise which corresponds to the data section final data.
Further, if preceding transfers have been performed and REDY = Low, XLAT must rise after REDY = High.
RVDT
A0
tDS
A7
M0
D0/SQ00
SQ00
M7
D15/SQ15
SQ15
tDH
A0
M7
tSS
SCK
tSWL
tSWH
tSLP
tLSD
tBSP
tSLP
XLAT
tSLD or tLWH
tLWL
tSLD
tRLP
tSBD
REDY
tLDR
Fig. 5-3. Write Timing
∗ t is the cycle of 2/3 the clock frequency applied to the XTLI pin. (512fs)
– 20 –
tLDR
tRLP
CXD2724AQ-1
Data section write begins after XLAT rises, and here also transfer must be performed with LSB first, with tDS
and tDH restrictions. In addition, after XLAT rises at the starting point for sending the data section, wait for 3t +
20ns or more for the first SCK rise (tLSD).
When 16 bits of this write is repeated, REDY goes Low within 4t + 50ns, and the microcomputer is informed of
waiting status for the SV cycle, which is the dedicated data rewrite cycle, by the microcomputer interface
(tSBD).
When REDY goes High again, the corresponding data is written.
The next communication can be restarted by using the REDY signal as follows.
• When REDY = Low, the SCK for the next transfer can rise (tBSP ≥ 20ns).
• In the same way, when REDY = Low, the XLAT for the next transfer can fall (tLDR ≥ 20ns).
REDY will fall due to this communication, but it is prohibited for XLAT to rise for the next transfer before REDY
rises. Make sure that the next XLAT rises after REDY rises (tRLP ≥ 20ns).
In order to restart the next transfer without using the REDY signal, the following conditions must be observed:
• There should be 2t + 40ns or more left between the SCK rise for the final data section and the SCK rise for
the next transfer (tSS).
• In the same way, the XLAT for the next transfer can fall after waiting for 3t + 20ns or more after the final
data section SCK rise (tSLD).
The tSS and tSLD here are shorter times than tSBD ≤ 4t + 50ns, so these are rather loose restrictions.
However, even in this case the XLAT rise for the next transfer must come after REDY rises (tRLP ≥ 20ns).
Further, the restriction for the XLAT fall at the starting point of this transfer from tSLD can be:
tSLD ≥ 3t + 20ns
– 21 –
CXD2724AQ-1
6. Setup Register
When the setup register is selected in microcomputer interface transfer mode, the following settings are
possible for hardware such as the serial audio interface and DAC, and for software such as the Dolby Pro
Logic Surround decoder.
The setup register has a total of four fields, and 16 bits of setup information can be stored per field. However,
when this LSI is reset, the setup register contents are also reset to the settings shown in the "When reset"
column in Tables 6-1 to 6-4 below.
(1) Field A
Data
section bit
SQA15
SQA14
SQA13
SQA12
SQA11,
SQA10
SQA09,
SQA08
SQA07,
SQA06
SQA05,
SQA04
SQA03 to
SQA00
Control contents
When reset
DSP bypass mode
0: OFF
1: ON
OFF
Noise sequencer
0: OFF
1: ON
OFF
Virtualizer
0: OFF
1: ON
OFF
Compensation filter
0: OFF
1: ON
OFF
Decimation ratio setting SQA11 SQA10
(SFC mode only)
0
0
: 1/1 (No decimation)
Be sure to also set
0
1
: 1/2 decimation
SQC07 and SQC06.
1
0
: 1/3 decimation
Dolby 3 Stereo
1/1
(No decimation)
SQA09 SQA08
0
0
: OFF
0
1
: ON
OFF
Reserve bit
Be sure to set both bits Low when changing the
setup register Field A settings.
all "L"
SFC mode
SQA05 SQA04
0
0
: OFF
0
1
: ON
OFF
Be sure to set both bits Low when changing the
setup register Field A settings.
all "L"
Reserve bit
Table 6-1. Setup Register Field A
∗ Bit names are indicated by the field name and the bit number. The bit names for Field A are SQA00 to
SQA15, and the first three letters of the bit names for Fields B, C and D are SQB, SQC and SQD,
respectively.
– 22 –
CXD2724AQ-1
(2) Field B
Data
section bit
Control contents
Center channel trim volume
(5 bits, analog)
When reset
00000: 0dB
00001: –1dB
00010: –2dB
↓
11101: –29dB
11110: –30dB
11111: –31dB
0dB
SQB10 to
SQB06
00000: 0dB
00001: –1dB
00010: –2dB
↓
11101: –29dB
11110: –30dB
11111: –31dB
0dB
SQB05 to Reserve bit
SQB00
Be sure to set all of these bits Low when
changing the setup register Field B settings.
all "L"
SQB15 to
SQB11
Center channel trim volume
(5 bits, analog)
Table 6-2. Setup Register Field B
– 23 –
CXD2724AQ-1
(3) Field C
Data
section bit
Control contents
0: normal
1: IIS
normal
SQC14
LRCK polarity selection 0: Lch "H"
1: Lch "L"
Lch "H"
SQC13
BCK polarity selection
relative to LRCK edge
Falling edge
SQC15
SQC12,
SQC11
SQC10
SQC09,
SQC08
SQC07,
SQC06
SQC05,
SQC04
LRCK format
When reset
Serial audio
interface setting
0: Falling edge
1: Rising edge
SQC12 SQC11
0
0
: MSB first/Frontward truncation/24 bits
0
1
: MSB first/Rearward truncation/16 bits
1
0
: MSB first/Rearward truncation/18 bits
1
1
: MSB first/Rearward truncation/20 bits
MSB
first/Frontward
truncation/24 bits
DAC forced mute
0: ON
1: OFF
ON
Reserve bit
Be sure to set both bits Low when changing
the setup register Field C settings.
all "L"
Decimation ratio setting SQC07 SQC06
(SFC mode only)
0
0
: 1/1 (No decimation)
Be sure to also set
0
1
: 1/2 decimation
∗
SQA11 and SQA10.
1
: 1/3 decimation
BFOT output clock
frequency division
ratio setting
SQC03 to Reserve bit
SQC00
1/1
(No decimation)
SQC05 SQC04
0
0
: 384Fs
0
1
: 256Fs
1
0
: 512Fs
1
1
: 768Fs
384Fs
Be sure to set all of these bits Low when changing
the setup register Field C settings.
all "L"
Table 6-3. Setup Register Field C
Note) BCK polarity selection (SQC13) is valid only in slave mode. Fix to "0" in master mode.
– 24 –
CXD2724AQ-1
(4) Field D
Data
section bit
SQD15 to
SQD03
Control contents
Reserve bit
Be sure to set all of these bits Low when changing the
setup register Field D settings.
Coefficient memory SQD02
type setting
0
0
SQD02 to
SQD00
01
0
0
00
0
1
0
1
0
0
1
1
1
0
0
1
0
1
1
1
0
1
1
1
ROM only (ROM = 00 to ffH)
ROM/RAM mixed
(ROM = 00 to dfH/RAM = E0 to ffH)
ROM/RAM mixed
(ROM = 00 to bfH/RAM = C0 to ffH)
ROM/RAM mixed
(ROM = 00 to 9fH/RAM = A0 to ffH)
ROM/RAM mixed
(ROM = 00 to 7fH/RAM = 80 to ffH)
ROM/RAM mixed
(ROM = 00 to 3fH/RAM = 40 to ffH)
ROM/RAM mixed
(ROM = 00 to 1fH/RAM = 20 to ffH)
RAM only (RAM = 00 to ffH)
Table 6-4. Setup Register Field D
– 25 –
When reset
all "L"
ROM only
CXD2724AQ-1
7. Coefficient RAM/ROM
When the coefficient RAM is selected in microcomputer interface transfer mode, the various application
functions can be turned on and off, and the coefficient parameters such as each section's volume and delay
time can be set.
Coefficient RAM addresses other than those given in these specifications are "don't care". However, the RAM
is not cleared entirely when this LSI is reset, so there are no initial values as for the setup register. Be sure to
set all of the necessary data; otherwise misoperation may result.
(1) Configuration
The coefficient RAM and ROM have a capacity of 256 words × 16 bits each. However, the address space for
the coefficient data is from 00H to ffH (256 words), so it is not possible to access all of the coefficient RAM and
ROM data at the same time. That is to say, of the total 512 words in both the coefficient RAM and ROM, only
the specified 256 words can be handled.
The coefficient RAM and ROM areas are allocated by setting SQD02 to SQD00 of setup register Field D.
Coefficient data transferred via the microcomputer interface is stored only in the coefficient RAM area specified
by these bits.
(Even if a ROM area address is specified and transfer is performed, the transfer is ignored.)
AAA
AAA
AAA
+ AAA
AAA
00H
bfH
c0H
ffH
00H
ROM
=
bfH
c0H
RAM
ffH
ROM
RAM
Coefficient address space
Fig. 7-1. Coefficient Data ROM/RAM Allocation when SQD02 to SQD00 are Set to "010" (Setting Example)
The contents of the data transferred to the coefficient RAM area differ for each mode. (See "8. Applications" for
the detailed contents.) The RAM area may also differ, so SQD02 to SQD00 must be sent when switching the
mode.
Mode
Setting item SQD02 to SQD00
Remarks
Pro Logic + simple SFC mode
111
00 to ff = Coefficient RAM area
Virtual Dolby Surround mode
100
80 to ff = Coefficient RAM area
SFC mode
111
00 to ff = Coefficient RAM area
Table 7-1. Coefficient RAM Area
– 26 –
CXD2724AQ-1
8. Applications
The CXD2724Q is equipped with various applications such as Dolby Pro Logic Surround mode (Pro Logic
mode), Virtual Dolby Surround mode (Virtual mode), Dolby 3 Stereo mode, noise sequencer mode, SFC mode,
and DSP bypass mode.
The methods of setting each mode and of changing the mode are described below.
Note) The filter and other parameter values for each application assume a sampling frequency (fs) of 44.1 [kHz].
Consult your Sony representative with regard to use at other fs.
8-1. Dolby Pro Logic Surround Mode (Pro Logic Mode)
Pro Logic mode is realized using the adaptive matrix, passive decoder including BNR, auto input balance,
center channel mode control, simple SFC and other functions.
(1) Setting Pro Logic Mode
Pro Logic mode must be set by the following procedures in order to achieve stable adaptive matrix operation.
Setting Pro Logic mode by procedures other than those given below may aggravate the decoder
characteristics.
• Immediately after power-on reset
i) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ Field C is "All 0", so the DAC forced mute is applied.
ii) Transfer the Pro Logic mode coefficient data.
iii) Transfer the setup data set in Pro Logic mode.
• Changing to Pro Logic mode from Virtual mode
Note) The coefficients for the Pro Logic mode soft mute∗1 status must be set in coefficient RAM addresses
00H to 7fH before shifting to Virtual mode.
i) Apply the soft mute in Virtual mode.
ii) Transfer the setup data set in Pro Logic mode.
iii) Cancel the Pro Logic mode soft mute.
• Changing to Pro Logic mode from a different mode (other than Virtual mode)
i) Apply the soft mute in the current mode.
ii) Set the coefficients at the following addresses to "0000H".
Addresses: 6eH to 7fH
iii) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ The DAC forced mute is not applied by Field C.
iv) Transfer the Pro Logic mode coefficients for the soft mute status.
v) Transfer the setup data set in Pro Logic mode.
vi) Cancel the Pro Logic mode soft mute.
∗1 Soft mute: See "Appendix 1. Soft Mute".
– 27 –
CXD2724AQ-1
(2) Setting Data
(2)-1. Setup Data
Table 8-1-1 lists the registers most closely related to Pro Logic mode.
Setup data not listed in Table 8-1-1 may be set as desired, with due consideration given to the contents of
Fields A to D noted in "6. Setup Register".
Register name Setting value
Remarks
SQA14
"0"
1: Noise sequencer mode
SQA13
"0"
1: Virtual mode
SQA09, 08
"00"
01: Dolby 3 Stereo mode
SQA05, 04
"00"
01: SFC mode
SQB15 to 11
Don't care
Center channel (C-ch) trim volume
SQB10 to 06
Don't care
Surround channel (S-ch) trim volume
SQD02 to 00
"111"
Coefficient RAM area setting (111: Other than Virtual mode, 100: Virtual mode)
Table 8-1-1. Pro Logic Mode Setup Register Settings
– 28 –
CXD2724AQ-1
(2)-2. Coefficient Data
The coefficient RAM area for Pro Logic mode is from addresses 00H to ffH (all areas). The coefficient data
consists of "fixed values" shown in Table 8-1-2 and "setting values" shown in Table 8-1-3 which can be set by
the user. All coefficient values must be sent to the coefficient RAM via the microcomputer interface.
Note that once data has been transferred to the coefficient RAM, the coefficient RAM data (00H to 7fH) is
saved unless the power is turned off, even if the RAM area is changed by setting SQD02 to SQD00 (even if
the mode is changed to Virtual mode).
• Fixed values during Pro Logic mode initialization
The following fixed values must be set in the coefficient RAM to ensure proper internal operation.
Address
Fixed value
Address
Fixed value
Address
Fixed value
Address
Fixed value
27H
6dH
6eH
6fH
70H
71H
72H
73H
74H
75H
76H
77H
78H
79H
7aH
7bH
7cH
7dH
7eH
7fH
80H
81H
82H
83H
84H
85H
86H
87H
88H
89H
8aH
8bH
8cH
8dH
8eH
8fH
0000H
051eH
ff86H
02a0H
f6c0H
2715H
4000H
5149H
e571H
0f4eH
f5b8H
075cH
fa97H
0402H
fd0bH
0225H
fe7cH
01d3H
f312H
4b85H
850fH
7d6bH
7d72H
22b6H
3a94H
0074H
7f18H
a000H
8000H
febfH
04f9H
eb83H
7b01H
cae0H
0400H
0074H
90H
91H
92H
93H
94H
95H
96H
97H
98H
99H
9aH
9bH
9cH
9dH
9eH
9fH
a0H
a1H
a2H
a3H
a4H
a5H
a6H
a7H
a8H
a9H
aaH
abH
acH
adH
aeH
b3H
b4H
b6H
b8H
b9H
7f18H
0400H
001eH
7fc5H
0002H
7ffdH
8000H
dd1eH
da82H
109cH
2641H
3441H
dd1eH
109cH
da82H
2641H
3441H
0bbfH
e755H
4000H
f619H
e57eH
36dcH
5a82H
10c9H
2641H
7f18H
7e30H
4cbaH
c216H
0aa4H
27b4H
7e14H
7ff9H
0063H
0000H
baH
bbH
bcH
bdH
beH
bfH
c0H
c1H
c2H
c3H
c4H
c5H
c6H
c7H
c8H
c9H
caH
cbH
ccH
cdH
ceH
cfH
d0H
d1H
d2H
d3H
d5H
d7H
d8H
daH
dbH
deH
dfH
e3H
e4H
e5H
43b9H
0400H
401eH
ec00H
8000H
a000H
0024H
ff92H
010aH
fce2H
097bH
e38dH
1555H
0400H
1400H
2000H
c000H
ffe4H
febcH
f520H
c144H
a57eH
0757H
0012H
7f00H
7fffH
fc00H
68a9H
5121H
7ff4H
7fe8H
8000H
c400H
0000H
0000H
0000H
e6H
e7H
e8H
e9H
eaH
ebH
ecH
edH
eeH
efH
f0H
f9H
feH
ffH
0000H
0000H
0000H
0000H
0000H
0000H
0000H
0000H
0000H
0000H
7fffH
8000H
b800H
0001H
Table 8-1-2. Pro Logic Mode Fixed Value Coefficients
– 29 –
CXD2724AQ-1
• Pro Logic mode user setting coefficients
The relationships between the coefficient RAM and each function during Pro Logic mode operation are as
follows.
Address
00H
01H
02H
03H
04H
05H
06H
07H
08H
09H
0aH
0bH
0cH
0dH
0eH
0fH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1aH
1bH
1cH
1dH
1eH
1fH
20H
21H
22H
23H
24H
Symbol
KLV
KRV
KCV
KSV
KLm1
KRm1
a0
a1
b
KLm2
KRm2
a0
a1
b
KLd
KRd
KCd
KSd
Kfb
a0
a1
b
a0
a1
b
KDin
TP1
TP2
TP3
TP4
TP5
TP6
KDout
KDV1
KDV2
KDV3
KLRm1
Function
Simple SFC: L-ch dry → L-ch mix volume
Simple SFC: R-ch dry → R-ch mix volume
Simple SFC: C-ch → C-ch volume
Simple SFC: S + L/R (HPF1) → S-ch mix volume
Simple SFC: L-ch → LPF1 mix volume
Simple SFC: R-ch → LPF1 mix volume
Simple SFC: LPF1 coefficient
Simple SFC: LPF1 coefficient
Simple SFC: LPF1 coefficient
Simple SFC: L-ch → HPF1 mix volume
Simple SFC: R-ch → HPF1 mix volume
Simple SFC: HPF1 coefficient
Simple SFC: HPF1 coefficient
Simple SFC: HPF1 coefficient
Simple SFC: L-ch → Delay RAM mix volume
Simple SFC: R-ch → Delay RAM mix volume
Simple SFC: C-ch → Delay RAM mix volume
Simple SFC: S-ch → Delay RAM mix volume
Simple SFC: Delay RAM feedback volume
Simple SFC: HPF2 coefficient
Simple SFC: HPF2 coefficient
Simple SFC: HPF2 coefficient
Simple SFC: LPF2 coefficient
Simple SFC: LPF2 coefficient
Simple SFC: LPF2 coefficient
Simple SFC: Delay RAM write address
Simple SFC: Delay RAM read Tap1 address
Simple SFC: Delay RAM read Tap2 address
Simple SFC: Delay RAM read Tap3 address
Simple SFC: Delay RAM read Tap4 address
Simple SFC: Delay RAM read Tap5 address
Simple SFC: Delay RAM read Tap6 address
Simple SFC: Delay RAM feedback Tap address
Simple SFC: Delay RAM → S-ch mix volume
Simple SFC: Delay RAM → R-ch mix volume
Simple SFC: Delay RAM → L-ch mix volume
Simple SFC: LPF1 → L-ch mix volume
Table 8-1-3 (1). Pro Logic Mode Setting Value Coefficients
– 30 –
Setting value
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-16.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-15.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
CXD2724AQ-1
Address
25H
26H
28H
29H
2aH
2bH
2cH
2dH
afH
b0H
b1H
b2H
b5H
b7H
d4H
d6H
d9H
dcH
ddH
f2H
f3H
f4H
f5H
f6H
f7H
f8H
faH
fbH
Symbol
KLRm2
KLRm3
KTP1
KTP2
KTP3
KTP4
KTP5
KTP6
b2
b1
a
–a
aslw
2D
Kx
KiA
Ke
Kia
Kis
KL
KR
KH
KP
KCH
KCP
KS
Kdlb
Dly
Function
Simple SFC: LPF1 → R-ch mix volume
Simple SFC: HPF1 → S-ch mix volume
Simple SFC: Tap1 volume
Simple SFC: Tap2 volume
Simple SFC: Tap3 volume
Simple SFC: Tap4 volume
Simple SFC: Tap5 volume
Simple SFC: Tap6 volume
7K LPF parameter
7K LPF parameter
7K LPF parameter
7K LPF parameter
Passive decoder M-BNR
Passive decoder M-BNR
Auto input balance ON/OFF
Serial audio interface input volume
De-emphasis ON/OFF
Analog input mix volume
Digital input mix volume
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Passive decoder volume
Passive decoder M-BNR ON/OFF
Passive decoder delay time adjustment
Table 8-1-3 (2). Pro Logic Mode Setting Value Coefficients
– 31 –
Setting value
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
See Table 8-1-13.
0000 = OFF, df66 = ON
0000 = OFF, 5723 = ON
0000 = OFF, 125e = ON
8000 = OFF, eda2 = ON
See Table 8-1-12.
See Table 8-1-12.
0000 = OFF, 00ff = ON
See Table 8-1-5.
0000 = OFF, ac19 = ON
See Table 8-1-4.
See Table 8-1-5.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Table 8-1-8.
0000 = OFF, 2000 = ON
See Table 8-1-9.
SIA2
SIA1
RIN
LIN
LPF
LPF
–KiA (d6H)
–KiA (d6H)
ADC
ADC
DeEmphasis
DeEmphasis
Decimation
Decimation
DC Cut
DC Cut
(2)-3. Signal Flow for Dolby Pro Logic Mode
– 32 –
–Kis (ddH)
–Kia (dcH)
–Kis (ddH)
–Kia (dcH)
Rt
S
C
R
L
Fig. 8-1-1
Pro
Logic
Decoder
Lt
R
L
S
C
S
C
Simple SFC
R
L
Over
Sampling
Over
Sampling
Over
Sampling
Over
Sampling
DAC
DAC
DAC
DAC
LPF
LPF
Trim
Vol
Trim
Vol
MUX &
LPF
MUX &
LPF
XSOUT
XCOUT
ROUT
LOUT
CXD2724AQ-1
CXD2724AQ-1
(3) Volume Coefficient Settings
[Relevant data] Coefficients: KiA (d6H), Kia (dcH), Kis (ddH)
The I/O levels and volumes are 2's complement format with a decimal point between D15 and D14, and
hexadecimal notation with D15 as MSB and D0 as LSB.
The coefficient and level relationships are as follows.
∗ D15 to D0 are negative values, but the DSP calculation is (–1) × (D15 to D0).
(3)-1. Kia (dcH): 0dB = c000H
The I/O levels for 8000H to ffffH are obtained by the following formulas.
D15 to D0
Level [dB]
8000H
a599H
c000H
d2b2H
e000H
eff6H
ffffH
0000H
+6.02
+3.00
0.00
–3.00
–6.02
–12.00
–84.29
–∞
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–2)
n=0
I/O level = 20 log [coefficient value] dB
Table 8-1-4. Kia (dcH) Setting Value Examples
(3)-2. KiA (d6H), Kis (ddH): 0dB = 8000H
The I/O levels for 8000H to ffffH are obtained by the following formulas.
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–1)
n=0
I/O level = 20 log [coefficient value] dB
D15 to D0
Level [dB]
8000H
a563H
c000H
e000H
ffffH
0000H
0.00
–3.00
–6.02
–12.04
–90.31
–∞
Table 8-1-5. KiA (d6H), Kis (ddH) Setting Value Examples
∗ Unless otherwise specified, subsequent setting examples (Pro Logic mode) in these specifications assume
either:
Kia = d2b2H, KiA = 0000H, Kis = 0000H
or:
Kia = 0000H, KiA = 8000H, Kis = a563H
(4) Auto Input Balance Control
[Relevant data] Coefficient: Kx (d4H)
The auto input balance function is turned on and off by coefficient Kx (d4H).
Coefficient
Kx (d4H)
ON = 00ffH
OFF = 0000H
Table 8-1-6. Auto Input Balance ON/OFF
– 33 –
CXD2724AQ-1
(5) Center Mode Control
[Relevant data] Coefficients: KP (f5H), KH (f4h), KL (f2H), KR (f3H), KCP (f7H), KCH (f6H)
The center channel output mode can be set to Normal, Wide or Phantom mode as shown in Table 8-1-7 below.
Mode
KP (f5H)
KH (f4H)
KL (f2H)
KR (f3H)
KCP (f7H)
KCH (f6H)
e000H
e000H
d2cdH
d2cdH
0000H
e000H
Wide
0000H
0000H
d2cdH
d2cdH
e000H
0000H
Phantom
e000H
0000H
d2cdH
d2cdH
0000H
0000H
Coefficient
Normal
Table 8-1-7. Center Mode Control Setting Value Examples
–KL (f2H)
LP
LO
–KR (f3H)
RP
RO
–KH (f4H), –KP (f5H)
LPF
CP
–KCH (f6H)
HPF
–KCP (f7H)
CO
Note) If KH is set to 0000H in Phantom center channel mode, the LPF is set to
data through status and the data added to the L and R channels is CP × KP.
Fig. 8-1-2. Signal Flow for Center Mode Control (L, R, C-ch)
Note) In Phantom center channel mode, the center channel information is divided equally between the left and
right speakers.
The level of each channel can be adjusted by changing
the KP, KH, KL, KR, KCP and KCH setting values. In
these cases, be sure to change only the shaded portions
for each mode in Table 8-1-7.
However, make sure that KP = KH in Normal mode. In
Phantom mode, set KH to 0000H and adjust the mix level
to the left and right channels using KP.
The I/O levels for 8000H to ffffH are obtained by the
following formulas.
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–4)
n=0
I/O level = 20 log [coefficient value] dB
D15 to D0
Level [dB]
8000H
c000H
d2cdH
e000H
e959H
eff6H
f7f6H
ffffH
0000H
+12.04
+6.02
+3.00
0
–3.00
–6.00
–12.00
–78.27
–∞
Table 8-1-8. KP, KH, KL, KR, KCP, KCH and KS
Setting Value Examples
∗ In Table 8-1-7, lowering the input level by 3dB using Kia (dcH) or Kis (ddH) raises the output level of the L
and R channels by 3dB. In this case, attaching external parts as shown in the Application Circuit is
recommended to increase the C and S channel gains.
– 34 –
CXD2724AQ-1
(6) Passive Decoder (Surround Channel)
The surround channel is processed according to the flow shown in Fig. 8-1-3.
The setting method for each section is described below.
–KS (f8H)
7kHz
LPF
SP
M-BNR
Delay
SO
Fig. 8-1-3. Passive Decoder Signal Flow (S-ch)
(6)-1. Delay Time Setting
Setting value Dly (fbH)
Delay (fs = 44.1kHz)
0020H
0040H
·
·
52b0H
·
6e40H
·
89d0H
·
a560H
·
·
bf80H
bfa0H
0.022ms
0.045ms
·
·
15.000ms
·
20.000ms
·
25.000ms
·
30.000ms
·
·
34.739ms
34.762ms
[Relevant data] Coefficient: Dly (fbH)
The surround channel delay time can be varied
by setting the coefficient Dly value. (Dly is the
delay line read address.)
Only the upper 11 of the 16 coefficient bits are
used. The lower 5 bits are not used, and are
ignored even if set.
That is to say, Dly can be set in 0020H
increments, and the delay time can be set in
approximately 0.022 ms increments.
The following condition also applies.
• 0020H ≤ Dly ≤ bfa0H
Table 8-1-9. Surround Channel (S-ch) Delay Time Setting
Value Examples
The coefficient value is calculated as follows.
(Dly) Decimal = (Delay [s] × fs [Hz] × 32
Example) For 20ms (fs = 44100 [Hz])
0.02 × 44100 × 32 = 28224
Hexadecimal conversion
6e40H
(6)-2. 7kHz Low-Pass Filter
[Relevant data] Coefficients: b2 (afH), b1 (b0H), a (b1H), –a (b2H)
The 7kHz LPF of the passive decoder can be turned on and off by setting the coefficients in Table 8-1-10.
ON
OFF
b2
b1
a
–a
df66
0000
5723
0000
125e
0000
eda2
8000
Table 8-1-10. Passive Decoder 7kHz LPF ON/OFF Setting
– 35 –
CXD2724AQ-1
(6)-3. Modified Dolby B-type NR
[Relevant data] Coefficients: aslw (b5H), 2D (b7H), KiA (d6H), Kia (dcH), Kis (ddH), Kdlb (faH)
The aslw and 2D coefficients and the ON/OFF coefficient Kdlb must be set for Modified Dolby B-type NR.
This function is turned on and off by setting Kdlb as shown in Table 8-1-11. The aslw and 2D coefficient values
differ according to the Dolby level, prefilter and coefficient Kia/Kis (KiA) conditions. Table 8-1-12 shows typical
setting value examples based on these three conditions. The prefilter gain (= –3.52dB) is the value when using
the Application Circuit given in these specifications.
Consult your Sony representative with regard to use under conditions other than those noted in Table 8-1-12.
Coefficient
Kdlb (faH)
ON = 2000H
OFF = 0000H
Table 8-1-11. Modified Dolby B-type NR ON/OFF Setting
Prefilter
Dolby level
Kia (dcH)
Kis (ddH)
aslw (b5H)
2D (b7H)
–3.52dB
300mVrms
d2b2H
0000H
00caH
0033H
–3.52dB
300mVrms
c000H
0000H
009eH
004aH
–3.52dB
200mVrms
d2b2H
0000H
00caH
0023H
(Digital input)
–20dBFS
0000H
a563H
00caH
0023H
Table 8-1-12. Modified Dolby B-type NR Coefficient Value Examples for Different Input Level Conditions
(during digital input: KiA (d6H) = 8000H)
(6)-4. Volume
[Relevant data] Coefficient: KS (f8H)
The KS (f8H) volume values are as shown in Table 8-1-8. See "5. Center Mode Control" for the calculation
method.
– 36 –
CXD2724AQ-1
(7) Simple SFC
Simple SFC effects can be added after Dolby Pro Logic Surround decoder processing. (See Fig. 8-1-1.)
Fig. 8-1-4 shows the signal flow for the simple SFC block.
When not using simple SFC, set the coefficients as follows to set the simple SFC block to through status.
KLV (00H), KRV (01H), KCV (02H), KSV (03H) = 8000H
KDV1 (21H), KDV2 (22H), KDV3 (23H), KLRm1 (24H), KLRm2 (25H), KLRm3 (26H) = 0000H
–KCV (02H)
C
C
–KLV (00H)
L
L
–KRV (01H)
R
R
–KCd (10H)
–Kfb (12H)
–KRd (0fH)
Delay
KDin
KDout
TP1 TP2 TP3 TP4 TP5 TP6
HPF2 + LPF2
13H to 18H
–KDV3
(23H)
–KLd (0eH)
1
–KSd (11H)
2
3
4
5
–KTP1 to –KTP6
(28H to 2dH)
–KRm1 (05H)
6
–KDV2
(22H)
–KLRm1
(24H)
–KLRm2
(25H)
–KDV1 (21H)
LPF1
06H to 08H
–KLm1 (04H)
–KRm2 (0aH)
HPF1
0bH to 0dH
–KLm2 (09H)
–KLRm3 (26H)
–KSV (03H)
S
S
Fig. 8-1-4. Simple SFC Signal Flow
– 37 –
CXD2724AQ-1
(7)-1. Volume Settings for Each Section
[Relevant data] Coefficients: KLV (00H), KRV (01H), KCV (02H), KSV (03H), KLm1 (04H), KRm1 (05H),
KLm2 (09H), KRm2 (0aH), KLd (0eH), KRd (0fH), KCd (10H), KSd (11H),
Kfb (12H), KDV1 (21H), KDV2 (22H), KDV3 (23H), KLRm1 (24H),
KLRm2 (25H), KLRm3 (26H), KTP1 (28H), KTP2 (29H), KTP3 (2aH),
KTP4 (2bH), KTP5 (2cH), KTP6 (2dH)
The format is the same as that described in "(3) Volume Coefficient Settings". The levels are as follows when
0dB = 8000H.
The I/O levels for 8000H to ffffH are obtained by the following formulas.
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–1)
n=0
I/O level = 20 log [coefficient value] dB
D15 to D0
Level [dB]
8000H
a563H
c000H
d2b2H
e000H
f000H
ffffH
0000H
0.00
–3.00
–6.02
–9.02
–12.04
–18.06
–90.31
–∞
Table 8-1-13. Setting Value Examples for Each Volume
(Negative Values)
The above coefficients are normally applied as negative values, but positive values should be applied when
intentionally inverting the phase with TP1 to TP6, etc. In this case, the levels are as follows when 0dB = 7fffH.
The I/O levels for 7fffH to 0001H are obtained by the following formulas.
14
(Coefficient value) = [D15 + ∑ (Dn × 2n – 15)]
n=0
I/O level = 20 log [coefficient value] dB
D15 to D0
Level [dB]
7fffH
5a9dH
4000H
2d4eH
2000H
1000H
0001H
0000H
0.00
–3.00
–6.02
–9.02
–12.04
–18.06
–90.31
–∞
Table 8-1-14. Setting Value Examples for Each Volume
(Positive Values)
– 38 –
CXD2724AQ-1
(7)-2. Delay Line Settings
[Relevant data] Coefficients: KDin (19H), TP1 (1aH), TP2 (1bH), TP3 (1cH), TP4 (1dH), TP5 (1eH),
TP6 (1fH), KDout (20H)
The Pro Logic mode delay lines are used for both the passive decoder short delay and the simple SFC
reverberation, and are thus subject to the following restrictions:
• Dly + 0020H ≤ KDin (0020H ≤ Dly ≤ KDin – 0020H)
• 0020H ≤ TP∗ ≤ KDout
• KDin + KDout ≤ bfe0H
Dly (fbH): Pro Logic delay line read address
KDin (19H): Simple SFC delay line write address
TP1 to TP6 (1aH to 1fH): Simple SFC tap read addresses (determine the delay time for each tap)
KDout (20H): Simple SFC feedback loop read address (determines the maximum delay time)
Note) The minimum unit for all the above coefficients is "0020H". Values smaller than this are ignored.
The TP1 to TP6 and KDout addresses are specified in a different
manner than Dly and KDin. These addresses are specified by the
address value assuming KDin as the reference (= 0000H).
That is to say, the actual address is KDin + KDout, etc.
The coefficient values are calculated as follows.
Delay
Setting value
KDout, TP1 to TP6 (fs = 44.1kHz)
0020H
0040H
·
·
1a60H
·
35f0H
·
5180H
·
6d10H
·
·
bf80H
bfa0H
(Dly) Decimal = (Delay [s]) × fs [Hz] × 32
Example) When using 20ms for the passive decoder, and all
remaining delay lines as reverberation
20ms → Dly = 6e40H
KDin = 6e40H + 0020H = 6e60H
KDout = bfe0H – 6e60H = 5180H
0020H ≤ TP1 to 6 ≤ 5180H
0.022ms
0.045ms
·
·
4.784ms
·
9.784ms
·
14.784ms
·
19.784ms
·
·
34.739ms
34.762ms
Table 8-1-15. Simple SFC Delay Time Setting
Value Examples
Passive decoder
0000H
20.0ms
Dly
6e40H
KDin
6e60H
Simple SFC
KDout
14.8ms
5180H
34.8ms (0000H to bfe0H)
Fig. 8-1-5. Pro Logic Mode Delay Line Setting Example
– 39 –
CXD2724AQ-1
(7)-3. Filters
[Relevant data] Coefficients: a0 (06H, 0bH, 13H, 16H), a1 (07H, 0cH, 14H, 17H), b (08H, 0dH, 15H, 18H)
LPF1, HPF1, LPF2 and HPF2 are comprised of primary IIR filters, and the coefficient setting and cut-off
frequency relationship are as shown in Table 8-1-16.
LPF1, 2
HPF1, 2
Cut-off
frequency [Hz]
a0
a1
b
a0
a1
b
100
200
300
400
500
600
700
800
900
1000
1200
1400
1600
1800
2000
2200
2400
2600
2800
3000
3200
3400
3600
3800
4000
4200
4400
4600
4800
5000
FF19
FE34
FD53
FC74
FB99
FAC1
F9EB
F918
F848
F77A
F5E6
F45C
F2DB
F162
EFF2
EE89
ED28
EBCE
EA7A
E92D
E7E6
E6A5
E569
E432
E301
E1D4
E0AB
DF87
DE67
DD4B
00E7
01CC
02AD
038C
0467
053F
0615
06E8
07B8
0886
0A1A
0BA4
0D25
0E9E
100E
1177
12D8
1432
1586
16D3
181A
195B
1A97
1BCE
1CFF
1E2C
1F55
2079
2199
22B5
7E30
7C67
7AA4
78E7
7731
7580
73D4
722E
708E
6EF2
6BCB
68B6
65B4
62C3
5FE2
5D11
5A4E
579A
54F3
5259
4FCB
4D48
4AD0
4863
4600
43A6
4155
3F0D
3CCD
3A94
80E8
81CD
82AE
838D
8468
8540
8616
86E9
87B9
8887
8A1B
8BA5
8D26
8E9F
900F
9178
92D9
9433
9587
96D4
981B
995C
9A98
9BCF
9D00
9E2D
9F56
A07A
A19A
A2B6
7F18
7E33
7D52
7C73
7B98
7AC0
79EA
7917
7847
7779
75E5
745B
72DA
7161
6FF1
6E88
6D27
6BCD
6A79
692C
67E5
66A4
6568
6431
6300
61D3
60AA
5F86
5E66
5D4A
7E30
7C67
7AA4
78E7
7731
7580
73D4
722E
708E
6EF2
6BCB
68B6
65B4
62C3
5FE2
5D11
5A4E
579A
54F3
5259
4FCB
4D48
4AD0
4863
4600
43A6
4155
3F0D
3CCD
3A94
LPF1, 2
HPF1, 2
Cut-off
frequency [Hz]
a0
a1
b
a0
a1
b
5200
5400
5600
5800
6000
6200
6400
6600
6800
7000
7200
7400
7600
7800
8000
8200
8400
8600
8800
9000
9200
9400
9600
9800
10000
10200
10400
10600
10800
11000
OFF
DC32
DB1D
DA0C
D8FD
D7F2
D6E9
D5E3
D4DF
D3DE
D2DF
D1E3
D0E8
CFEF
CEF8
CE03
CD0F
CC1D
CB2B
CA3B
C94D
C85F
C772
C685
C59A
C4AF
C3C5
C2DA
C1F1
C107
C01E
8000
23CE
24E3
25F4
2703
280E
2917
2A1D
2B21
2C22
2D21
2E1D
2F18
3011
3108
31FD
32F1
33E3
34D5
35C5
36B3
37A1
388E
397B
3A66
3B51
3C3B
3D26
3E0F
3EF9
3FE2
0000
3863
3639
3416
31F9
2FE2
2DD0
2BC4
29BD
27BB
25BD
23C4
21CF
1FDD
1DEF
1C04
1A1C
1838
1655
1475
1298
10BC
0EE2
0D09
0B32
095C
0788
05B3
03E0
020D
003A
0000
A3CF
A4E4
A5F5
A704
A80F
A918
AA1E
AB22
AC23
AD22
AE1E
AF19
B012
B109
B1FE
B2F2
B3E4
B4D6
B5C6
B6B4
B7A2
B88F
B97C
BA67
BB52
BC3C
BD27
BE10
BEFA
BFE3
8000
5C31
5B1C
5A0B
58FC
57F1
56E8
55E2
54DE
53DD
52DE
51E2
50E7
4FEE
4EF7
4E02
4D0E
4C1C
4B2A
4A3A
494C
485E
4771
4684
4599
44AE
43C4
42D9
41F0
4106
401D
0000
3863
3639
3416
31F9
2FE2
2DD0
2BC4
29BD
27BB
25BD
23C4
21CF
1FDD
1DEF
1C04
1A1C
1838
1655
1475
1298
10BC
0EE2
0D09
0B32
095C
0788
05B3
03E0
020D
003A
0000
Table 8-1-16. Simple SFC HPF and LPF Setting Coefficients
– 40 –
CXD2724AQ-1
8-2. Virtual Dolby Surround Mode (Virtual Mode)
Virtual mode is comprised of the Dolby Pro Logic Surround decoder and the Virtualizer as shown in Fig. 8-2-1.
Virtual Dolby Surround is realized by the Virtualizer block.
(1) Setting Virtual Mode
Virtual mode must be set by the following procedures in order to achieve stable adaptive matrix operation.
Setting Virtual mode by procedures other than those given below may aggravate the decoder characteristics.
• Immediately after power-on reset
i) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ Field C is "All 0", so the DAC forced mute is applied.
ii) Transfer the Virtual mode coefficient data.
iii) Transfer the setup data set in Virtual mode.
• Changing to Virtual mode from a different mode
i) Apply the soft mute in the current mode.
ii) Set the coefficients at the following addresses to "0000H".
Addresses: 6eH to 7fH
iii) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ The DAC forced mute is not applied by Field C.
iv) Transfer the Virtual mode coefficients for the soft mute status.
v) Transfer the setup data set in Virtual mode.
vi) Cancel the Virtual mode soft mute.
(2) Setting Data
(2)-1. Setup Data
Table 8-2-1 lists the registers most closely related to Virtual mode.
Setup data not listed in Table 8-2-1 may be set as desired, with due consideration given to the contents of
Fields A to D noted in "6. Setup Register".
Register name Setting value
Remarks
SQA14
"0"
1: Noise sequencer mode
SQA13
"1"
1: Virtual mode
SQA09, 08
"00"
01: Dolby 3 Stereo mode
SQA05, 04
"00"
01: SFC mode
SQD02 to 00
"100"
Coefficient RAM area setting (111: Other than Virtual mode, 100: Virtual mode)
Table 8-2-1. Virtual Mode Setup Register Settings
– 41 –
CXD2724AQ-1
(2)-2. Coefficient Data
The coefficient RAM area for Virtual mode is from addresses 80H to ffH. Addresses 00 to 7fH use the ROM
data. (The ROM contents are mainly the coefficients used by the Virtualizer.)
Like Pro Logic mode, the coefficient data consists of fixed values and setting values, with all fixed values
exactly the same as for Pro Logic mode.
Use the area from address 80H in Table 8-1-2. The setting values are as shown in Table 8-2-2, and consist of
adding the Virtualizer attenuation coefficient attV (f1H) setting to the Wide center mode settings of Pro Logic
mode.
Address
afH
b0H
b1H
b2H
b5H
b7H
d4H
d6H
d9H
dcH
ddH
f1H
f2H
f3H
f4H
f5H
f6H
f7H
f8H
faH
fbH
Symbol
b2
b1
a
–a
aslw
2D
Kx
KiA
Ke
Kia
Kis
attV
KL
KR
KH
KP
KCH
KCP
KS
Kdlb
Dly
Function
7K LPF parameter
7K LPF parameter
7K LPF parameter
7K LPF parameter
Passive decoder M-BNR
Passive decoder M-BNR
Auto input balance ON/OFF
Serial audio interface input volume
De-emphasis ON/OFF
Analog input mix switch
Digital input mix switch
Virtual Dolby Surround attenuator
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Center mode control volume
Passive decoder volume
Passive decoder M-BNR ON/OFF
Passive decoder delay time setting
Table 8-2-2. Virtual Mode Setting Value Coefficients
– 42 –
Setting value
0000 = OFF, df66 = ON
0000 = OFF, 5723 = ON
0000 = OFF, 125e = ON
8000 = OFF, eda2 = ON
See Table 8-1-12.
See Table 8-1-12
0000 = OFF, 00ff = ON
See Table 8-1-5.
0000 = OFF, ac19 = ON
See Table 8-1-4.
See Table 8-1-5.
See Table 8-2-3.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Tables 8-1-7, 8.
See Table 8-1-8.
0000 = OFF, 2000 = ON
See Table 8-1-9.
– 43 –
SIA2
SIA1
RIN
LIN
LPF
LPF
–KiA (d6H)
–KiA (d6H)
ADC
ADC
DeEmphasis
DeEmphasis
Decimation
Decimation
DC Cut
DC Cut
–Kis (ddH)
–Kia (dcH)
–Kis (ddH)
–Kia (dcH)
(2)-3. Signal Flow for Dolby Virtual Surround Mode
Rt
S
C
R
L
Fig. 8-2-1
Pro
Logic
Decoder
Lt
Virtual
Surround
Process
VR
VL
C
R
L
Virtualizer
Mixing
Over
Sampling
Over
Sampling
DAC
DAC
MUX &
LPF
MUX &
LPF
ROUT
LOUT
CXD2724AQ-1
CXD2724AQ-1
(3) Volume Coefficient Settings
[Relevant data] Coefficients: attV (f1H), KL (f2H), KR (f3H), KCP (f7H), KS (f8H)
Adjust the levels of the two Virtual mode channels by the amount of the four Pro Logic decoder output
channels using KL (f2H), KR (f3H), KCP (f7H) and KS (f8H). (See Table 8-1-7.)
The mixing level of the surround channel can be adjusted
with coefficient attV (f1H).
attV can be set in the range of 7fffH to 0000H as shown in
Table 8-2-3.
Coefficient value Level [dB]
7fffH
5a67H
3fffH
2d4eH
2000H
1000H
0001H
0000H
The I/O levels for 7fffH to 0001H are obtained by the
following formulas.
+6.02
+3.00
0.00
–3.00
–6.02
–12.04
–84.29
–∞
∗ Sony recommended value: 5333H (+2.28dB)
14
(Coefficient value) = [D15 + ∑ (Dn × 2n – 15)] × 2
Table 8-2-3. attV (f1H) Setting Value Examples
n=0
I/O level = 20 log [coefficient value] dB
Also, the most effective listening area is shown in Fig. 8-2-3.
Lch
L
Lt
Lt
L
L
L
R
–KR (f3H)
R
Rout
Mixing
C
1.2 to 2.0m
44°
C
attV (f1H)
–KCP (f7H)
Rt
R
Phantom
center
R
Rt
C
Lout
–KL (f2H)
Pro
Logic
Decoder
Rch
S
–KS (f8H)
VL
Virtual
Surround
Process
VR
Virtual
surround
Virtual
surround
S
S
attV (f1H)
Listening center
Fig. 8-2-2. Volume Setting Coefficients
Fig. 8-2-3. Listening Area
– 44 –
CXD2724AQ-1
8-3. Dolby 3 Stereo Mode
This mode is a part of the Pro Logic adaptive matrix functions.
Specifically, surround output is muted and surround signal directionality is not harmonized.
(1) Setting Dolby 3 Stereo Mode
Dolby 3 Stereo mode must be set by the following procedures in order to achieve stable adaptive matrix
operation. Setting Dolby 3 Stereo mode by procedures other than those given below may aggravate the
decoder characteristics.
• Immediately after power-on reset
i) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ Field C is "All 0", so the DAC forced mute is applied.
ii) Transfer the Dolby 3 Stereo mode coefficient data.
iii) Transfer the setup data set in Dolby 3 Stereo mode.
• Changing to Dolby 3 Stereo mode from Virtual mode
Note) The coefficients for the Dolby 3 Stereo mode or Pro Logic mode soft mute status must be set in
coefficient RAM addresses 00H to 7fH when shifting to Virtual mode.
i) Apply the soft mute in Virtual mode.
ii) Transfer the setup data set in Dolby 3 Stereo mode.
iii) Cancel the Dolby 3 Stereo mode soft mute.
• Changing to Dolby 3 Stereo mode from a different mode
i) Apply the soft mute in the current mode.
ii) Set the coefficients at the following addresses to "0000H".
Addresses: 6eH to 7fH
iii) Transfer the following setup data.
SQA = 0030H (Field A)
SQD = 7ee7H (Field D)
∗ The DAC forced mute is not applied by Field C.
iv) Transfer the Dolby 3 Stereo mode coefficients for the soft mute status.
v) Transfer the setup data set in Dolby 3 Stereo mode.
vi) Cancel the Dolby 3 Stereo mode soft mute.
– 45 –
CXD2724AQ-1
(2) Setting Data
(2)-1. Setup Data
Table 8-3-1 lists the registers most closely related to Dolby 3 Stereo mode.
Setup data not listed in Table 8-3-1 may be set as desired, with due consideration given to the contents of
Fields A to D noted in "6. Setup Register".
Register name Setting value
Remarks
SQA14
"0"
1: Noise sequencer mode
SQA13
"0"
1: Virtual mode
SQA09, 08
"01"
01: Dolby 3 Stereo mode
SQA05, 04
"00"
01: SFC mode
SQB15 to 11
Don't care
SQD02 to 00
"111"
Center channel (C-ch) trim volume
Coefficient RAM area setting (111: Other than Virtual mode, 100: Virtual mode)
Table 8-3-1. Dolby 3 Stereo Mode Setup Register Settings
(2)-2. Coefficient Data
The coefficient data used in Dolby 3 Stereo mode is entirely the same as that for Pro Logic mode. See "8-1.
Dolby Pro Logic Surround Mode".
– 46 –
CXD2724AQ-1
8-4. Noise Sequencer Mode
(1) Setting Noise Sequencer Mode
Set noise sequencer mode by the following procedures.
• Immediately after power-on reset
i) Transfer the setup data set in noise sequencer mode.
ii) Transfer the noise sequencer mode coefficient data.
• Changing to noise sequencer mode from a different mode
i) Apply the soft mute in the current mode.
ii) Transfer the setup data set in noise sequencer mode.
iii) Transfer the noise sequencer mode coefficient data.
(2) Setting Data
(2)-1. Setup Data
Table 8-4-1 lists the registers most closely related to noise sequencer mode.
Setup data not listed in Table 8-4-1 may be set as desired, with due consideration given to the contents of
Fields A to D noted in "6. Setup Register".
Register name Setting value
Remarks
SQA14
"1"
1: Noise sequencer mode
SQA13
"0"
1: Virtual mode
SQA09, 08
"00"
01: Dolby 3 Stereo mode
SQA05, 04
"00"
01: SFC mode
SQB15 to 11
Don't care
Center channel (C-ch) trim volume
SQB10 to 06
Don't care
Surround channel (S-ch) trim volume
SQD02 to 00
"111"
Coefficient RAM area setting (111: Other than Virtual mode, 100: Virtual mode)
Table 8-4-1. Noise Sequencer Mode Setup Register Settings
– 47 –
CXD2724AQ-1
(2)-2. Coefficient Data
Noise sequencer mode allows both Pro Logic and Virtual processing. Of the coefficients for these two types of
processing, change the coefficients from addresses d0H to e2H as shown in the tables below.
The other coefficients may be left as the Pro Logic mode or Virtual mode coefficient settings.
L-ch
C-ch
R-ch
S-ch
L→C→R→S
L→C→R
T1 (d0H)
T2 (d1H)
T3 (d2H)
T4 (d3H)
Address
Fixed value
2000
0000
0000
0000
2000
2000
2000
3000
0000
0000
3000
3000
2000
3000
4000
0000
4000
4000
2000
3000
4000
5000
5000
4000
d4H
d5H
d6H
d7H
d8H
d9H
daH
dbH
dcH
ddH
deH
dfH
e0H
e1H
e2H
1000H
0040H
c000H
d2b1H
0000H
2d4fH
0000H
d2b1H
c000H
d2b1H
8000H
7789H
6f12H
0876H
6f14H
Table 8-4-2. Noise Sequencer Mode Coefficient Setting Values
Table 8-4-3. Noise Sequencer Mode
Coefficient Fixed Values
(3) Output Level Adjustment
[Relevant data] Coefficients: KL (f2H), KR (f3H), KH (f4H), KP (f5H), KCH (f6H), KCP (f7H), KS (f8H)
The noise output level in noise sequencer mode is adjusted by the center mode control coefficients (f2H to
f7H) and the passive decoder volume coefficient (f8H)
See (5) and (6)-4 of "8-1. Pro Logic Mode".
8-5. SFC Mode
SFC mode is used for 2-channel stereo input, and realizes reverberation effects using the delay lines, and
dynamics processing using 1/2 and 1/3 decimation and the compressor.
∗ This is a separate application from the simple SFC of Pro Logic mode.
(1) Setting SFC Mode
Set SFC mode by the following procedures.
• Immediately after power-on reset
i) Transfer the setup data set in SFC mode.
ii) Transfer the SFC mode coefficient data.
• Changing to SFC mode from a different mode
i) Apply the soft mute in the current mode.
ii) Transfer the setup data set in SFC mode.
iii) Transfer the SFC mode coefficient data.
– 48 –
CXD2724AQ-1
(2) Setting Data
(2)-1. Setup Data
Table 8-5-1 lists the registers most closely related to SFC mode.
Setup data not listed in Table 8-5-1 may be set as desired, with due consideration given to the contents of
Fields A to D noted in "6. Setup Register".
Register name
Setting value
SQA11, 10
Don't care
SQA05, 04
"01"
Remarks
00: No decimation, 01: 1/2, 10: 1/3
01: SFC mode
SQB15 to 11
Don't care
Center channel (C-ch) trim volume
SQB10 to 06
Don't care
SQC07, 06
Don't care
Surround channel (S-ch) trim volume
00: No decimation, 01: 1/2, 1∗: 1/3
SQD02 to 00
"111"
Coefficient RAM area setting (111: SFC mode)
Table 8-5-1. SFC Mode Setup Register Settings
(2)-2. Coefficient Data
The SFC mode coefficient data uses the RAM for the entire area. Also, like other modes, the coefficient data
consists of fixed values and setting values.
• Fixed values during SFC mode initialization
The following fixed values must be set in the coefficient RAM to ensure proper DSP internal operation.
Address
Fixed value
Address
Fixed value
Address
Fixed value
Address
Fixed value
00H
01H
38H
39H
3aH
3bH
3cH
3dH
3eH
3fH
40H
41H
42H
43H
44H
45H
7fe8H
7fd1H
0000H
0092H
0209H
02cdH
0109H
fda9H
fd19H
0189H
058aH
016dH
f7beH
f72aH
0a4eH
2706H
46H
47H
48H
49H
4aH
4bH
4cH
4dH
4eH
4fH
50H
51H
52H
53H
54H
55H
34eeH
0000H
6000H
ff80H
00a1H
016eH
01f8H
0193H
0024H
fe70H
fdbaH
fed8H
015aH
037fH
0344H
ffffH
56H
57H
58H
59H
5aH
5bH
5cH
6dH
6eH
6fH
70H
71H
72H
73H
74H
75H
fb5cH
f8e3H
fbf6H
0575H
129cH
1e0dH
2294H
051eH
ff86H
02a0H
f6c0H
2715H
4000H
5149H
e571H
0f4eH
76H
77H
78H
79H
7aH
7bH
7cH
7dH
7eH
7fH
80H
94H
d7H
d8H
daH
dbH
f5b8H
075cH
fa97H
0402H
fd0bH
0225H
fe7cH
01d3H
f312H
4b85H
0000H
7fffH
68a9H
5121H
7ff4H
7fe8H
Table 8-5-2. SFC Mode Fixed Value Coefficients
– 49 –
CXD2724AQ-1
• SFC mode user setting coefficients
The relationships between the coefficient RAM and each function during SFC mode operation are as follows.
Address
02H
03H
04H
05H
06H
07H
08H
09H
0aH
0bH
0cH
0dH
0eH
0fH
10H
11H
12H
13H
14H
15H
16H
17H
18H
19H
1aH
1bH
1cH
1dH
1eH
1fH
20H
21H
22H
23H
24H
25H
26H
Symbol
k
XthP
XthM
Ksd
Ap
Am
Bp
Bm
Cp
Cm
KLsri
KRsri
Kfb
ahd
a00
a01
a02
b01
b02
KLtp0
KLtp1
KLtp2
KLtp3
KLtp4
KRtp0
KRtp1
KRtp2
KRtp3
KRtp4
KStp0
KStp1
KStp2
KStp3
b0
b1
KLdry
KRdry
Function
Compressor gain coefficient
Compressor threshold value (+)
Compressor threshold value (–)
Compressor ON/OFF
Compressor parameter
Compressor parameter
Compressor parameter
Compressor parameter
Compressor parameter
Compressor parameter
Delay line L-ch input volume
Delay line R-ch input volume
Delay line feedback coefficient
Feedback loop internal Hi-dump filter coefficient
Feedback loop internal LPF0 parameter
Feedback loop internal LPF0 parameter
Feedback loop internal LPF0 parameter
Feedback loop internal LPF0 parameter
Feedback loop internal LPF0 parameter
Delay line L-ch Tap0 volume
Delay line L-ch Tap1 volume
Delay line L-ch Tap2 volume
Delay line L-ch Tap3 volume
Delay line L-ch Tap4 volume
Delay line R-ch Tap0 volume
Delay line R-ch Tap1 volume
Delay line R-ch Tap2 volume
Delay line R-ch Tap3 volume
Delay line R-ch Tap4 volume
Delay line S-ch Tap0 volume
Delay line S-ch Tap1 volume
Delay line S-ch Tap2 volume
Delay line S-ch Tap3 volume
All pass filter 0 coefficient
All pass filter 1 coefficient
L-ch direct sound mix volume
R-ch direct sound mix volume
Table 8-5-3 (1). SFC Mode Setting Value Coefficients
– 50 –
Setting value
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-7.
0000 = OFF, 8000 = ON
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-7.
See Table 8-5-5.
See Table 8-5-5.
See Tables 8-5-5, 6.
See Table 8-2-8.
See Tables 8-5-9, 10, 11.
See Tables 8-5-9, 10, 11.
See Tables 8-5-9, 10, 11.
See Tables 8-5-9, 10, 11.
See Tables 8-5-9, 10, 11.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Tables 8-5-5, 6.
See Table 8-5-5.
See Table 8-5-5.
CXD2724AQ-1
Address
27H
28H
29H
2aH
2bH
2cH
2dH
2eH
2fH
30H
31H
32H
33H
34H
35H
36H
37H
5dH
81H
82H
83H
84H
85H
86H
87H
88H
89H
8aH
8bH
8cH
8dH
8eH
8fH
90H
91H
92H
93H
d6H
d9H
dcH
ddH
Symbol
KLeff
KReff
KLlpi
KRlpi
a10
a11
a12
b11
b12
KLlpo
KRlpo
KLod
KRod
KSod
KLd
KRd
KCod
Kd
Ltp0
Ltp1
Ltp2
Ltp3
Ltp4
Rtp0
Rtp1
Rtp2
Rtp3
Rtp4
Stp0
Stp1
Stp2
Stp3
tp_fb
ap0_in
ap0_out
ap1_in
ap1_out
KiA
Ke
Kia
Kis
Function
L-ch reflected sound mix volume
R-ch reflected sound mix volume
LPF1 L-ch input volume
LPF1 R-ch input volume
LPF1 parameter
LPF1 parameter
LPF1 parameter
LPF1 parameter
LPF1 parameter
LPF1 L-ch mix volume
LPF1 R-ch mix volume
L-ch output total volume
R-ch output total volume
S-ch output total volume
L-ch → C-ch mix volume
R-ch → C-ch mix volume
C-ch output total volume
Compressor input volume (both L and R)
Delay line L-ch Tap0 read address
Delay line L-ch Tap1 read address
Delay line L-ch Tap2 read address
Delay line L-ch Tap3 read address
Delay line L-ch Tap4 read address
Delay line R-ch Tap0 read address
Delay line R-ch Tap1 read address
Delay line R-ch Tap2 read address
Delay line R-ch Tap3 read address
Delay line R-ch Tap4 read address
Delay line S-ch Tap0 read address
Delay line S-ch Tap1 read address
Delay line S-ch Tap2 read address
Delay line S-ch Tap3 read address
Delay line feedback read address
All pass filter 0 delay RAM write address
All pass filter 0 delay RAM read address
All pass filter 1 delay RAM write address
All pass filter 1 delay RAM read address
Serial audio interface input volume
De-emphasis ON/OFF
Analog input mix switch
Digital input mix switch
Table 8-5-3 (2). Coefficient RAM Setting Data in SFC Mode
– 51 –
Setting value
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-9.
See Table 8-5-9.
See Table 8-5-9.
See Table 8-5-9.
See Table 8-5-9.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-5.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-12.
See Table 8-5-5.
0000 = OFF, ac19 = ON
See Table 8-5-4.
See Table 8-5-5.
RIN
LIN
SIA2
SIA1
Decimation
Decimation
DeEmphasis
DeEmphasis
DC_Cut1
DC_Cut1
– 52 –
0
0
1
1
Delay
0
3
b1 (24H)
Delay
–KSod (34H)
Hi-Sampling
Over
Sampling
Over
Sampling
–KRlpo (31H)
–KRod (33H)
–KRlpi (2aH)
(2bH to 2fH)
Secondary
LPF
LPF1
Over
Sampling
Over
Sampling
–KLlpo (30H)
–KLod (32H)
–KCod (37H)
–KLlpi (29H)
–KRdry (26H)
b1 (24H)
–KReff (28H)
2
–KLeff (27H)
1
–KRd (36H)
–KLd (35H)
–KLdry (25H)
(02H to 0bH)
Compressor
(02H to 0bH)
Compressor
–KStp
(1fH to 22H)
4
Delay
4
Hi-Sampling
3
3
Hi-Sampling
–Kd (5dH)
–Kd (5dH)
Fig. 8-5-1. Signal Flow for SFC Mode
b0 (23H)
2
2
b0 (23H)
–KRtp
(1aH to 1eH)
(10H to 14H)
Secondary
LPF
LPF0
–Kia (dcH)
–Kis (ddH)
–Kia (dcH)
–Kis (ddH)
–KLtp
(15H to 19H)
–Kfb (0eH)
ALL PASS FILTER
(REVERVE)
1, 1/2, 1/3
–KRsri (0dH)
Hi Dump
–ahd (0fH)
Down Sampling
–KLsri (0cH)
The settings for this section are the same as
for DPL mode. (Same coefficients and addresses)
ADC
ADC
–KiA (d6H)
–KiA (d6H)
(2)-3. Signal Flow
DAC
DAC
DAC
DAC
XSOUT
S-ch
ROUT
R-ch
LOUT
L-ch
XCOUT
C-ch
CXD2724AQ-1
CXD2724AQ-1
(3) Volume Settings
[Relevant data] Coefficients: KLsri (0cH), KRsri (0dH), Kfb (0eH), KLtp0 (15H), KLtp1 (16H),
KLtp2 (17H), KLtp3 (18H), KLtp4 (19H), KRtp0 (1aH), KRtp1 (1bH),
KRtp2 (1cH), KRtp3 (1dH), KRtp4 (1eH), KStp0 (1fH), KStp1 (20H),
KStp2 (21H), KStp3 (22H), b0 (23H), b1 (24H), KLdry (25H), KRdry (26H),
KLeff (27H), KReff (28H), KLlpi (29H), KRlpi (2aH), KLlpo (30H),
KRlpo (31H), KLod (32H), KRod (33H), KSod (34H), KLd (35H), KRd (36H),
KCod (37H), Kd (5dH), KiA (d6H), Kia (dcH), Kis (ddH)
The I/O levels and volumes are 2's complement format with a decimal point between D15 and D14, and
hexadecimal notation with D15 as MSB and D0 as LSB.
The coefficient and level relationships are as follows.
(3)-1. Kia (dcH): 0dB = c000H
The I/O levels for 8000H to ffffH are obtained by the following
formulas.
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–2)
n=0
I/O level = 20 log [coefficient value] dB
D15 to D0
Level [dB]
8000H
c000H
e000H
eff6H
ffffH
0000H
+6.02
0.00
–6.02
–12.00
–84.29
–∞
Table 8-5-4. Kia (dcH) Setting Value Examples
(3)-2. Other Coefficients
Except for Kia, the coefficients listed in the [Relevant data] above
are basically specified by negative values (D15 to D0) with "0dB =
8000H". When intentionally inverting the phase, however, specify
positive values with "0dB = 7fffH".
∗ The DSP calculation for coefficient values other than Kfb is
(–1) × (D15 to D0).
The I/O levels for 8000H to ffffH are obtained by the following
formulas.
14
(Coefficient value) = [(–1) × D15 + ∑ (Dn × 2n – 15)] × (–1)
n=0
I/O level = 20 log [coefficient value] dB
14
n=0
I/O level = 20 log [coefficient value] dB
Level [dB]
8000H
a563H
c000H
d2b2H
e000H
f000H
ffffH
0000H
0.00
–3.00
–6.02
–9.02
–12.04
–18.06
–90.31
–∞
Table 8-5-5. Setting Value Examples
for Each Volume
(Other than Kia, Negative Values)
The I/O levels for 7fffH to 0001H are obtained by the following
formulas.
(Coefficient value) = [D15 + ∑ (Dn × 2n – 15)]
D15 to D0
D15 to D0
Level [dB]
7fffH
5a9dH
4000H
2d4eH
2000H
1000H
0001H
0000H
0.00
–3.00
–6.02
–9.02
–12.04
–18.06
–90.31
–∞
Table 8-5-6. Setting Value Examples for Each Volume
(Other than Kia, Positive Values)
– 53 –
CXD2724AQ-1
(4) Compressor
[Relevant data] Coefficients: k (02H), XthP (03H), XthM (04H), Ksd (05H), Ap (06H), Am (07H), Bp (08H),
Bm (09H), Cp (0aH), Cm (0bH)
The parameter table is shown in Table 8-5-7, and the I/O characteristics in Fig. 8-5-2.
Compressor ON: Ksd (05H) = 8000H
Compressor OFF: Ksd (05H) = 0000H
Threshold
XthM
XthP
–∞ [dB]
Comp_5
0
0000
0
0000
–20 [dB]
Comp_4
–1/10
F334
1/10
0CCC
–17 [dB]
Comp_3
–1/7
EDB7
1/7
1249
–14 [dB]
Comp_2
–1/5
E667
1/5
1999
–9.5 [dB]
Comp_1
–1/3
D556
1/3
2AAA
Gain
k
6.0 [dB]
2.0
4000
5.2 [dB]
20/11
3A2E
4.4 [dB]
5/3
3555
2.9 [dB]
7/5
2CCC
1.6 [dB]
6/5
2666
Coefficient
Ap
Am
Bp
Bm
Cp
Cm
–1.0
E000
1.0
2000
2.0
4000
2.0
4000
0
0000
0
0000
–100/99
DFAE
100/99
2052
200/99
40A5
200/99
40A5
–1/99
FEB6
1/99
014A
–49/54
E2F7
49/54
1D09
52/27
3DA1
52/27
3DA1
–1/54
FDA2
1/54
025E
–5/8
EC00
5/8
1400
33/20
34CC
33/20
34CC
–1/40
FCCD
1/40
0333
–9/20
F19A
9/20
0E66
3/2
3000
3/2
3000
–1/20
F99A
1/99
0666
Table 8-5-7. Compressor Parameter Table
– 54 –
CXD2724AQ-1
Input Level [dB]
0
–30
–20
–10
Comp5
–10
Comp4
Output Level [dB]
Comp3
Linear
Comp2
Comp1
6.0 [dB]
–20
–30
–20
Comp4
–17
Comp3
–14
Comp2
–9.5
Comp1
Threshold Level [dB]
Fig. 8-5-2. Compressor I/O Characteristics
– 55 –
CXD2724AQ-1
(5) Hi-Dump Filter Setting
[Relevant data] Coefficient: ahd (0fH)
This filter is used to attenuate the high frequencies. It is mainly used in the delay line feedback loop to prevent
or alleviate noise generated when high frequency components are multiplied. Table 8-5-8 shows the
parameter table.
To turn off this filter, set "ahd = 8000H".
fc [Hz]
40
60
80
100
200
400
600
800
–ahd
1/1
1/2
1/3
EF46
FEEA
FE8D
FE31
FC68
F8EA
F585
F23A
FE8D
FDD5
FD1E
FC68
F8EA
F23A
EBEE
E603
FDD5
FCC3
FBB3
FAA6
F585
EBEE
E32F
DB3B
fc [Hz]
1k
2k
4k
6k
8k
10k
12k
14k
–ahd
1/1
1/2
1/3
EF08
E073
C97A
B91E
AD94
A578
9FC6
9BCC
E073
C97A
AD94
9FC6
9912
D404
B91E
9FC6
974D
Table 8-5-8. Hi-Dump Filter Parameter Table
(6) Secondary LPF Settings
[Relevant data] Coefficients: a00 (10H), a01 (11H), a02 (12H), b01 (13H), b02 (14H), a10 (2bH),
a11 (2cH), a12 (2dH), b11 (2eH), b12 (2fH)
These two LPF are comprised from the same secondary IIR filters. The parameter tables are shown in Tables
8-5-9 to 8-5-11. These tables show the parameters for no decimation, 1/2 decimation and 1/3 decimation,
respectively.
Use Table 8-5-9 (No decimation) for LPF1.
The coefficients used for the LPF0 and LPF1 parameters are as follows.
LPF0: a00 (10H), a01 (11H), a02 (12H), b01 (13H), b02 (14H)
LPF1: a10 (2bH), a11 (2cH), a12 (2dH), b11 (2eH), b12 (2fH)
To turn off the filters, set only a00 and a10 to "8000H" and the other four coefficient values to "0000H".
– 56 –
CXD2724AQ-1
a00
Cut-off
frequency [Hz] a10
5200
5300
5400
5500
5600
5700
5800
5900
6000
6100
6200
6300
6400
6500
6600
6700
6800
6900
7000
7100
7200
7300
7400
7500
7600
7700
7800
7900
8000
8100
F4A5
F448
F3EB
F38D
F32D
F2CD
F26D
F20B
F1A8
F145
F0E0
F07B
F016
EFAF
EF47
EEDF
EE76
EE0D
EDA2
ED37
ECCB
EC5E
EBF0
EB82
EB13
EAA4
EA33
E9C2
E950
E8DD
a01
a11
a02
a12
b01
b11
b02
b12
16B6
176F
182A
18E7
19A5
1A65
1B27
1BEA
1CB0
1D77
1E3F
1F09
1FD5
20A2
2171
2241
2313
23E7
24BC
2593
266B
2744
281F
28FC
29DA
2AB9
2B9A
2C7C
2D60
2E45
0B5B
0BB8
0C15
0C73
0CD3
0D33
0D93
0DF5
0E58
0EBB
0F20
0F85
0FEA
1051
10B9
1121
118A
11F3
125E
12C9
1335
13A2
1410
147E
14ED
155C
15CD
163E
16B0
1723
7FDF
7D90
7B43
78F7
76AD
7464
721C
6FD6
6D91
6B4D
690B
66CA
648A
624B
600D
5DD1
5B96
595C
5723
54EA
52B3
507D
4E48
4C14
49E1
47AF
457E
434D
411E
3EEF
D2B4
D391
D469
D53B
D609
D6D2
D796
D855
D910
D9C6
DA77
DB24
DBCD
DC71
DD10
DDAC
DE43
DED6
DF66
DFF0
E077
E0FA
E179
E1F4
E26C
E2DF
E34F
E3BA
E422
E487
a00
Cut-off
frequency [Hz] a10
8200
8300
8400
8500
8600
8700
8800
8900
9000
9100
9200
9300
9400
9500
9600
9700
9800
9900
10000
10100
10200
10300
10400
10500
10600
10700
10800
10900
11000
OFF
E86A
E7F6
E781
E70C
E696
E61F
E5A7
E52F
E4B6
E43C
E3C1
E346
E2CA
E24D
E1D0
E152
E0D3
E053
DFD3
DF52
DED0
DE4D
DDCA
DD45
DCC0
DC3B
DBB4
DB2D
DAA5
8000
a01
a11
a02
a12
b01
b11
b02
b12
2F2C
3014
30FD
31E8
32D5
33C3
34B2
35A3
3695
3788
387D
3974
3A6C
3B65
3C60
3D5C
3E5A
3F5A
405A
415D
4261
4366
446D
4575
467F
478B
4898
49A6
4AB7
0000
1796
180A
187F
18F4
196A
19E1
1A59
1AD1
1B4A
1BC4
1C3F
1CBA
1D36
1DB3
1E30
1EAE
1F2D
1FAD
202D
20AE
2130
21B3
2236
22BB
2340
23C5
244C
24D3
255B
0000
3CC1
3A93
3867
363B
3410
31E5
2FBB
2D92
2B69
2941
2719
24F2
22CB
20A5
1E7F
1C5A
1A35
1810
15EB
13C7
11A3
0F7F
0D5C
0B38
0915
06F2
04CF
02AC
0089
0000
E4E8
E545
E59E
E5F4
E647
E695
E6E1
E729
E76D
E7AE
E7EC
E826
E85D
E890
E8C0
E8ED
E917
E93D
E960
E980
E99C
E9B5
E9CB
E9DD
E9ED
E9F9
EA02
EA07
EA0A
0000
Table 8-5-9. Secondary LPF Parameter Table (No Decimation, Q = 0.707107)
– 57 –
CXD2724AQ-1
Cut-off
a00
frequency [Hz]
2600
2700
2800
2900
3000
3100
3200
3300
3400
3500
3600
3700
3800
3900
4000
F4A5
F3EB
F32D
F26D
F1A8
F0E0
F016
EF47
EE76
EDA2
ECCB
EBF0
EB13
EA33
E950
a01
a02
b01
b02
16B6
182A
19A5
1B27
1CB0
1E3F
1FD5
2171
2313
24BC
266B
281F
29DA
2B9A
2D60
0B5B
0C15
0CD3
0D93
0E58
0F20
0FEA
10B9
118A
125E
1335
1410
14ED
15CD
16B0
7FDF
7B43
76AD
721C
6D91
690B
648A
600D
5B96
5723
52B3
4E48
49E1
457E
411E
D2B4
D469
D609
D796
D910
DA77
DBCD
DD10
DE43
DF66
E077
E179
E26C
E34F
E422
Cut-off
a00
frequency [Hz]
4100
4200
4300
4400
4500
4600
4700
4800
4900
5000
5100
5200
5300
5400
5500
OFF
E86A
E781
E696
E5A7
E4B6
E3C1
E2CA
E1D0
E0D3
DFD3
DED0
DDCA
DCC0
DBB4
DAA5
8000
a01
a02
b01
b02
2F2C
30FD
32D5
34B2
3695
387D
3A6C
3C60
3E5A
405A
4261
446D
467F
4898
4AB7
0000
1796
187F
196A
1A59
1B4A
1C3F
1D36
1E30
1F2D
202D
2130
2236
2340
244C
255B
0000
3CC1
3867
3410
2FBB
2B69
2719
22CB
1E7F
1A35
15EB
11A3
0D5C
0915
04CF
0089
0000
E4E8
E59E
E647
E6E1
E76D
E7EC
E85D
E8C0
E917
E960
E99C
E9CB
E9ED
EA02
EA0A
0000
Table 8-5-10. Secondary LPF Parameter Table (1/2 Decimation, Q = 0.707107)
Cut-off
a00
frequency [Hz]
1800
1900
2000
2100
2200
2300
2400
2500
2600
2700
2800
2900
3000
3100
3200
3300
3400
3500
3600
OFF
F3EB
F2CD
F1A8
F07B
EF47
EE0D
ECCB
EB82
EA33
E8DD
E781
E61F
E4B6
E346
E1D0
E053
DED0
DD45
DBB4
8000
a01
a02
b01
b02
182A
1A65
1CB0
1F09
2171
23E7
266B
28FC
2B9A
2E45
30FD
33C3
3695
3974
3C60
3F5A
4261
4575
4898
0000
0C15
0D33
0E58
0F85
10B9
11F3
1335
147E
15CD
1723
187F
19E1
1B4A
1CBA
1E30
1FAD
2130
22BB
244C
0000
7B43
7464
6D91
66CA
600D
595C
52B3
4C14
457E
3EEF
3867
31E5
2B69
24F2
1E7F
1810
11A3
0B38
04CF
0000
D469
D6D2
D910
DB24
DD10
DED6
E077
E1F4
E34F
E487
E59E
E695
E76D
E826
E8C0
E93D
E99C
E9DD
EA02
0000
Table 8-5-11. Secondary LPF Parameter Table (1/3 Decimation, Q = 0.707107)
– 58 –
CXD2724AQ-1
(7) Delay Time Settings
[Relevant data] Coefficients: Ltp0 (81H), Ltp1 (82H), Ltp2 (83H), Ltp3 (84H), Ltp4 (85H), Rtp0 (86H),
Rtp1 (87H), Rtp2 (88H), Rtp3 (89H), Rtp4 (8aH), Stp0 (8bH), Stp1 (8cH),
Stp2 (8dH), Stp3 (8eH), tp_fb (8fH), ap0_in (90H), ap0_out (91H),
ap1_in (92H), ap1_out (93H)
Setup: SQA05, SQA04, SQC07, SQC06
First, select No decimation, 1/2 decimation or 1/3 decimation.
1/1 (No decimation): SQA11, 10 = "00", SQC07, 06 = "00"
1/2 decimation:
SQA11, 10 = "01", SQC07, 06 = "01"
1/3 decimation:
SQA11, 10 = "10", SQC07, 06 = "1∗" (∗ = Don't care)
Next, set tp_fb (8fH) which determines the comb filter delay time, and ap0_in (90H), ap0_out (91H), ap1_in
(92H) and ap1_out (93H) which determine the all pass filter delay times.
The following conditions apply.
• 0 ≤ tp_fb, tp_fb + 0020H ≤ ap0_in ≤ ap0_out, ap0_out + 0020H ≤ ap1_in ≤ ap1_out ≤ bfe0H
• 0 ≤ Comb filter tap (Ltp0 to Stp3) ≤ tp_fb
Note) The minimum unit for all the above coefficients is "0020H". Values larger than this are ignored.
(7)-1. Comb Filter
First, set the comb filter maximum delay time tp_fb (8fH). The coefficient value is calculated as follows.
(Dly) Decimal = (Delay [s]) × fs [Hz] × 32
(The delay value is multiplied by 1/2 and 1/3 during 1/2 and 1/3 decimation, respectively.)
Next set the delay times for the comb filter taps, and calculate the coefficient values in the same manner as for
tp_fb. (0 ≤ Tap ≤ tp_fb)
Example) For a maximum delay time of 36ms (1/2 decimation, fs = 44100Hz)
0.036 × (1/2) × 44100 × 32 = 25401.6
Rounding up to 25402 and converting to hexadecimal notation:
633aH
However, the address is specified in 0020H increments, so this becomes:
6340H
Therefore, set all (14) of the L, R and S channel taps to 6340H (36 ms) or less. For example, the L
channel settings could be:
Ltp0 = 1ba0H (10ms)
Ltp1 = 2960H (15ms)
Ltp2 = 3720H (20ms)
Ltp3 = 44e0H (25ms)
Ltp4 = 52c0H (30ms)
Set the R and S channels in the same manner.
– 59 –
CXD2724AQ-1
Delay (fs = 44.1kHz)
Setting
value
1/1 (No decimation)
1/2 decimation
1/3 decimation
0020H
0040H
·
·
3720H
·
6e40H
·
a560H
·
bf80H
bfa0H
0.022ms
0.045ms
·
·
10.000ms
·
20.000ms
·
30.000ms
·
34.739ms
34.761ms
0.045ms
0.090ms
·
·
20.000ms
·
40.000ms
·
60.000ms
·
69.478ms
69.523ms
0.068ms
0.136ms
·
·
30.000ms
·
60.000ms
·
90.000ms
·
104.217ms
104.285ms
Table 8-5-12. SFC Mode Delay Time Setting Value Examples
(7)-2. All Pass Filters (APF0, APF1)
The all pass filter delay times are determined by (read address) – (write address - 0020H). Set ap∗_in and
ap∗_out so that this subtraction results in the target delay time setting value. The calculation method is the
same as that for tp_fb.
Example) When setting a maximum comb filter delay time of 36ms and splitting the remainder evenly
between APF0 and APF1.
(1/2 decimation)
(bfe0H – 6340H)/2 = 2e50H
The address is specified in 0020H increments, so 2e40H is used for APF0, and 2e60H for APF1.
tp_fb = 6340H, so:
ap0_in = 6360H, ap0_out = 6340H + 2e40H = 9180H
ap1_in = 91a0H, ap1_out = 9180H + 2e60H = bfe0H
tp_fb
0000H
6340H
36.0ms
ap0_in
ap0_out
6360H
9180H
16.8ms
ap1_in
ap1_out
91a0H
bfe0H
16.8ms
69.6ms (0000H to bfe0H)
Fig. 8-5-3. Delay Time Setting Example (1/2 Decimation)
Note) Assuming the tap read address to be 0000H, the comb filter has a delay time of "0". However, the all
pass filters are delayed by one sample after reading from the delay RAM.
Therefore, perfect through operation is not possible even if (write address) = (read address).
– 60 –
CXD2724AQ-1
8-6. Bypass Mode
In this mode, the DSP is bypassed. The ADC and DAC are not used and both the L and R channels are in
analog-to-analog through status.
(1) Setting Bypass Mode
Set the uppermost bit (SQA15) of setup register Field A to "1".
The other setup data and coefficient data is "Don't care".
LIN
MUX &
LPF
LOUT
LPF
MUX &
LPF
ROUT
LPF
RIN
Fig. 8-6-1. Bypass Mode
In bypass mode, the output after ADC prefilter and the output after DAC postfilter are swtiched by the analog
switch. The popping noise occurs at switching due to the difference of these filter's reference voltages
(500mV). Therefore, the countermeasure against the noise, such as the system muting, is required when using
this mode.
– 61 –
CXD2724AQ-1
Appendix 1. Soft Mute
The condition where the final volume coefficient data connected to the CXD2724Q output of each mode is off
(= 0000H) is called "soft mute".
(Soft mute cannot be applied in bypass mode.)
Table 9 shows the coefficients that should be set to 0000H in each mode during soft mute. Table 9 also
includes the loop input volume coefficients and feedback volume coefficients for modes which contain a
feedback loop.
Mode name
Coefficient name (Address [H])
Pro Logic mode
KLV (00), KRV (01), KCV (02), KSV (03), KLd (0e), KRd (0f), KCd (10), KSd (11),
Kfb (12), KDV1 (21), KDV2 (22), KDV3 (23), KLRm1 (24), KLRm2 (25), KLRm3 (26),
KL (f2), KR (f3), KH (f4), KP (f5), KCH (f6), KCP (f7), KS (f8)
Virtual mode
attV (f1), KL (f2), KR (f3), KCP (f7), KS (f8)
Dolby 3 Stereo mode
Same as Pro Logic mode
Noise sequencer mode
Same as Pro Logic or Virtual mode
SFC mode
KLsri (0c), KRsri (0d), Kfb (0e), KLod (32), KRod (33), KSod (34), KCod (37)
Table 9. Recommended Mute Coefficients
RAM Initialization
Although this LSI contains a number of RAM, there is no clear function and the like. Therefore, it is impossible
to predict the type of data existing in the RAM after power-on. Also, the previous mode's data remains even
after the mode is changed, possibly causing momentary noise. If these problems cannot be handled by the
system mute, apply soft mute for a time equal to the maximum delay time of the delay RAM (varies according
to the mode and coefficient settings) during power-on and when changing the mode. This clears all the RAM.
Example 1) When using 20.0ms for the passive decoder and 14.8ms for the simple SFC delay line
The maximum delay time is 20.0ms, so soft mute must be applied continuously for 20.0ms.
Example 2) When using the delay RAM in SFC mode with 1/2 decimation
Comb filter delay time = 36.0ms
All pass filter delay time = 16.8ms
The maximum delay time is 36.0ms, so soft mute must be applied for 36.0ms.
– 62 –
CXD2724AQ-1
Appendix 2. Compensation Filter
This filter compensates the shoulder characteristics of the digital filters. Fig. 9 shows the frequency response
measured under the following conditions.
• Vin = 300mVrms (sine wave)
• Output level at 1kHz = 0dB
• DC cut filter cut-off = 5kHz
+2
+1
0
–1
Level [dB]
–2
–3
–4
–5
–6
Hosho filter [L-ch]
0dB = 300mVrms (1kHz sin)
–7
–8
–9
–10
10
20
50
100 200
500 1k
Frequency [Hz]
2k
5k
10k
20k
Fig. 9. Compensation Filter Frequency Response (Dotted line: Without the compensation filter)
Operation
Turn the filter on and off in each mode except bypass mode using SQA12 of setup register Field A. See "6.
Setup Register".
– 63 –
A
B
C
D
E
F
G
DGND
DGND DGND
XS24
VDD1
VSS4
T.P
DGND AGND
0.1µ
A
VSS3
SCK
T.P
SI
T.P
BCK
LRCK
XMST
VSS5
T.P
T.P
T.P
VSS0
VSS6
T.P
B
2
1
3
T.P
4
5
7
6
VSS1
DGND
DGND
DGND
G
AGND
AGND
DGND
0.1µ
0.1µ
F
AGND
0.1µ
AVS1 25
LO1 26
LIN 27
AVD5 28
AVS5 29
XCOUT 30
AVDX 31
XTLO 32
0.1µ
0.1µ
AGND
AGND
1.2k
100p
10k
330p
10µ
10k
Cout
Lin
AGND AGND
100k
Lout
AGND AGND
100k
AGND AGND
10µ
IC3
IC3
330p
AGND
10k
AGND
12k
AGND
1M
10µ
Sout
AGND AGND
IC2 100k
47p
IC2 100k
10µ
AGND AGND
Rin
Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for
any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same.
(Especially , the deviation of the A/D converter front-stage resistor has a bad influence on the separation when using Pro Logic)
∗ The phases of the center and surround channels are invertedand output. Therefore, be sure to invert them by the external amplifier.
33k
AGND
8.2k
47k
AGND
8.2k
47k
Rout
AGND AGND
100k
10µ
IC1
100k
100p
1M
10µ
AGND
330p
AGND
22k
AGND
1000p
3.3k
100p
15k
AGND
1000p
5.6k
AGND
1000p
1.2k
33k
10k
IC1
330p
AGND
330p
AGND
2200p
5.6k
AGND
12k
10k
AGND
15k
22k
AGND
AGND 2200p
10µ
E
AGND
10k
330p
AGND
1000p
3.3k
D
AGND 100k
10000p 22p
4.7µ
AGND
C
AGND
0.1µ
100k
AGND
AGND
22p
10µ
AGND
AGND
AVS2 40
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
DGND
0.1µ
8
TST1
∗ NE5522, containing 2 amplifiers, are used for operational amplifiers. Take care for their combinations.
∗ Use ±12V power supplies for the operational amplifiers and connect 0.1µF bypass capacitors.
∗ Use Daishinku (AT- 49, 33.8688MHz) for the crystal oscillator.
∗ Wiring indicated by bold lines should be (1) thick, (2) short, and (3) shielded around its periphery by GND.
∗ Resistor deviation: ±1%, capacitor deviation: ±5%
DGND
: ROUT +5V power supply
: RIN +5V power supply
: XSOUT +5V power supply
: Crystal oscillator circuit +5V power supply
: XCOUT +5V power supply
: LIN +5V power supply
: LOUT +5V power supply
: Digital +5V power supply
80 T.P
79 T.P
78 T.P
77 T.P
T.P
T.P
74 VSS7
T.P
DGND 75 T.P
DGND
76 T.P
T.P
73 VDD2
TST2
XTLI 33
TST4
AVSX 34
TST3
71 T.P
CSL1
72 T.P
AVD3
0.1µ
AVS6 36
T.P
XSOUT 35
TST0
70 T.P
VDD0
69 T.P
RVDT
AVD6 37
BFOT
68 T.P
REDY
RIN 38
CSL2
67 T.P
VSS2
LO2 39
AVD4
66 T.P
CXD2724AQ-1
XLAT
XRST
XRST
– 64 –
AVD1
0.1µ
DGND
DGND
Microcomputer
AGND
AVS4
AVS3
65 T.P
CXD2500AQ
LRCK DA15 DA16
0.1µ
AVD2
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41
DGND
DGND
0.1µ
XTAI
ROUT
LOUT
Application Circuit
CXD2724AQ-1
CXD2724AQ-1
Package Outline
Unit: mm
80PIN QFP (PLASTIC)
23.9 ± 0.4
+ 0.1
0.15 – 0.05
+ 0.4
20.0 – 0.1
64
0.15
41
65
16.3
17.9 ± 0.4
+ 0.4
14.0 – 0.1
40
A
+ 0.2
0.1 – 0.05
25
1
24
0.8
0.2
M
+ 0.15
0.35 – 0.1
+ 0.35
2.75 – 0.15
0° to 10°
DETAIL A
PACKAGE STRUCTURE
PACKAGE MATERIAL
EPOXY RESIN
SONY CODE
QFP-80P-L01
LEAD TREATMENT
SOLDER PLATING
EIAJ CODE
QFP080-P-1420
LEAD MATERIAL
42/COPPER ALLOY
PACKAGE MASS
1.6g
JEDEC CODE
– 65 –
0.8 ± 0.2
80