SAMSUNG KD16903

DATA PROCESSOR
KD16903
1. BLOCK DIAGRAM
1.1 SYSTEM BLOCK DIAGRAM
CKIN
RESB
VIP
SCL
SDA
VOCODER
DIN
FS
MCLK
DOUT
VOICE
CODEC
1
KD16903
DATA PROCESSOR
1.2 CHIP BLOCK DIAGRAM
SRAM
256
MSM
VOCODER
SRAM
256
I2C
I/F
SSP1611
Digital
I/F
CODEC
P.ROM 2K
VIP
NOTE:
2
Not Scaled
DATA PROCESSOR
KD16903
1.3 FUNCTIONAL BLOCK DIAGRAM
Voice
Intelligibility
Proces
DIN
DOUT
PCM
INPUT
I/F
BPF (Center: 300HZ)
BPF (Center: 600HZ)
PCM
OUTPUT
I/F
+
BPF (Center: 1.2kHZ)
HPF (Cutoff: 2.4kHZ)
3
KD16903
DATA PROCESSOR
TCLKDR
TIDR
TSHFTDR
GND3
TUPDDR
TSELDR1
TSEKDR0
VDD3
SAS
2. PIN ASSIGNMENTS
25
24
23
22
21
20
19
18
17
VDD4 26
16 SCL
TODR 27
15 SDA
GPO3 28
14 GND2
KA16903
32BCC
(Top View)
GPO2 29
DOUT 30
4
13 CKIN
12 VDD2
1
2
3
4
5
6
7
8
9
GPI1
GPI2
GPI3
GND1
RESB
FS
10 DIN
GPI0
GPO1 32
VDD1
11 MCLK
GPO0
GND4 31
DATA PROCESSOR
KD16903
3. PIN DESCRIPTION
Related Block
PIN NAME
PIN NO.
I/O
Description
RESB
8
I
Reset: Active Low with CKIN(Min 10 cycle)
SDA
15
I/O
I2C Serial Data
SCL
16
I
I2C Serial Clock
SAS
17
I
I2C Address Selection
DIN
10
I
16 Bit PCM Serial Data In
DOUT
30
O
16 Bit PCM Serial Data Out
FS
9
I
PCM Data Frame Sync.
MCLK
11
I
PCM Data Bit Clock
CKIN
13
I
System Clock (9.84MHz)
GPI0
3
I
Test Pin0 (Host INT. Indicator)
GPI1
4
I
Test Pin1(0:No Fade, 1:Fade)
GPI2
5
I
Test Pin2 (0:RAM Test)
GPI3
6
I
Test Pin3 (0:Codec Bypass)
TSELDR0
19
I
Test Pin for JTAG
TSELDR1
20
I
Test Pin for JTAG
TUPDDR
21
I
Test Pin for JTAG
TSHFTDR
23
I
Test Pin for JTAG
TIDR
24
I
Test Pin for JTAG
TCLKDR
25
I
Test Pin for JTAG
TODR
27
O
Test Pin for JTAG
GPO0
1
O
Host Ack. Pin
GPO1
32
O
Host Test Output
GPO2
29
O
Host Test Output
GPO3
28
O
Host Test Output
Power
VDD1, VDD2
VDD3, VDD4
2, 12,
18, 26
P
Digital Power (+3.0V)
Ground
GND1, GND2
GND3, GND4
7, 14,
22, 31
G
Digital GND
HIU
CIU
System
TEST
5
KD16903
DATA PROCESSOR
4. DSP PORT ASSIGNMENT FOR I/F WITH PERIPHERALS
I/F
Read/ Write
Port
Interrupt
HIU
Read
EXT1
INT1
Write
EXT1
Read
EXT0
Write
EXT0
CIU
INT0
5. HARDWARE SPECIFICATION
5.1 CODEC INTERFACE UNIT (CIU)
- Time Diagram
FS
1
2
3
4
5
6
7
DOUT
1
2
3
4
5
6
7
~
~
DIN
15
16
~
~
~
~
MCLK
15
16
Important!:
During FS (Frame Sync. Clock) high, the falling edge of MCLK (PCM Bit Clock) should exist one time.
6
DATA PROCESSOR
KD16903
5.2 HOST INTERFACE UNIT (HIU)
- I2C Bus Interface
The VIP can be controlled by a microcontroller via the 2-line I2C bus, SDA (Serial Data Line) and SCL (Serial
Clock Line). Both lines must be connected to a positive supply via pull-up resistor. Data transfer may be initiated
only when the bus is not busy. When the bus is free, both lines are high. The data on the SDA line must be stable
during the high period of clock, SCL. When the SCL is low, the SDA can change. Every byte transferred through
the SDA line must contain 8 bits including programmable slave address and read/write direction control bit. Each
byte must be followed by acknowledge bit which is sent back to the microcontroller by the VIP by pulling down the
SDA line. The MSB is transferred first.
- I2C bus interface start and stop condition
The start condition is high to low transition of the SDA line while the SCL is high. The stop condition is low to high
transition of the SDA line while SCL is high.
SDA
SCL
Data Valid
Change
of data
Allowed
SDA
SCL
S
P
Start
Condition
Stop
Condition
7
KD16903
DATA PROCESSOR
- I2C Bus Interface Acknowledge
The acknowledge related clock pulse is generated by a microcontroller.
The transmitter releases the SDA line (high) during the acknowledge clock pulse. The receiver must pull down
the SDA line during the acknowledge clock pulse so that it remains stable low during the high period of this clock
pulse. The slave-transmitter generates negative acknowledge when read operation processes. The negative
acknowledge is generated by a master (microcontroller).
I2C Bus Interface Format-Write Operation
Chip Address
MSB
Function Address
LSB
MSB
DATA
LSB
S 1 0 0 0 0 0 A0 W A
MSB
LSB
A
A P
SCL
SDA
1 0 0 0 0 0 0 0
S
P
I2C Bus Interface Format-Read Operation
Chip Address
MSB
Function Address
LSB
S 1 0 0 0 0 0 A0 R A
MSB
DATA
LSB
MSB
A
LSB
N/
A
P
SCL
SDA
1 0 0 0 0 0 0 1
S
P
- Relationship between the I2C Bus Interface signal SCL/SDA and main clock of KD16903(CKIN)
Commands are sent from MSM to KD16903 via the I2C (SDA/SCL) bus, triggered by the input signal CKIN. To
achieve immunity towards noise, the glitch protection circuitry must be put into operation, thereby meeting the
I2C specification.
Thus CKIN should be input with the SDA/SCL.
Another issue is, at least 100 clock(CKIN) cycles are needed to execute the command completely by the
KD16903. Even as the end condition of the I2C interface is met, the MSM must supply KD16903 with CKIN, as
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DATA PROCESSOR
KD16903
long as the command is being processed.
SCL
SDA
STOP Condition
CKIN
more than 100 clock cycles
RESET Mechanism
RESB should be held "LOW" for more than 10 cycles.
CKIN
RESB
more than 10 clock cycles
CKIN becomes valid at this point
Using RESB
The KD16903 consists of an DSP Unit, Host Interface, and a Codec Interface. And between these internal units,
information is exchanged via the interrupt mechanism.
None of the internally exchanged informations are available outside the KD16903.
On the handphone, signals FS, MCLK, CKIN are controlable by the MSM. However, it is also likely that the
KD16903 may fall into a state of deadlock, since none of these signals are monitorable externally.
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KD16903
DATA PROCESSOR
Furthermore trying to escape from the deadlock state by resupplying the FSK, MCLK, CKIN may not guarantee
nominal operation.
One way to escape from this deadlock state is to use the external reset mechanism. However, it is a good
practice using the internal reset mechanism, supplied at a every new CKIN set, hence avoiding this deadlock
state altogether.
To avoid deadlock, Rest must be used for following three cases.
1. Initialization to enter stable state of KD16903.
2. When changing CKIN(CHIPX8) from Hold to Running.
3. When start running Vocoder.
Please note that the corresponding commands for the functions (VIP/EQ) must be downloaded after the Reset.
- Hardware Recommendation for Reset
Separate GPIO port must be assigned for RESB.
10
DATA PROCESSOR
KD16903
6. COMMAND
6.1 SUMMARY
IC Address
Command
Data
80H
01H
-
Bypass (Default, DSP OFF)
80H
02H
-
VIP
80H
03H
-
Equalizer
80H
04H
-
Equalizer Flat
80H
05H
-
Equalizer Mode1
80H
06H
-
Equalizer Mode2
80H
07H
-
Equalizer Mode3
80H
08H
-
Equalizer Mode4
00H
VIP Level 100%
01H
VIP Level 80%
02H
VIP Level 60%
80H
09H
Bit[7:5]
Description
Bit[4:0]
000B
80H
0AH
Band1 Gain Control
001B
00000H -
Band2 Gain Control
010B
11000H
Band3 Gain Control
011B
80H
80H
80H
0BH
Band4 Gain Control
**H
Host Test Mode (Return **H).
Read after IC Read Address 0x81
Bit [7:4]
Bit [3:0]
0H
0H - CH
VIP Filter1 Gain Control
...
0H - CH
Bit [3:0] = 0H: +12dB,
Bit [3:0] = CH: 0dB,
1dB Step
9H
0H - CH
VIP Filter10 Gain Control
0CH
0DH
00H - FFH
Noise Level Selection
80H
01H
Return Current Status followed by IC Read Address
0x81, [7:4] = Unused, [3:2] = VIP Level,
[1] = Working Mode(0:VIP, 1:EQ), [0] = Bypass
Flag (0: DSP ON, 1: DSP OFF)
80H
01H
Return Band1 Tone Level Status followed by IC
Read Address 0x81 (00H: -12dB - 18H: + 12dB)
02H
Return Band2 Tone Level Status followed by IC
Read Address 0x81
80H
03H
Return Band3 Tone Level Status followed by IC
Read Address 0x81
80H
04H
Return Band4 Tone Level Status followed by IC
Read Address 0x81
80H
0EH
11
KD16903
DATA PROCESSOR
6.2 DESCRIPTION
- Bypass Mode
• Format
•
Command Code (Hex)
Command Name
01
Bypass
Description
In bypass mode, DIN (PCM input data line) is directly connected to DOUT (PCM output data line) and the DSP is
in stop mode.
- VIP Mode
• Format
•
Command Code (Hex)
Command Name
02
VIP
Description
This one byte command selects VIP mode.
- Equalizer Mode
•
•
Format
Command Code (Hex)
Command Name
03
EQ
Description
This one byte command selects Equalizer mode. Default tone levels are dipicted in
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DATA PROCESSOR
KD16903
10
0
-10
-20
-30
102
103
Figure 1: Default Tone Level (Band1: + 4dB, Band2: 0dB, Band3: 0dB, Band4: +1dB)
- VIP Level Select
• Format
Command Code (Hex)
Data (Hex)
Command Name
00
09
01
02
•
Description
100% (Max.)
VIP Level
80% (Mid.)
60% (Min.)
Description
When the current mode is the VIP, its level can be changed using incoming data byte after the command. The
default VIP level is 80%.
13
KD16903
DATA PROCESSOR
- EQ Mode Select
•
Format
Command Code (Hex)
Command Name
04
EQ Flat
05
EQ Mode1
Band1: +3dB, Band2: -1dB, Band3: -1dB, Band4: +1dB
06
EQ Mode2
Band1: +3dB, Band2: 0dB, Band3: 0dB, Band4: +3dB
07
EQ Mode3
Band1: +5dB, Band2: 0dB, Band3: 0dB, Band4: 0dB
08
EQ Mode4
Band1: +5dB, Band2: 0dB, Band3: 0dB, Band4: +1dB
•
Description
All Bands are set to 0dB
Description
Although equalizer can control all four bands, it assigns five preset tone level modes.
- EQ Tone Select
•
Format
Command Code (Hex)
Data
[7:5]
[4:0]
0A
Description
00
Band1 Select
01
Band2 Select
10
Band3 Select
11
Band4 Select
00000
+12dB
00001
+11dB
Command Name
Tone Control
…
01100
0dB
…
•
10111
-11dB
11000
-12dB
Description
The equalizer controls four different frequency bands. The gain for each frequency band can be controlled
between -12dB and +12dB. The [7:5] in data byte after the command determines the frequency band to be
controlled and [4:0] determines gain level.
14
DATA PROCESSOR
KD16903
- VIP Filter Gain Selection
•
Format
Command Code (Hex)
Data (Hex)
[7:4]
0B
[3:0]
Description
0
150Hz Filter Gain to Servo
1
300Hz Filter Gain to Servo
2
150Hz & 300 Hz Sum Gain
3
600Hz Filter Gain to Servo
4
1.2kHz Filter Gain to Summer
5
1.2kHz Filter Gain to Servo
6
2.4kHz Filter Gain to Summer
7
2.4kHz Filter Gain to Servo
8
4.8kHz Filter Gain to Summer
9
4.8kHz Filter Gain to Servo
0
+ 12dB
1
+ 11dB
Command Name
VIP Filter Gain Control
…
C
•
0dB
Description
These commands select the gains of filter outputs in the VIP mode. The detailed description of filter structure can
be found in "VIP specification" published by SRS Labs.
15
KD16903
DATA PROCESSOR
- Noise Level Selection
•
Format
Command Code (Hex)
Data (Hex)
0D
00 - FF
•
Description
Assume the value in data as noise
level
Command Name
Noise Level Select
Description
When the input from ADC has small noise, this noise can incresed in VIP or EQ mode since the specific
frequency levels are increased. To avoid this problem in mute, the input data is tested for 25ms. If the absolute
values of input data are less than noise level specified in Data and stay for 25ms, then the input is considered as
zeros and are processed. Default noise level is set to 0x1F.
- Current Status
•
Format
Command Code (Hex)
Data (Hex)
0E
01
•
Description
Command Name
Return current status register contents Current Status
Description
It returns the contents of the current status register as:
Status [7:4] = unused
Status [3:2] = VIP Level (00: 100%, 01: 80%, 10: 60%)
Status [1] = Working Mode (0: VIP, 1:EQ)
Status [0] = DSP On/Off (0: DSP On, 1: DSP Off)
- EQ Tone Level Status
•
Format
Command Code (Hex)
0E
•
Data (Hex)
Description
Command Name
02
Return current band1 tone level
03
Return current band2 tone level
Current Tone Level
04
Return current band3 tone level
Status
05
Return current band4 tone level
Description
These commands return the current tone levels in EQ mode. Returned byte value is between 0x00 (-12dB) and
0x18 (+12dB).
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DATA PROCESSOR
KD16903
7. MEMORY SIZE AND REQUIRED MIPS
7.1 MEMORY SIZE
Memory
Size (word*)
Data
Bank 0
256
Bank 1
256
VIP
800
4band EQ
500
Test
400
Others
100
Total
1860
Program
* word = 16 bit
7.2 MIPS
Routines
No. of Cycles
MIPS
Remark
VIP
650
5.2
-
4band EQ
400
3.2
Working only when VIP is OFF
Others
80
0.64
-
Total (VIP ON) = 650 + 70 + 80 = 800 (6.4 MIPS)
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KD16903
DATA PROCESSOR
8. ELECTRICAL CHARACTERISTICS
(Unless otherwise specified, Vcc = 2.7V to 3.3V, TA = -30°C to 85°C ; typical characteristic are specified at
Vcc = 3.0V, TA = 25°C; all signals are referenced to GND)
8.1 DIGITAL INTERFACES
Symbol
Parameter
VIL
Input Low Voltage
VIH
Input High Voltage
VOL
Test Condition
Min.
Typ.
Max.
0.8
Output Low Voltage
Unit
V
1.9
V
IOL = 1uA
0.05
V
IOL = 4mA (see Note1)
0.4
V
IOL = 8mA (see Note 2)
IOH = -1uA
VOH
Output High Voltage
IOH = -4mA (see Note1)
VDD-0.05
V
2.4
V
IOH = -8mA (see Note2)
IIL
IIH
IOZ
Input Low Current
Input High Current
Output Current in High
impedance (Tri-state)
VIN = Vss
-10
VIN = VSS (see Note3)
-60
VIN = VDD
-10
VIN = VDD (see Note4)
60
VOUT = VSS or VDD
-5
-30
30
10
uA
-10
uA
10
uA
10
uA
5
uA
NOTES:
1. Normal Output Pin
2. SDA ,SCL Output Pin
3. Input Buffer with pull -up (3, 4, 5, 6, 8 Pin)
4. Input Buffer with pull -down (17, 19, 20, 21, 23, 24, 25 Pin)
8.2 POWER DISSIPATION (@3.3V)
Symbol
18
Parameter
Test Condition
Min.
Typ.
Max.
Unit
ICC0
Operation Current
VIP or EQ Operation Mode
-
3
4
mA
ICC1
Bypass Current
Bypass Operation Mode
-
100
150
uA
ICC2
Static Current
No Operation (Sleep Mode)
-
10
uA
DATA PROCESSOR
KD16903
9. PACKAGE DIMENSION
9.1 32 BCC TYPE
0.40 + 0.10
0.15
0.03
C A B
C
0.50 + 0.10
4.20
0.15
0.03
C A B
C
0.50
0.50 + 0.10
0.45 + 0.10
PIN CD.2
+ 0.10
4.15
0.60 MAX
5.00 + 0.10
B
0.75
+ 0.025
INDEX
???? MARKING TYPES
4X
A
0.15
/ / 0.20 C
0.15
C
19
KD16903
DATA PROCESSOR
9.00 + 0.30
7.00 + 0.20
9.00 + 0.30
7.00 + 0.20
#32
(0.70)
#1
0.80
0.30 + 0.10
1.40 + 0.10
170 MAX
0.10 MAX
+ 0.10
0.127 - 0.05
0-8
0.05 MIN
0.10 MAX
20
0.50 + 0.20