IDT IDT821024PP Quad non-programmable pcm codec Datasheet

QUAD NON-PROGRAMMABLE
PCM CODEC
DESCRIPTION
FEATURES
•
•
•
•
•
•
•
•
•
•
IDT821024
4 channel CODEC with on-chip digital filters
Selectable A-law or µ-law companding
Master clock frequency selection: 2.048 MHz, 4.096 MHz or
8.192 MHz
- Internal timing automatically adjusted based on MCLK and
frame sync signal
Separate PCM and master clocks
Single PCM port with up to 8.192 MHz data rate (128 time slots)
Transhybrid balance impedance hardware adjustable via external
components
Transmit gains hardware adjustable via external components
Low power +5.0 V CMOS technology
+5.0 V single power supply
Package available: 32 pin PLCC, 44 pin TQFP
The IDT821024 is a single-chip, four channel PCM CODEC with onchip filters. The device provides analog-to-digital and digital-to-analog
conversions and supports both a-law and µ−law companding. The digital
filters in IDT821024 provides the necessary transmit and receive filtering
for voice telephone circuit to interface with time-division multiplexed
systems. All of the digital filters are performed in digital signal processors
operating from an internal clock, which is derived from MCLK. The fixed
filters set the transmit and receive gain and frequency response.
In the IDT821024 the PCM data is transmitted to and received from
the PCM highway in time slots determined by the individual Frame Sync
signals (FSRn and FSXn, where n = 1-4) at rates from 256 KHz to 8.192
MHz. Both Long and Short Frame Sync modes are available in the
IDT821024.
The IDT821024 can be used in digital telecommunication applications
such as PBX, Central Office Switch, Digital Telephone and Integrated Voice/
Data Access Unit.
FUNCTIONAL BLOCK DIAGRAM
IIN1
VOUT1
IIN2
VOUT2
Anolog Front End
CH1
PCM TSA 1
PCM TSA 2
Anolog Front End
CH2
PCM TSA 3
DSP
VOUT4
MCLK
IREF
FSX2
FSR2
FSX3
FSR3
FSX4
FSR4
DX
PCM Interface
Anolog Front End
CH4
TSC
DR
PCLK
Clock
&
Reference Circuits
PDN 1~ 4
Control
VCCA
CNF
FSR1
A/µ
DGND
IIN4
PCM TSA 4
VCCD
VOUT3
Anolog Front End
CH3
AGND
IIN3
FSX1
The IDT logo is a registered trademark of Integrated Device Technology, Inc
INDUSTRIAL TEMPERATURE RANGE
APRIL 3, 2003
1
2003 Integrated Device Technology, Inc.
DSC-6034/4
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
VOUT1
CNF
PDN1
PDN2
PDN3
PDN4
MCLK
4
3
2
1
32
31
30
PIN CONFIGURATIONS
5
29
PCLK
IIN2
6
28
TSC
VOUT2
7
27
DGND
VCCA
8
26
DX
IREF
9
25
VCCD
AGND
10
24
DR
VOUT3
11
23
FSR1
IIN3
12
22
FSX1
IIN4
13
21
FSR2
FSR3
FSX2
PDN3
PDN4
MCLK
PCLK
37
36
35
34
19
FSX3
PDN2
38
18
FSR4
PDN1
39
17
FSX4
NC
40
16
15
41
A/µ
NC
42
CNF
VOUT1
43
14
IIN1
44
VOUT4
32-Pin
PLCC
20
IIN1
IIN2
1
33
NC
VOUT2
2
32
NC
NC
3
31
TSC
NC
4
30
DGND
VCCA
5
29
NC
IREF
6
28
DX
AGND
7
27
VCCD
NC
8
26
DR
NC
9
25
FSR1
VOUT3
10
24
FSX1
IIN3
11
23
FSR2
12
13
14
15
16
17
18
19
20
21
22
IIN4
VOUT4
NC
NC
A/µ
NC
FSX4
FSR4
FSX3
FSR3
FSX2
44-Pin
TQFP
2
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
PIN DESCRIPTION
Pin Number
PLCC
TQFP
Name
I/O
AGND
--
10
7
Analog Ground.
All ground pins should be connected to the ground plane of the circuit board.
VCCA
--
8
5
+5 V Analog Power Supply.
All power supply pins should be connected to the power plane of the circuit board.
DGND
--
27
30
Digital Ground.
All ground pins should be connected to the ground plane of the circuit board.
VCCD
--
25
27
+5 V Digital Power Supply.
All power supply pins should be connected to the power plane of the circuit board.
DR
I
24
26
Receive PCM Data Input.
The PCM data for Channel 1, 2, 3 and 4 is shifted serially into DR pin by the Receive Frame Sync Signal
(FSR) with MSB first. A byte of data for each channel is received every 125 µs at the PCLK rate.
DX
FSR1
FSR2
FSR3
FSR4
FSX1
FSX2
FSX3
FSX4
IREF
VOUT1
VOUT2
VOUT3
VOUT4
IIN1
IIN2
IIN3
IIN4
MCLK
Description
O
26
28
Transmit PCM Data Output.
The PCM data for Channel 1, 2, 3 and 4 is shifted serially out to the DX pin by the Transmit Frame Sync Signal
(FSX) with MSB first. A byte of data for each channel is transmitted every 125 µs at the PCLK rate. DX is high
impedance between time slots.
I
23
21
19
17
25
23
21
19
Receive Frame Sync Input for Channel 1/2/3/4
This 8kHz signal pulse identifies the receive time slot for Channel N on a system’s receive PCM frame. It must
be synchronized to PCLK.
I
22
20
18
16
24
22
20
18
Transmit Frame Sync Input for Channel 1/2/3/4
This 8 kHz signal pulse identifies the transmit time slot for Channel N on a system’s transmit PCM frame. It
must be synchronized to PCLK.
O
9
6
Reference Current.
The IREF output is biased at the internal reference voltage. A resistor placed from IREF to ground sets the
reference current used by the analog-to-digital converter to encode the signal current present on IINn pin (n is
channel number, n = 1 to 4) into digital form.
O
4
7
11
14
43
2
10
13
Voice Frequency Receiver Output for Channel 1/2/3/4
This is the output of receiver amplifier for Channel N. The received digital data from DR is processed and
converted to an analog signal at this pin.
I
5
6
12
13
44
1
11
12
Voice Frequency Transmitter Input for Channel 1/2/3/4
This is the input to the gain setting amplifier in the transmit path for Channel N. The analog voice band voltage
signal is applied to this pin through a resistor. This input is a virtual AC ground input, which is biased at the
IREF pin.
35
Master Clock.
The Master Clock provides the clock for the DSP. It can be either 2.048 MHz or 4.096 MHz. The IDT821024
determines the MCLK frequency via the FSX inputs and makes the necessary internal adjustments
automatically. The MCLK frequency must be an integer multiple of the FSX frequency.
I
30
PCLK
I
29
34
PCM Clock.
The PCM Clock shifts out the PCM data to the DX pin and shifts in PCM data from the DR pin. The PCM clock
frequency is an integer multiple of the frame sync frequency. When PCLK is connected to MCLK, the PCM
clock can generate the DSP clock as well.
TSC
O
28
31
Time Slot Control.
This open drain output is low active. When the PCM data is transmitted to the DX pin for any of the four
channels, this pin will be pulled low.
A/µ
I
15
16
A/µ -Law Selection.
When this pin is low, µ-Law is selected; when this pin is high, A-Law is selected. This pin can be connected to
VCCD or DGND pin directly.
3
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
PIN DESCRIPTION (cont’d)
Name
PDN1
PDN2
PDN3
PDN4
CNF
NC
I/O
Pin Number
PLCC
TQFP
Description
I
2
1
32
31
39
38
37
36
Channel 1/2/3/4 Power Down.
When this pin is high, Channel N is powered down.
O
3
41
Capacitor For Noise Filter.
This pin should be connected to AGND through a 0.1 µF capacitor.
--
3, 4, 8, 9,
14, 15, 17,
29, 32, 33,
40, 42
No connection
4
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
FUNCTIONAL DESCRIPTION
and compressed to PCM format.
The IDT821024 contains four channel PCM CODEC with on chip digital
filters. It provides the four-wire solution for the subscriber line circuitry in
digital switches. The device converts analog voice signal to digital PCM
data, and converts digital PCM data back to analog signal. Digital filters
are used to bandlimit the voice signals during the conversion. Either A-law
or µ-law is supported by the IDT821024. The law selection is performed
by A/µ pin.
The frequency of the master clock (MCLK) can be 2.048 MHz, 4.096
MHz, or 8.192 MHz. Internal circuitry determines the master clock frequency
automatically.
The serial PCM data for four channels are time multiplexed via two pins,
DX and DR. The time slots of the four channels are determined by the
individual Frame Sync signals at rates from 256 kHz to 8.192 MHz. For
each channel, the IDT821024 provides a transmit Frame Sync signal and
a receive Frame Sync signal.
Each channel of the IDT821024 can be powered down independently
to save power consumption. The Channel Power Down Pins PDN1-4
configure channels to be active (power-on) or standby (power-down)
separately.
Transmit PCM Interface
The transmit PCM interface clocks out 1 byte (8 bits) PCM data out of
DX pin every 125 µs. The transmit logic, synchronized by the Transmit
Frame Sync signal (FSXn), controls the data transmission. The FSXn
pulse identifies the transmit time slot of the PCM frame for Channel N.
The PCM Data is transmitted serially on DX pin with the Most Significant
Bit (MSB) first. When the PCM data is being output on DX pin, the TSC
signal will be pulled low.
Receive Signal Processing
In the receive path, the PCM code is received at the rate of 8,000 samples
per second. The PCM code is expanded and sent to the DSP for
interpolation. A receive filter is implemented in the DSP as a digital lowpass
filter. The filtered signal is then sent to an oversampling DAC. The DAC
output is post-filtered and delivered at VOUT pin by an amplifier. The
amplifier can drive resistive load higher than 2 KΩ.
Receive PCM Interface
The receive PCM interface clocks 1 byte (8 bits) PCM data into DR pin
every 125 µs. The receive logic, synchronized by the Receive Frame Sync
signal (FSRn), controls the data receiving process. The FSRn pulse
identifies the receive time slot of the PCM frame for Channel N. The PCM
Data is received serially on DR pin with the Most Significant Bit (MSB)
first.
Signal Processing
High performance oversampling Analog-to-Digital Converters (ADC) and
Digital-to-Analog Converters (DAC) are used in the IDT821024 to provide
the required conversion accuracy. The associated decimation and interpolation filtering are realized with both dedicated hardware and Digital Signal
Processor (DSP). The DSP also handles all other necessary functions such
as PCM bandpass filtering and sample rate conversion.
Hardware Gain Setting In Transmit Path
The transmit gain of the IDT821024 for each channel can be set by 2
resistors, RREF and RTXn (as shown in Figure 1), according to the following equation:
Transmit Signal Processing
In the transmit path, the analog input signal is received by the ADC and
converted into digital data. The digital output of the oversampling ADC is
decimated and sent to the DSP. The transmit filter is implemented in the
DSP as a digital bandpass filter. The filtered signal is further decimated
to
SLIC
VTX
Gt =
The receive gain of IDT821024 is fixed and equal to 1.
IDT821024
CTX1
RTX1
A/D
I REF
VIN1
V REF
to
IREF
Bal
Net
to
SLIC
RSN
3 × R REF
R TXn
RRX 1
IREF1
VREF1
CRX1
VOUT1
RREF1
CFIL
VREF
D/A
Figure 1. IDT821024 Transmit Gain Setting for Channel 1
5
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
OPERATING THE IDT821024
The following descriptions about operation applies to all four channels of
the IDT821024.
Power-on Sequence and Master Clock Configuration
To power on the IDT821024 users should follow this sequence:
1. Apply ground;
2. Apply VCC, finish signal connections;
3. Set PDN1-4 pins high, thus all of the 4 channels are powered down;
The master clock (MCLK) frequency of IDT821024 can be configured as
2.048 MHz, 4.096 MHz or 8.192 MHz. Using the Transmit Frame Sync
(FSX) inputs, the device determines the MCLK frequency and makes the
necessary internal adjustments automatically. The MCLK frequency must
be an integer multiple of the Frame Sync frequency.
Operating Modes
There are two operating modes for each transmit or receive channel:
standby mode (when the channel is powered down) and normal mode (when
the channel is powered on). The mode selection of each channel is done
by its corresponding PDN pin. When PDNn is 1, Channel N is in standby
mode; when PDNn is 0, Channel N is in normal mode.
In standby mode, all circuits are powered down with the analog outputs
placed in high impedance state.
In normal mode, each channel of the IDT821024 is able to transmit and
receive both PCM and analog information. The normal mode is used when
a telephone call is in progress.
Companding Law Selection
An A/µ pin is provided by IDT821024 for the companding law selection.
When this pin is low, µ-law is selected; when the pin is high, A-law is
selected.
6
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
ABSOLUTE MAXIMUM RATINGS
Rating
Power Supply Voltage
Voltage on Any Pin with Respect to
Ground
Package Power Dissipation
Storage Temperature
Com’I & Ind’I
≤ 6.5
-0.5 to 5.5
Unit
V
V
≤ 600
-65 to +150
mW
°C
RECOMMENDED DC OPERATING
CONDITIONS
Parameter
Operating Temperature
Power Supply Voltage
Min.
-40
4.75
Typ.
Max.
+85
5.25
Unit
°C
V
NOTE: MCLK: 2.048 MHz, 4.096 MHz or 8.192 MHz with tolerance of ± 50 ppm
NOTE: Stresses greater than those listed under ABSOLUTE MAXIMUM RATINGS may cause
permanent damage to the device. This is a stress rating only and functional operation of the
device at these or any other conditions above those indicated in the operational sections of
this specification is not implied. Exposure to absolute maximum rating conditions for extended
periods may affect reliability.
ELECTRICAL CHARACTERISTICS
Digital Interface
Parameter
V IL
VIH
V OL
Description
Input Low Voltage
Input High Voltage
Output Low Voltage
Min
Typ
Max
0.8
VDD-0.6
V
V
Test Conditions
All digital inputs
All digital inputs
DX, TSC,IL = 14mA
All other digital outputs,
IL = 4mA.
All digital pins, IL = 14mA
DX, IH = -7 mA, all other outputs, IH = -4 mA
VDD-0.2
V
All digital pins, IH = -1mA
2.0
0.4
0.8
Units
V
V
V
V
0.2
VOH
II
IOZ
CI
Output High Voltage
Input Current
Output Current in High-impedance State
Input Capacitance
-10
-10
10
10
5
µA
µA
pF
Any digital inputs GND<VIN<VDD
DX
Note: Total current must not exceed absolute maximum ratings.
Power Dissipation
Parameter
PD2
PD1
PD0
Description
Operating Power Dissipation 1
Operating Power Dissipation 1
Standby Power Dissipation
Min
Typ
180
60
4
Max
240
90
10
Units
mW
mW
mW
Test Conditions
All channels are active
Only one channel is active
All channels are powered down,with only MCLK present
Note: Power measurements are made at MCLK = 4.096 MHz, outputs unloaded
Analog Interface
Parameter
VOUT1
VOUT2
RO
RL
I IR
I IOS
IOUT
IZ
CL
Description
Output Voltage
Output Voltage Swing
Output Resistance
Load Resistance
Analog Input Current Range
Offset Current Allowed on IIN
VOUT Output Current (F< 3400Hz)
Output Leakage Current
Load Capacitance
Min
2.25
3.25
Typ
2.4
Max
2.6
1
4
2000
± 40
-1.6
-5
-10
+1.6
5
10
100
7
Units
V
V P-P
Ω
Ω
µA
µA
mA
µA
pF
Test Conditions
Alternating ±zero µ -law PCM code applied to DR.
RL=2000 Ω
0dBm0, 1020Hz PCM code applied to DR
External loading
RREF = 13kΩ
Power down
External loading
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
TRANSMISSION CHARACTERISTICS
0dBm0 is defined as 0.6832Vrms for A-law and 0.6778 Vrms for µ-law, both for 600 Ω load. Unless otherwise noted, the analog input is a 0
dBm0, 1020 Hz sine wave; the input amplifier is set for unity gain. The digital input is a PCM bit stream equivalent to that obtained by passing a 0
dBm0, 1020 Hz sine wave through an ideal encoder. The output level is sin(x)/x-corrected. Typical value are tested at VDD = 5V and TA = 25°C.
Absolute Gain
Parameter
GXA
GRA
Description
Transmit Gain, Absolute
0°C to 85°C
-40°C
Receive Gain, Absolute
0°C to 85°C
-40°C
Min
Typ
Max
Units
-0.25
-0.35
0.25
0.35
dB
dB
-0.25
-0.35
0.25
0.35
dB
dB
Test Conditions
Signal input of 0 dBm0, µ-law or A-law
Measured relative to 0 dBm0, µ-law or A-law, PCM input of 0
dBm0 1020 Hz , R L = 10 kΩ
Gain Tracking
Parameter
GT X
GT R
Description
Transmit Gain Tracking
+3 dBm0 to –40 dBm0
-40 dBm0 to -50 dBm0
-50 dBm0 to -55 dBm0
Receive Gain Tracking
+3 dBm0 to –40 dBm0
-40 dBm0 to -50 dBm0
-50 dBm0 to -55 dBm0
Min
Typ
Max
Units
-0.10
-0.25
-0.50
0.10
0.50
0.50
dB
dB
dB
-0.10
-0.25
-0.50
0.10
0.50
0.50
dB
dB
dB
Max
Units
-40
-40
0.15
-0.1
-35
dB
dB
dB
dB
dB
0
0.15
-0.2
-35
dB
dB
dB
dB
Max
340
Units
µs
280
150
80
280
260
µs
µs
µs
µs
µs
50
80
120
150
µs
µs
µs
µs
Test Conditions
Tested by Sinusoidal Method, µ-law/A-law
Tested by Sinusoidal Method, µ-law/A-law
Frequency Response
Parameter
GXR
GRR
Description
Transmit Gain, Relative to GXA
f = 50 Hz
f = 60 Hz
f = 300 Hz to 3400 Hz
f = 3600 Hz
f = 4600 Hz and above
Receive Gain, Relative to GRA
f below 300 Hz
f = 300 Hz to 3400 Hz
f = 3600 Hz
f = 4600 Hz and above
Min
Typ
-0.15
-0.15
Test Conditions
Group Delay
Parameter
D XA
D XR
D RA
D RR
Description
Transmit Delay, Absolute *
Transmit Delay, Relative to 1800 Hz
f = 500 Hz – 600 Hz
f = 600 Hz –1000 Hz
f = 1000 Hz – 2600 Hz
f = 2600 Hz – 2800 Hz
Min
Typ
Receive Delay, Absolute *
Receive Delay, Relative to 1800 Hz
f = 500 Hz – 600 Hz
f = 600 Hz –1000 Hz
f = 1000 Hz – 2600 Hz
f = 2600 Hz – 2800 Hz
Note*: Minimum value in transmit and receive path.
8
Test Conditions
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
Distortion
Parameter
STD X
SFD X
Description
Transmit Signal to Total Distortion Ratio
A-law :
Input level = 0 dBm0
Input level = -30 dBm0
Input level = -40 dBm0
Input level = -45 dBm0
µ-law :
Input level = 0 dBm0
Input level = -30 dBm0
Input level = -40 dBm0
Input level = -45 dBm0
Receive Signal to Total Distortion Ratio
A-law :
Input level = 0 dBm0
Input level = -30 dBm0
Input level = -40 dBm0
Input level = -45 dBm0
µ-law :
Input level = 0 dBm0
Input level = -30 dBm0
Input level = -40 dBm0
Input level = -45 dBm0
Single Frequency Distortion, Transmit
SFDR
Single Frequency Distortion, Receive
-42
dBm0
IMD
Intermodulation Distortion
-42
dBm0
Max
16
-68
12
-78
-53
Units
dBrnC0
dBm0p
dBrnC0
dBm0p
dBm0
STDR
Min
Typ
Max
Units
36
36
30
24
dB
dB
dB
dB
36
36
31
27
dB
dB
dB
dB
Test Conditions
ITU-T O.132
Sine Wave Method,Psophometric Weighted for Alaw, C Message Weighted for µ-law.
ITU-T O.132
36
36
30
24
dB
dB
dB
dB
36
36
31
27
-42
dB
dB
dB
dB
dBm0
Sine Wave Method,Psophometric Weighted for Alaw;Sine Wave Method,C Message Weighted for µlaw;
200 Hz - 3400 Hz, 0 dBm0 input, output any other
single frequency ≤ 3400 Hz
200 Hz - 3400 Hz, 0 dBm0 input, output any other
single frequency ≤ 3400 Hz
Transmit or receive,two frequencies in the range
(300 Hz− 3400 Hz) at −6 dBm0
Noise
Parameter
NXC
NXP
NRC
NRP
NRS
PSRX
PSRR
SOS
Description
Transmit Noise, C Message Weighted for µ-law
Transmit Noise, Psophometric Weighted for A-law
Receive Noise, C Message Weighted for µ-law
Receive Noise, Psophometric Weighted for A-law
Noise, Single Frequency
f = 0 kHz – 100 kHz
Power Supply Rejection Transmit
f = 300 Hz – 3.4 kHz
f = 3.4 kHz – 20 kHz
Power Supply Rejection Receive
f = 300 Hz – 3.4 kHz
f = 3.4 kHz – 20 kHz
Spurious Out-of-Band Signals at VOUT Relative to
Input PCM code applied:
4600 Hz – 20 kHz
20 kHz – 50 kHz
Min
Typ
Test Conditions
IIN = 0 A, tested at VOUT
VDD = 5.0 VDC + 100 mVrms
40
25
dB
dB
40
25
dB
dB
PCM code is positive one LSB, VDD = 5.0 VDC +
100 mVrms
0 dBm0, 300 Hz – 3400 Hz input
-40
-30
9
dB
dB
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
Interchannel Crosstalk
Parameter
Description
Min
Typ
Max
Units
XT X-R
Transmit to Receive Crosstalk
-85
-78
dB
XT R-X
Receive to Transmit Crosstalk
-85
-80
dB
XTX-X
Transmit to Transmit Crosstalk
-85
-78
dB
XT R-R
Receive to Receive Crosstalk
-85
-80
dB
Test Conditions
300 Hz – 3400 Hz, 0 dBm0 signal into IIN of interfering channel.
Idle PCM code into channel under test.
300 Hz – 3400 Hz, 0 dBm0 PCM code into interfering channel. IIN
= 0 A for channel under test.
300 Hz – 3400 Hz, 0 dBm0 signal into IIN of interfering channel.
IIN = 0 A for channel under test.
300 Hz – 3400 Hz, 0 dBm0 PCM code into interfering channel. Idle
PCM code into channel under test.
Intrachannel Crosstalk
Parameter
XT X-R
XT R-X
Description
Transmit to Receive Crosstalk
Receive to Transmit Crosstalk
Min
Typ
-80
-80
Max
-70
-70
Units
dB
dB
10
Test Conditions
300 Hz – 3400 Hz, 0 dBm0 signal into IIN. Idle PCM code into DR.
300 Hz – 3400 Hz, 0 dBm0 PCM code into DR. IIN = 0 A.
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
TIMING CHARACTERISTICS
Clock
Parameter
t1
t2
t3
Description
PCLK Duty Cycle
PCLK Rise and Fall Time
MCLK Duty Cycle
Min
40
t4
MCLK Rise and Fall Time
t5
PCLK Clock Period
244
Description
Data Output Delay Time (for Short
Frame Sync Mode)
Data Hold Time
Data Delay to High-Z
Min
5
Frame sync Hold Time
Frame sync High Setup Time
TSC Enable Delay Time(for Short
Frame Sync Mode)
TSC Disable Delay Time
50
55
5
Data Output Delay Time(for Long
Frame Sync Mode)
TSC Enable Delay Time(for Long
Frame Sync Mode)
Receive Data Setup Time
Receive Data Hold Time
Typ
40
Max
60
25
60
Units
%
ns
%
15
ns
ns
Test Conditions
PCLK=512kHz to 8.192MHz
PCLK=512kHz to 8.192MHz
MCLK=2.048Hz,4.096MHz
or 8.192MHz
MCLK=2.048Hz,4.096MHz
or 8.192MHz
PCLK=512kHz to 8.192MHz
Transmit
Parameter
t11
t12
t13
t14
t15
t16
t17
t18
t19
t21
t22
5
50
50
Typ
Max
70
Units
ns
70
220
t5+70
ns
ns
t5-50
80
ns
ns
ns
ns
5
220
t5+70
40
5
40
ns
25
5
ns
ns
ns
Note: Timing parameter t13 is referenced to a high-impedance state.
MCLK
t4
t4
Figure 2. MCLK Timing
11
Test Conditions
IDT821024 QUAD NON-PROGRAMMABLE PCM CODEC
INDUSTRIAL TEMPERATURE RANGE
Time Slot
1
PCLK
t15
2
t14
3
4
5
t2
6
t2
7
8
t5
FSX/
FSR
DX
BIT 1
BIT 3
BIT 2
BIT 1
BIT 4
BIT 5
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
BIT 7
BIT 8
t22
t21
DR
t13
t12
t11
BIT 2
BIT 3
BIT 6
t17
t16
TSC
Figure 3. PCM Interface Timing for Short Frame Mode
Time Slot
PCLK
1
2
3
4
t5
t15
5
6
7
1
8
t2
t2
FSX/
FSR
DX
BIT 1
BIT 2
t21
DR
BIT 1
t13
t12
t18
BIT 2
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
t22
BIT 3
t17
t19
TSC
Figure 4. PCM Interface Timing for Long Frame Mode
12
ORDERING INFORMATION
IDT
XXXXXX
XX
X
Device Type
Package
Process/
Temperature
Range
Blank
Industrial (-40 °C to +85 °C)
J
Plastic Leaded Chip Carrier (PLCC, PL32)
PP
Thin Quad Flat Pack (TQFP, PP44)
821024
Quad Non-Programmable PCM CODEC
Data Sheet Document History
01/16/2002
02/21/2002
09/10/2002
01/08/2003
04/03/2003
pgs. 4, 5
pgs. 1-4, 13
pg. 8
pgs. 1, 13
pg. 1
CORPORATE HEADQUARTERS
2975 Stender Way
Santa Clara, CA 95054
for SALES:
800-345-7015 or 408-727-6116
fax: 408-492-8674
www.idt.com*
for Tech Support:
408-330-1552
email: [email protected]
*To search for sales office near you, please click the sales button found on our home page or dial the 800# above and press 2.
The IDT logo is a registered trademark of Integrated Device Technology, Inc.
13