AGERE T8502

Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Features
■
Meets or exceeds ITU-T G.711—G.714 requirements and VF characteristics of D3/D4 (as per
Bellcore PUB43801)
■
+5 V only
■
Two independent channels
■
Pin-selectable receive gain control
■
Pin-selectable µ-law or A-law companding
Description
■
Automatic powerdown mode
■
Low-power, latch-up-free CMOS technology
— 40 mW/channel typical operating power
dissipation
— 12.5 mW/channel typical standby power
dissipation
■
Automatic master clock frequency selection
— 2.048 MHz or 4.096 MHz
The T8502 and T8503 devices are single-chip, twochannel, µ-law/A-law PCM codecs with filters. These
integrated circuits provide analog-to-digital and
digital-to-analog conversion. They provide the
transmit and receive filtering necessary to interface a
voice telephone circuit to a time-division multiplexed
system. These devices are packaged in both 20-pin
SOJs and 20-pin SOGs.
■
Independent transmit and receive frame strobes
■
2.048 MHz or 4.096 MHz data rate
■
On-chip sample and hold, autozero, and precision
voltage reference
■
Differential architecture for high noise immunity
and power supply rejection
■
Operating temperature range: –40 °C to +85 °C
The T8502 differs from the T8503 in its timing mode.
The T8502 operates in the delayed timing mode
(digital data is valid one clock cycle after frame sync
goes high), and the T8503 operates in the
nondelayed timing mode (digital data valid when
frame sync goes high) (see Figures 5 and 6).
GSX0
VFXIN0
DX
DR
–
FILTER
NETWORK
+
+2.4 V
VFRO0
GSX1
VFXIN1
VFRO1
PCM
INTERFACE
ENCODER
CHANNEL 0
FILTER
NETWORK
DECODER
GAIN
CONTROL
INTERNAL TIMING
& CONTROL
FSX0
FSR0
FSX1
FSR1
GNDD
GS0
GS1
MCLK
ASEL
CHANNEL 1
BIAS
CIRCUITRY
&
REFERENCE
VDD
GNDA (2)
5-3579.b
Figure 1. Block Diagram
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Functional Description
Two channels of PCM data input and output are passed
through only two ports, DX and DR, so some type of
time-slot assignment is necessary. The scheme used
here is to utilize a fixed-data rate mode of 32 or 64 time
slots corresponding to master clock frequencies of
either 2.048 MHz or 4.096 MHz, respectively. Each
device has four frame sync (FSX and FSR) inputs, one
pair for each channel. During a single 125 µs frame,
each frame sync input is supplied a single pulse. The
timing of the respective frame sync pulse indicates the
beginning of the time slot during which the data for that
channel is clocked in or out of the device. FSX and FSR
must be high for a minimum of one master clock cycle.
They can be operated independently, or they can be
tied together for coincident transmit and receive data
transfer. During a frame, channel 0 and 1 transmit
frame sync pulses must be separated from each other
by one or more time slots. Likewise, channel 0 and 1
receive frame sync pulses must be separated from
each other by one or more time slots. Both transmit and
receive frame strobes must be derived from master
clock, but they do not need to be byte aligned.
A channel is placed in standby mode by removing both
FSX and FSR for 500 µs. Note, if any one of those
pulses (per channel) is removed, operation is indeterminate. Standby mode reduces overall device power
consumption by turning off nonessential circuitry. Critical circuits that ensure a fast, quiet powerup are kept
active. Master clock need not be active when both
channels are in standby mode.
The frequency of the master clock must be either
2.048 MHz or 4.096 MHz. Internal circuitry determines
the master clock frequency during the powerup reset
interval.
The analog input section in Figure 2 includes an onchip op amp that is used in conjunction with external,
user-supplied resistors to vary encoder passband gain.
The feedback resistance (RF) should range from 10 kΩ
to 200 kΩ, and capacitance from GSX to ground should
2
be kept to less than 50 pF. The input signal at VFXIN
should be ac coupled. For best performance, the maximum gain of this op amp should be limited to 20 dB or
less. Gain in the receive path is selectable via the GS
pins as either 0 dB or –3.5 dB.
GSX
RF
CI
RI
VFXIN
TO
CODEC
FILTERS
–
+
2.4 V
GAIN =
RF
RI
5-3786.a
Figure 2. Typical Analog Input Section
Pin Information
VFXIN0
1
20
VFXIN1
GSX0
2
19
GSX1
GNDA0
3
18
GNDA1
VFRO0
4
17
VFRO1
GS0
5
16
GS1
VDD
6
15
ASEL
FSR0
7
14
FSR1
FSX0
8
13
FSX1
MCLK
9
12
DR
GNDD
10
11
DX
T-8502
T-8503
5-3788.b
Figure 3. Pin Diagram
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Pin Information (continued)
Table 1. Pin Descriptions
Symbol
VFXIN1
VFXIN0
Pin
20
1
Type*
Name/Function
Voice Frequency Transmitter Input. Analog inverting input to the uncommitted operI
ational amplifier at the transmit filter input. Connect the signal to be digitized to this pin
through a resistor RI (see Figure 2).
O
Gain Set for Transmitter. Output of the transmit uncommitted operational amplifier.
The pin is the input to the transmit differential filters. Connect the pin to its
corresponding VFXIN through a resistor RF (see Figure 2).
O
Voice Frequency Receiver Output. This pin can drive 2000 Ω (or greater) loads.
GSX1
GSX0
19
2
VFRO1
VFRO0
VDD
17
4
6
GNDA1
GNDA0
DR
18
3
12
—
DX
11
O
MCLK
9
I
GNDD
10
—
FSX1
FSX0
13
8
Id
FSR1
FSR0
14
7
Id
GS1
GS0
ASEL
16
5
15
Iu
—
I
Id
+5 V Power Supply. This pin should be bypassed to ground with at least 0.1 µF of
capacitance as close to the device as possible.
Analog Grounds. All ground pins must be connected on the circuit board.
Receive PCM Data Input. The data on this pin is shifted into the device on the falling
edges of MCLK. Data is only entered for valid time slots as defined by the FSR inputs.
Transmit PCM Data Output. This pin remains in the high-impedance state except
during active transmit time slots. An active transmit time slot is defined as one in which
a pulse is present on one of the FSX inputs. Data is shifted out on the rising edge of
MCLK.
Master Clock Input. The frequency must be 2.048 MHz or 4.096 MHz. This clock
serves as the bit clock for all PCM data transfer.
Digital Ground. Ground connection for the digital circuitry. All ground pins must be
connected on the circuit board.
Transmit Frame Sync. This signal is an edge trigger and must be high for a minimum
of one MCLK cycle. This signal must be derived from MCLK. The division ratio is 1:256
or 1:512 (FSX:MCLK). Each FSX input must have a pulse present at the start of the
desired active output time slot. Pulses on FSX inputs must be separated by one or more
integer multiples of time slots. If the device is to be used as an A/D converter only, FSX
must be tied to FSR. An internal pull-down device is included on each FSX.
Receive Frame Sync. This signal is an edge trigger and must be high for a minimum
of one MCLK cycle. This signal must be derived from MCLK. The division ratio is 1:256
or 1:512 (FSR:MCLK). Each FSR input must have a pulse present at the start of the
desired active input time slot. Pulses on FSR inputs must be separated by one or more
integer multiples of time slots. If the device is to be used as a D/A converter only, FSR
must be tied to FSX. An internal pull-down device is included on each FSR.
Gain Selection. A high or floating state sets the receive path gain at 0 dB; a logic low
sets the gain to –3.5 dB. A pull-up device is included.
A-Law/µ-Law Select. A logic low selects µ-law coding. A logic high selects A-law
coding. A pull-down device is included.
* Id indicates a pull-down device is included on this lead. Iu indicates a pull-up device is included on this lead.
Lucent Technologies Inc.
3
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are
absolute stress ratings only. Functional operation of the device is not implied at these or any other conditions in
excess of those given in the operational sections of this data sheet. Exposure to absolute maximum ratings for
extended periods can adversely affect device reliability.
Parameter
Storage Temperature Range
Power Supply Voltage
Voltage on Any Pin with Respect to Ground
Maximum Power Dissipation (package limit)
Symbol
Tstg
VDD
—
PD
Min
–55
—
–0.5
—
Max
150
6.5
0.5 + VDD
600
Unit
°C
V
V
mW
Handling Precautions
Although protection circuitry has been designed into this device, proper precautions should be taken to avoid
exposure to electrostatic discharge (ESD) during handling and mounting. Lucent Technologies Microelectronics
Group employs a human-body model (HBM) and a charged-device model (CDM) for ESD-susceptibility testing and
protection design evaluation. ESD voltage thresholds are dependent on the circuit parameters used to define the
model. No industry-wide standard has been adopted for CDM. However, a standard HBM (resistance = 1500 Ω,
capacitance = 100 pF) is widely used and, therefore, can be used for comparison purposes. The HBM ESD
threshold presented here was obtained by using these circuit parameters:
HBM ESD Threshold Voltage
Device
Rating
T8502
>2000
T8503
>2000
Electrical Characteristics
Specifications apply for TA = –40 °C to +85 °C, VDD = 5 V ± 5%, MCLK = either 2.048 MHz or 4.096 MHz, and
GND = 0 V, unless otherwise noted.
dc Characteristics
Table 2. Digital Interface
Parameter
Input Low Voltage
Input High Voltage
Output Low Voltage
Output High Voltage
Input Current, Pins 9, 12
Input Current, Pins 7, 8, 13, 14, 15
Input Current, Pins 5, 16
Output Current in High-impedance State
Input Capacitance
4
Symbol
VIL
VIH
VOL
VOH
II
II
II
IOZ
CI
Test Conditions
All digital inputs
All digital inputs
DX, IL = 3.2 mA
DX, IL = –3.2 mA
DX, IL = –320 µA
GNDD < VIN < VDD
GNDD < VIN < VDD
GNDD < VIN < VDD
DX
—
Min
—
2.0
—
2.4
3.5
–10
2
–120
–30
—
Typ
—
—
—
—
—
—
—
—
<±2
—
Max
0.8
—
0.4
—
—
10
150
–2
30
5
Unit
V
V
V
V
V
µA
µA
µA
µA
pF
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Electrical Characteristics (continued)
dc Characteristics (continued)
Table 3. Power Dissipation
Power measurements are made at MCLK = 4.096 MHz with outputs unloaded and ASEL and GS[1:0] not
connected. Clock and frame sync levels are +5 V and 0 V.
Channels
Parameter
Operational
0
Standby Current
Symbol
Test Conditions
Min
Typ
Max
Unit
IDDS
MCLK present;
FSX[1:0] = FSR[1:0] = 0 V
MCLK present;
FS pulses present for
one channel,
FSX = FSR = 0 V for other
channel
MCLK, FS pulses present
—
5
8
mA
—
10
16
mA
—
16
23
mA
Max
—
2.4
—
—
50
—
2.5
—
100
20
Unit
MΩ
µA
—
MHz
pF
kΩ
V
Ω
pF
Ω
10000
Ω
2.25 2.38
2.5
V
2.0
2.35
2.65
V
3.2
—
—
Vp-p
1
Partial Standby Current
IDDP
2
Powerup Current
IDD1
Transmission Characteristics
Table 4. Analog Interface
Parameter
Input Resistance, VFXIN
Input Leakage Current, VFXIN
dc Open-loop Voltage Gain, GSX
Open-loop Unity Gain Bandwidth, GSX
Load Capacitance, GSX
Load Resistance, GSX
Input Voltage, VFXIN
Load Resistance, VFRO
Load Capacitance, VFRO
Output Resistance, VFRO
Output Voltage, VFRO
Output Voltage, VFRO, Standby
Output Voltage Swing, VFRO
Lucent Technologies Inc.
Symbol
RVFXI
IBVFXI
AVOL
fO
CLX1
RLX1
VIX
RLVFRO
CLVFRO
ROVFRO
VOR
VORPD
VSWR
Test Conditions
0.25 V < VFXI < 4.75 V
0.25 V < VFXI < 4.75 V
—
—
—
—
Relative to ground
—
—
0 dBm0, 1020 Hz PCM code
applied to DR
Standby mode FSX = FSR = 0 V for
channel under test
Alternating ± zero µ-law PCM
code applied to DR
Standby mode FSX = FSR = 0 V for
channel under test, no load
RL = 2000 Ω
Min Typ
1.0
60
— 0.04
5000 —
1
3
—
—
10
—
2.25 2.35
2000 —
—
—
—
—
3000
—
5
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Transmission Characteristics (continued)
ac Transmission Characteristics
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.
Table 5. Absolute Gain
Parameter
Encoder Milliwatt
Response (transmit
gain tolerance)
Decoder Milliwatt
Response (receive
gain tolerance)
Symbol
EmW
DmW
Relative Decoder Gain
Variation Referenced
to DmW
RGR
Test Conditions
Min Typ Max
Signal input of 0.775 Vrms,
0 °C to 85 °C
–0.20 — 0.20
µ-law or A-law
–40 °C to +85 °C –0.25 — 0.25
Unit
dBm0
dBm0
Measured relative to
0 °C to 85 °C
–0.20
0.775 Vrms µ-law or A-law, –40 °C to +85 °C –0.25
PCM input of 0 dBm0
1020 Hz, RL = 10 kΩ
Decoder gain at –3.5 dB
–40 °C to +85 °C –0.15
(GS = 0)
—
—
0.20
0.25
dBm0
dBm0
—
0.15
dB
Table 6. Gain Tracking
Parameter
Transmit Gain Tracking Error
Sinusoidal Input µ-Law/A-Law
Receive Gain Tracking Error
Sinusoidal Input µ-Law/A-Law
Symbol
GTX
GTR
Test Conditions
+3 dBm0 to –37 dBm0
–37 dBm0 to –50 dBm0
+3 dBm0 to –37 dBm0
–37 dBm0 to –50 dBm0
Min
–0.25
–0.50
–0.25
–0.50
Typ
—
—
—
—
Max
0.25
0.50
0.25
0.50
Unit
dB
dB
dB
dB
Test Conditions
µ-law 3 dBm0 ≤ VFXI ≤ –30 dBm0
A-law 3 dBm0 ≤ VFXI ≤ –30 dBm0
µ-law –30 dBm0 ≤ VFXI ≤ –40 dBm0
A-law –30 dBm0 ≤ VFXI ≤ –40 dBm0
µ-law –40 dBm0 ≤ VFXI ≤ –45 dBm0
A-law –40 dBm0 ≤ VFXI ≤ –45 dBm0
µ-law 3 dBm0 ≤ VFRO ≤ –30 dBm0
A-law 3 dBm0 ≤ VFRO ≤ –30 dBm0
µ-law –30 dBm0 ≤ VFRO ≤ –40 dBm0
A-law –30 dBm0 ≤ VFRO ≤ –40 dBm0
µ-law –40 dBm0 ≤ VFRO ≤ –45 dBm0
A-law –40 dBm0 ≤ VFRO ≤ –45 dBm0
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
Min
36
35
30
29
25
25
36
35
30
29
25
25
—
Typ
—
—
—
—
—
—
—
—
—
—
—
—
—
Max Unit
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
—
dB
–38 dBm0
—
—
–40
dBm0
—
—
–42
dBm0
Table 7. Distortion
Parameter
Transmit Signal to Distortion
Symbol
SDX
Receive Signal to Distortion
SDR
Single Frequency Distortion,
Transmit
SFDX
Single Frequency Distortion,
Receive
SFDR
Intermodulation Distortion
6
IMD
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Transmission Characteristics (continued)
ac Transmission Characteristics (continued)
Table 8. Envelope Delay Distortion
Parameter
TX Delay, Absolute
TX Delay, Relative to 1600 Hz
Symbol
DXA
DXR
RX Delay, Absolute
RX Delay, Relative to 1600 Hz
DRA
DRR
Round-trip Delay, Absolute
DRTA
Test Conditions
f = 1600 Hz
f = 500 Hz—600 Hz
f = 600 Hz—800 Hz
f = 800 Hz—1000 Hz
f = 1000 Hz—1600 Hz
f = 1600 Hz—2600 Hz
f = 2600 Hz—2800 Hz
f = 2800 Hz—3000 Hz
f = 1600 Hz
f = 500 Hz—1000 Hz
f = 1000 Hz—1600 Hz
f = 1600 Hz—2600 Hz
f = 2600 Hz—2800 Hz
f = 2800 Hz—3000 Hz
Any time slot/channel to
any time slot/channel
f = 1600 Hz
Min
—
—
—
—
—
—
—
—
—
–40
–30
—
—
—
—
Typ
280
—
—
—
—
—
—
—
190
—
—
—
—
—
470
Max
300
220
145
75
40
75
105
155
200
—
—
90
125
175
600
Unit
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
µs
Overload Compression
Figure 4 shows the region of operation for encoder signal levels above the reference input power (0 dBm0).
9
FUNDAMENTAL OUTPUT POWER (dBm)
8
7
6
5
ACCEPTABLE
REGION
4
3
2
1
1
2
3
4
5
6
7
8
9
FUNDAMENTAL INPUT POWER (dBm)
5-3586C
Figure 4. Overload Compression
Lucent Technologies Inc.
7
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Transmission Characteristics (continued)
ac Transmission Characteristics (continued)
Table 9. Noise
Parameter
Transmit Noise,
µ-Law
Symbol
NXC
Transmit Noise,
A-Law
Receive Noise,
µ-Law
Receive Noise,
A-Law
Noise, Single Frequency,
f = 0 kHz—100 kHz
Power Supply Rejection Transmit
Power Supply Rejection Receive
NXP
NRC
NRP
NRS
PSRX
PSRX
Spurious Out-of-band Signals at
VFRO Relative to Input
SOS
Test Conditions
—
Input amplifier gain = 20 dB
—
Min
—
—
—
Typ
—
—
—
Max
18
19
–68
Unit
dBrnC0
dBrnC0
dBm0p
PCM code is alternating positive
and negative zero
PCM code is A-law positive one
—
—
13
dBrnC0
—
—
–75
dBm0p
VFXIN = 0 Vrms, measurement at
VFRO, DR = DX
VDD = 5.0 Vdc + 100 mVrms:
f = 0 kHz—4 kHz
f = 4 kHz—50 kHz
PCM code is positive one LSB
VDD = 5.0 Vdc + 100 mVrms:
f = 0 kHz—4 kHz
f = 4 kHz—25 kHz
f = 25 kHz—50 kHz
0 dBm0, 300 Hz—3400 Hz input
PCM code applied:
4600 Hz—7600 Hz
7600 Hz—8400 Hz
8400 Hz—50 kHz
—
—
–53
dBm0
36
30
—
—
—
—
dB
dB
36
40
30
—
—
—
—
—
—
dB
dB
dB
—
—
—
—
—
—
–30
–40
–30
dB
dB
dB
Table 10. Receive Gain Relative to Gain at 1.02 kHz
Frequency (Hz)
Below 3000
3140
3380
3860
4600 and above
Min
–0.150
–0.570
–0.735
—
—
Typ
±0.04
±0.04
–0.58
–10.7
—
Max
0.150
0.150
0.010
–9.4
–28
Unit
dB
dB
dB
dB
dB
Max
–30
–26
–30
–30
0
0.150
0.150
0.010
–9.4
–32
Unit
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
Table 11. Transmit Gain Relative to Gain at 1.02 kHz
Frequency (Hz)
16.67
40
50
60
200
300 to 3000
3140
3380
3860
4600 and above
8
Min
—
—
—
—
–1.8
–0.150
–0.570
–0.735
—
—
Typ
–35
–34
–36
–50
–0.5
±0.04
±0.04
–0.58
–10.7
—
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Transmission Characteristics (continued)
ac Transmission Characteristics (continued)
Table 12. Interchannel Crosstalk (Between Channels) RF = ≤ 200 kΩ (See Note.)
Parameter
Symbol
Transmit to Receive CTXX-RY
Crosstalk 0 dBm0
Transmit Levels
Receive to Transmit CTRX-XY
Crosstalk 0 dBm0
Receive Levels
Transmit to TransCTXX-XY
mit Crosstalk
0 dBm0 Transmit
Levels
Receive to Receive CTRX-RY
Crosstalk 0 dBm0
Receive Levels
Test Conditions
f = 300 Hz—3400 Hz
idle PCM code for channel under test;
0 dBm0 into other channel VFXIN
f = 300 Hz—3400 Hz
VFXIN = 0 Vrms for channel under test;
0 dBm0 code level on other channel DR
f = 300 Hz—3400 Hz
VFXIN = 0 Vrms for channel under test;
0 dBm0 into other channel VFXIN
Min
—
Typ
–100
Max
–77
Unit
dB
—
–92
–77
dB
—
–90
–77
dB
f = 300 Hz—3400 Hz
idle PCM code for channel under test;
0 dBm0 code level on other channel DR
—
–102
–77
dB
Min
—
Typ
–80
Max
–70
Unit
dB
—
–88
–70
dB
Table 13. Intrachannel Crosstalk (Within Channels) RF = ≤ 200 kΩ (See Note.)
Parameter
Symbol
Transmit to Receive CTXX-RX
Crosstalk 0 dBm0
Transmit Levels
Receive to Transmit CTRX-XX
Crosstalk 0 dBm0
Receive Levels
Test Conditions
f = 300 Hz—3400 Hz
idle PCM code for channel under test;
0 dBm0 into VFXIN
f = 300 Hz—3400 Hz
VFXIN = 0 Vrms for channel under test;
0 dBm0 code level on DR
Note: For Tables 12 and 13, crosstalk into the transmit channels (VFXIN) can be significantly affected by parasitic
capacitive feeds from GSX and VFRO outputs. PWB layouts should be arranged to keep these parasitics
low. The resistor value of RF (from GSX to VFXIN) should also be kept as low as possible (while maintaining
the load on GSX above 10 kΩ, per Table 4) to minimize crosstalk.
Lucent Technologies Inc.
9
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Timing Characteristics
Table 14. Clock Section (See Figures 5 and 6.)
Symbol
Parameter
tMCHMCL1 Clock Pulse Width
tMCH1MCH2 Clock Rise and
tMCL2MCL1
Fall Time
Test Conditions
—
—
Min
97
0
Typ
—
—
Max
—
15
Unit
ns
ns
Table 15. T8502 Transmit Section (See Figure 5.)
Symbol
tMCHDV
tMCHDV1
tMCLDZ*
tFSHMCL
tMCLFSH
tFSLMCL
tFSHFSL
Parameter
Data Enabled on TS Entry
Data Delay from MC
Data Float on TS Exit
Frame-sync Hold Time
Frame-sync High Setup
Frame-sync Low Setup
Frame-sync Pulse Width
Test Conditions
0 < CLOAD < 100 pF
0 < CLOAD < 100 pF
CLOAD = 0
—
—
—
—
Min
0
0
10
50
50
50
0.1
Typ
—
—
—
—
—
—
—
Max
60
60
100
—
—
—
125 – tMCHMCH
Unit
ns
ns
ns
ns
ns
ns
µs
Min
0
0
0
50
50
50
0.1
Typ
—
—
—
—
—
—
—
Max
80
60
30
—
—
—
125 – tMCHMCH
Unit
ns
ns
ns
ns
ns
ns
µs
* Timing parameter tMCLDZ is referenced to a high-impedance state.
Table 16. T8503 Transmit Section (See Figure 6.)
Symbol
tFSHDV
tMCHDV1
tMCHDZ*
tFSHMCL
tMCLFSH
tFSLMCL
tFSHFSL
Parameter
Data Enabled on TS Entry
Data Delay from FSX
Data Float on TS Exit
Frame-sync Hold Time
Frame-sync High Setup
Frame-sync Low Setup
Frame-sync Pulse Width
Test Conditions
0 < CLOAD < 100 pF
0 < CLOAD < 100 pF
CLOAD = 0
—
—
—
—
* Timing parameter tMCHDZ is referenced to a high-impedance state.
Table 17. T8502 and T8503 Receive Section (See Figures 5 and 6.)
Symbol
tDVMCL
tMCLDV
10
Parameter
Receive Data Setup
Receive Data Hold
Test Conditions
—
—
Min
30
15
Typ
—
—
Max
—
—
Unit
ns
ns
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Timing Characteristics (continued)
TIME SLOT
tMCHMCL1
MCLK
1
tMCLFS H
2
3
4
5
tMCH1MCH2
tFSLMCL
tFSHMCL
6
tMCL2MCL1
7
8
1
tFSLMCL
FSXN
tFSHFSL
tMCHDV1
tMCHDV
Dx
BIT 1
BIT 2
tMCLDZ
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
FSR N
tDV MCL
BIT
1
DR
BIT
2
tMCLDV
BIT
3
BIT
4
BIT
6
BIT
5
BIT
7
BIT
8
DR
STA BLE
5-3581.I(C)
Note: FSX and FSR do not need to be coincident.
Figure 5. T8502 Transmit and Receive Timing
TIME SLOT
tMCHMCL1
MCLK
1
tMCH1MCH2
2
3
tMCLFSH
4
5
tMCL2MCL1
tFSLMCL
tFSHMCL
6
7
8
1
tFSLMCL
FSXN
tFSHFSL
tFSHDV
DX
tMCHDV1
BIT 1
BIT 2
BIT 3
tMCHDZ
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
FSRN
tDVMCL
DR
BIT
2
BIT
1
tMCLDV
BIT
3
BIT
4
BIT
5
BIT
6
BIT
7
BIT
8
DR
STABLE
5-3581.R(C)
Note: FSX and FSR do not need to be coincident.
Figure 6. T8503 Transmit and Receive Timing
Lucent Technologies Inc.
11
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Applications
RF
GSXn
ZT2
VFXINn
VTR
0.1 µF
SLIC
ZT1
0.1 µF
T8502
T8503
ZHB
ZRCV
VFROn
ACIN
RG
5-3584.d
Figure 7. Typical T8502 and T8503/SLIC Interconnection
12
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Outline Diagrams
20-Pin SOJ
Dimensions are in millimeters.
L
N
B
1
PIN #1 IDENTIFIER ZONE
W
H
SEATING PLANE
0.10
1.27 TYP
0.51 MAX
0.79 MAX
Number
of Pins
(N)
Maximum Length
(L)
Maximum Width
Without Leads
(B)
Maximum Width
Including Leads
(W)
Maximum Height
Above Board
(H)
20
12.95
7.62
8.81
3.18
5-4413 (C)r4
Lucent Technologies Inc.
13
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Outline Diagrams (continued)
20-Pin SOG
Dimensions are in millimeters.
L
N
B
1
PIN #1 IDENTIFIER ZONE
W
H
SEATING PLANE
0.10
1.27 TYP
0.51 MAX
0.61
0.28 MAX
Number
of Pins
(N)
Maximum Length
(L)
Maximum Width
Without Leads
(B)
Maximum Width
Including Leads
(W)
Maximum Height
Above Board
(H)
20
13.00
7.62
10.64
2.67
5-4414 (C)r.4
14
Lucent Technologies Inc.
Data Sheet
July 1998
T8502 and T8503 Dual PCM Codecs with Filters
Ordering Information
Device Part No.
T-8502 - - EL2-D
T-8502 - - EL2-DT
T-8502 - - GL2-D
T-8502 - - GL2-DT
T-8503 - - EL2-D
T-8503 - - EL2-DT
T-8503 - - GL2-D
T-8503 - - GL2-DT
Package
20-Pin SOJ
20-Pin SOJ Tape & Reel
20-Pin SOG
20-Pin SOG Tape & Reel
20-Pin SOJ
20-Pin SOJ Tape & Reel
20-Pin SOG
20-Pin SOG Tape & Reel
Temperature
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
–40 °C to +85 °C
Comcode
108295908
108295916
108295924
108295932
108295940
108295957
108295965
108295973
Note: All parts are shipped in dry bag.
Lucent Technologies Inc.
15
For additional information, contact your Microelectronics Group Account Manager or the following:
INTERNET:
http://www.lucent.com/micro
E-MAIL:
[email protected]
N. AMERICA: Microelectronics Group, Lucent Technologies Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18103
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA PACIFIC: Microelectronics Group, Lucent Technologies Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256
Tel. (65) 778 8833, FAX (65) 777 7495
CHINA:
Microelectronics Group, Lucent Technologies (China) Co., Ltd., A-F2, 23/F, Zao Fong Universe Building, 1800 Zhong Shan Xi Road,
Shanghai 200233 P. R. China Tel. (86) 21 6440 0468, ext. 316, FAX (86) 21 6440 0652
JAPAN:
Microelectronics Group, Lucent Technologies Japan Ltd., 7-18, Higashi-Gotanda 2-chome, Shinagawa-ku, Tokyo 141, Japan
Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700
EUROPE:
Data Requests: MICROELECTRONICS GROUP DATALINE: Tel. (44) 1189 324 299, FAX (44) 1189 328 148
Technical Inquiries: GERMANY: (49) 89 95086 0 (Munich), UNITED KINGDOM: (44) 1344 865 900 (Bracknell),
FRANCE: (33) 1 48 83 68 00 (Paris), SWEDEN: (46) 8 600 7070 (Stockholm), FINLAND: (358) 9 4354 2800 (Helsinki),
ITALY: (39) 2 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application. No
rights under any patent accompany the sale of any such product(s) or information.
Copyright © 1998 Lucent Technologies Inc.
All Rights Reserved
July 1998
DS98-342ALC (Replaces DS97-205ALC)