ETC AM79C031

Am79213/Am79C203/031
Advanced Subscriber Line Interface Circuit (ASLIC™) Device
Advanced Subscriber Line Audio-Processing Circuit
(ASLAC™) Device
DISTINCTIVE CHARACTERISTICS
Performs all of the functions of a codec-filter
Single channel architecture
Performs Battery-feed, Ring-trip, Signaling,
Coding, Hybrid and Test (BORSCHT) functions
Single hardware design meets multiple country
requirements through software programming
Standard microprocessor interface
Industry standard PCM interface with full-time
slot assignment
Monitor of two-wire interface voltage and current
for subscriber line diagnostics
Low idle power per line
On-hook transmission
Only battery and +5 V supplies needed
Exceeds LSSGR and CCITT central office
requirements
Off-hook and ground-key detectors with
programmable thresholds
Programmable line feed characteristics
independent of battery voltage
Built-in voice path test modes
Analog and digital hybrid balance capability
— Digital I/O pins
— A-law/µ-law selection
Linear data available on PCM ports for custom
compression and expansion
Compatible with inexpensive protection
networks. Accommodates low tolerance fuse
resistors while maintaining longitudinal balance
to Bellcore specifications.
Power/Service Denial state
Small physical size
Integrated ring trip function
Four relay drivers with built-in energy
absorption zener diodes
Synchronized ring relay operation: zero volts ac
on, zero current off
Software enabled Normal or Automatic Ring-Trip
state
On-chip 12 kHz and 16 kHz metering generation
with on and off meter pulse shaping
Supports loop-start and ground-start signaling
0°C to +70°C commercial operation guaranteed
by production testing
–40°C to +85°C temperature range operation
available
Adaptive hybrid balance capability
Linear power feed with power management and
thermal shutdown features
Abrupt and smooth polarity reversal
Power-cross detection in Ringing and Nonringing states
Software programmable
—
—
—
—
—
—
—
DC loop feed characteristics and current limit
Loop supervision detection thresholds
Off-hook detect debounce interval
Two-wire AC impedance
Transhybrid balance
Transmit and receive gains
Equalization
Publication# 080160 Rev: D Amendment: /0
Issue Date: April 2000
TABLE OF CONTENTS
Distinctive Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Linecard Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Ordering Information. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
ASLIC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
ASLAC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Connection Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
32-Pin PLCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
44-Pin PLCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Pin Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
ASLIC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
ASLAC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
ASLIC/ASLAC Devices Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Electrical Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Absolute Maximum Electrical and Thermal Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
ASLIC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
ASLAC Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Operating ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Environmental . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Performance Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
ASLIC Device Relay Driver Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Switching Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Microprocessor Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Switching Waveforms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Input and Output Waveforms for AC Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Master Clock Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Microprocessor Interface (Input Mode) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Microprocessor Interface (Output Mode) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
PCM Highway Timing for XE = 0 (Transmit on Negative PCLK Edge) . . . . . . . . . . . . . . . . . 36
PCM Highway Timing for XE = 1 (Transmit on Positive PCLK Edge) . . . . . . . . . . . . . . . . . 37
ASLIC/ASLAC Devices Linecard Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Programmable Filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
General Description of CSD Coefficients . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
Physical Dimension . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
PL032 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
PL044 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Revision Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
2
Am79213/Am79C203/031 Data Sheet
LIST OF FIGURES
Figure 1.
Figure 2.
Figure 3.
Figure 4.
Figure 5.
Figure 6.
Figure 7.
Transmit and Receive Path Attenuation vs. Frequency . . . . . . . . . . . . . . . . . . . 26
Group Delay Distortion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
A-law Gain Linearity with Tone Input (Both Paths) . . . . . . . . . . . . . . . . . . . . . . . 28
µ-law Gain Linearity with Tone Input (Both Paths) . . . . . . . . . . . . . . . . . . . . . . . 28
Total Distortion with Tone Input (Both Paths) . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
A/A Overload Compression. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
ASLIC/ASLAC Typical Linecard Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
LIST OF TABLES
Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 8.
Table 9.
Table 10.
Table 11.
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
ASLIC Device DC Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
ASLIC Device Relay Driver Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
ASLIC Device Transmission Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
ASLAC Device DC Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
ASLAC Device Transmission and Signaling Specifications . . . . . . . . . . . . . . . . 22
Microprocessor Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
PCM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Master Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
User-Programmable Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
ASLIC/ASLAC Devices Linecard Parts List . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
ASLIC/ASLAC Products
3
The Am79213/Am79C203/031 Advanced Subscriber
Line Interface chip set implements a universal telephone
line interface function. This enables the design of a single,
low cost, high performance, fully software programmable
line interface card for multiple country applications world
wide. All AC, DC, and signaling parameters are fully
programmable via the microprocessor interface.
Additionally, the ASLIC device and ASLAC device have
integrated self test and line test capabilities to resolve
faults to the line or line circuit. The integrated test
capability is crucial for remote applications where
dedicated test hardware is not cost effective. The
Technical Reference, PID 21325A is recommended to be
used with this document.
LINECARD BLOCK DIAGRAM
Loop Voltage
Sense Resistors
Transmit
Receive
RFA
AD
Ring
and
Test
Relays
SA
ASLIC
Device
SB
B(Ring)
DC Feed Control
Metering
Loop Voltage Monitor
Loop Current Monitor
BD
ASLAC
Device
MPI
RFB
PCM
Relay Driver Outputs
Ring-Feed
Resistor
ASLIC Device Operating State
Relay Driver Inputs
Ringer
Supply
Ringing-Current
Sense Resistors
4
Am79213/Am79C203/031 Data Sheet
MPI and PCM Backplane
A(Tip)
ORDERING INFORMATION
ASLIC Device
Must order Am79C203 or Am79C2031 with the device below.
Am79213
J
C
TEMPERATURE RANGE
C = Commercial (0°C to 70°C)*
PACKAGE TYPE
J = 32-pin Plastic Leaded Chip Carrier (PL 032)
DEVICE NUMBER/DESCRIPTION
Am79213
Advanced Subscriber Line Interface Circuit
Valid Combinations
Am79213
JC
Valid Combinations
Valid Combinations list configurations planned to
be supported in volume for this device. Consult
the local Legerity sales office to confirm availability of specific valid combinations and to check on
newly released combinations.
Note:
* Functionality of the device from 0°C to +70°C is guaranteed by production testing. Performance from –40°C to +85°C
is guaranteed by characterization and periodic sampling of production units.
ASLIC/ASLAC Products
5
ORDERING INFORMATION (continued)
ASLAC Device
Must order Am79213 with the device below.
Am79C203/031
J
C
TEMPERATURE RANGE
C = Commercial (0°C to 70°C)*
PACKAGE TYPE
J = 32-pin Plastic Leaded Chip Carrier (PL032)
Am79C203 only
J = 44-pin Plastic Leaded Chip Carrier (PL044)
Am79C2031 only
DEVICE NUMBER/DESCRIPTION
Am79C203/031
Advanced Subscriber Line Audio-processing Circuit
Valid Combinations
Am79C203
Am79C2031
JC
Valid Combinations
Valid Combinations list configurations planned to
be supported in volume for this device. Consult
the local Legerity sales office to confirm availability of specific valid combinations and to check on
newly released combinations.
Note:
* Functionality of the device from 0°C to +70°C is guaranteed by production testing. Performance from –40°C to +85°C
is guaranteed by characterization and periodic sampling of production units.
6
Am79213/Am79C203/031 Data Sheet
RY1OUT
VCC
VBAT
BGND
BD
AD
SB
CONNECTION DIAGRAMS
Top View
32-Pin PLCC
4
3
2
1
32 31
30
RY2OUT
5
29
SA
RY3OUT
6
28
HPB
RINGOUT
7
27
HPA
TMG
8
26
RSVD
QBAT
9
25
BAL1
Am79213
C5
10
24
NC
C4
11
23
VREF
C3
12
22
VTX
C2
13
21
IDC
RSN
20
GND
IDIF
VLBIAS
Notes:
1. RSVD = Reserved. Do not connect to this pin.
ISUM
16 17 18 19
VDC
C1
14 15
DGND
PCLK
DRA
3
2
1
32 31 30
IBAT
TCSA
4
MCLK
DXA
2. NC = No Connect
FS
5
29
IAB
I/O1
6
28
IREF
I/O2
7
27
VLBIAS
DCLK
8
26
VCCA
DI/O
9
25
IDIF
Am79C203
VCCD
10
24
ISUM
CS
11
23
IRTA
C2
12
22
IRTB
C1
13
21
IDC
RST
VIN
AGND
17 18 19 20
VREF
VOUT
VM
INT
14 15 16
ASLIC/ASLAC Products
7
CONNECTION DIAGRAMS (continued)
2
RSVD
DGND
PCLK
3
MCLK
TSCA
4
TCSB
DXB
5
DRB
DXA
6
DRA
RSVD
Top View
44-Pin PLCC
1 44 43 42 41 40
8
39
38
IBAT
IAB
I/O2
9
37
IREF
I/O3
10
36
VLBIAS
DCLK
11
35
DI/O
12
34
VCCA
IDIF
VCCD
13
33
ISUM
I/O4
14
32
IRTA
CS
15
31
IRTB
C2
16
30
IDC
C1
17
29
RSVD
FS
7
I/O1
Am79C2031
RSVD
RST
RSVD
VIN
VREF
AGND
VOUT
VM
RSVD
INT
RSVD
18 19 20 21 22 23 24 25 26 27 28
Note:
RSVD = Reserved. Do not connect to this pin.
8
Am79213/Am79C203/031 Data Sheet
PIN DESCRIPTIONS
ASLIC Device
Pin Names
Type
Description
AD, BD
Output
A and B Line Drivers. These pins provide the currents to the A and B leads of the subscriber loop.
BAL1
Input
BGND
Gnd
Pre-balance. This pin receives voltages that are added to the VTX output signal. They can
be used to cancel out the metering echo in the transmit path.
Battery Ground. This pin connects to the ground return for Central Office or talk
battery.
C2–C1
Input
ASLIC Device Control. These ternary logic input pins control the operating state of the
ASLIC device.
C5–C3
Input
Test Relay Control. These are control inputs for the test relay drivers in the ASLIC device.
A logic Low turns on the relay driver and activates the relay. C3 controls RY1OUT, C4
controls RY2OUT, and C5 controls RY3OUT.
GND
Gnd
Analog and digital ground return for VCC.
HPA, HPB
Capacitor
High-Pass Filter Capacitor Connections. These pins connect to CHP, the external highpass filter capacitor that isolates the DC control loop from the voice transmission path.
IDC
Input
DC Loop Control Current. The DC loop current control line from the ASLAC device is connected to this pin. An internal resistance is provided between the IDC pin and RSN. An
external noise filter capacitor should be connected between this pin and VREF.
IDIF
Output
A – B Leg Current. The current at this pin is proportional to the difference of the currents
flowing out of the AD pin and into the BD pin of the ASLIC device.
ISUM
Output
A + B Leg Current. The current at this pin is proportional to the absolute value of the sum
of the currents flowing out of the AD pin and into the BD pin of the ASLIC device.
QBAT
Power
Quiet Battery Voltage. The QBAT pin is connected to the substrate.
RINGOUT,
RY1OUT,
RY2OUT,
RY3OUT
Output
Relay Drivers. These are open collector, high current relay driver outputs with emitters
internally connected to BGND. To absorb the inductive pulse from the relay coils, an internal Zener diode is connected between the collector of each driver and BGND.
RSN
Input
Receive Summing Node. The metallic current (both AC and DC) between AD and BD is
equal to ASLIC device current gain, K1, times the current into this pin. Networks that program receive gain and two-wire impedance connect to this node. This input is nominally
at VREF potential.
RSVD
Input
Reserved. This is used during Legerity testing. In the application, this pin must be floating.
SA, SB
Input
A and B Lead Voltage Sense. These pins sense the voltages on the line side of the fuse
resistors at the A and B leads. External sense resistors, RSA and RSB, are required to
protect these pins from lightning or power cross conditions.
TMG
Thermal
Thermal Management. A resistor connected from this pin to VBAT reduces the on-chip
power dissipation by absorbing excess power from the ASLIC device for short-loop conditions.
VBAT
Power
Battery Voltage. This pin supplies battery voltage to the line drivers.
VCC
Power
Power Supply. This is the positive supply for low voltage analog and digital circuits in the
ASLIC device.
VDC
Output
DC Loop VoltageThe voltage on this output is referenced to VREF and is proportional to
the negative absolute value of the DC subscriber loop voltage between A and B. This voltage is a fraction (β) of the voltage between HPA and HPB. This pin connects to the IAB
pin on the ASLAC device through external resistor RAB. A voltage that is significantly
more positive than VREF on the VDC pin indicates that the ASLIC device is in thermal
shutdown.
ASLIC/ASLAC Products
9
Pin Names
Type
Description
VLBIAS
Input
Longitudinal Offset Voltage. The input to this pin is the offset reference voltage for the
ASLIC device longitudinal control loop.
VREF
Input
Analog Reference. This voltage is provided by the ASLAC device and is used by the
ASLIC device for internal reference purposes. All analog input and output signals interfacing to the ASLAC device are referenced to this pin. Nominally set to 2.1 V.
VTX
Output
Four-Wire Transmit Signal. The voltage between this pin and VREF is a scaled version
of the AC component of the voltage sensed between the SA and SB pins. One end of the
two-wire input impedance programming network connects to VTX. The voltage at VTX
swings positive and negative about VREF.
Pin Names
Type
Description
AGND
Gnd
C2–C1
Output
ASLIC Device Control. These ternary logic output pins are dedicated to controlling the operating state of the ASLIC device. The levels of these outputs are logic High, logic Low,
and high impedance.
CS
Input, Active
Low
Chip Select. The chip select input (active Low) enables the device so commands and
data can be written to or read from it. If chip select is held Low for 16 or more DCLK cycles (independent of MCLK or PCLK), a hardware reset is executed at the time chip select returns to logic 1.
DCLK
Input
Data Clock. The data clock input shifts data into or out of the microprocessor interface of
the ASLAC device. The maximum clock rate is 4.096 MHz.
DGND
Gnd
Digital Ground. Digital ground return.
DI/O
Input/Output
Data Input/Output. Control data is serially written into and read out of the ASLAC device
via the DI/O pin, with the most significant bit first. The data clock (DCLK) determines the
data rate. DI/O is high impedance except when data is being transmitted from the ASLAC
device under control of CS.
DRA, DRB
Input
Receive PCM Data. Receive PCM data is received serially on either the DRA or DRB
port, with port selection under user program control. Data is received, most significant
bit first, in 8-bit PCM or 16-bit linear 2’s complement bursts every 125 µs at the PCLK
rate. The receive port is unaffected by the setting of the SMODE bit. (DRB – 44-pin
PLCC only.)
DXA, DXB
Output
Transmit PCM Data. Transmit PCM data is transmitted serially through either the DXA or
DXB port, with port selection under user control. The transmission data output is available
every 125 µs and is shifted out, most significant bit first, in 8-bit PCM or 16-bit linear 2’s
complement bursts at the PCLK rate. DXA/B are high impedance between bursts and
while the device is in the Inactive state.
ASLAC Device
Analog (Quiet) Ground. VREF is referenced to this ground.
For signaling register operation on the PCM highway, see the SMODE description. (DXB
– 44-pin PLCC only.)
10
FS
Input
Frame Sync. The frame sync signal is an 8 kHz pulse that identifies the beginning of a
frame. The ASLAC device references individual time slots with respect to this input, which
must be synchronized to PCLK.
IAB
Input
Loop Voltage Sense. The IAB pin is a current summing node referenced to VREF. An external resistor (RAB) is connected between this pin and the VDC pin of the ASLIC device,
In normal operation, current flows out of this pin. When the ASLIC device is in thermal
shutdown, current will be forced into this pin.
IBAT
Input
Battery Voltage Sense. The IBAT pin is a current summing node referenced to AGND and
receives a current that is proportional to the system battery voltage. A sense resistor/capacitor network is connected between the QBAT pin of the ASLIC device and the IBAT
pin.
Am79213/Am79C203/031 Data Sheet
Pin Names
Type
Description
IDC
Output
DC Loop Control Current. The IDC output supplies a current to the ASLIC device for proportional control of the DC loop current flowing through the subscriber loop.
IDIF
Input
Longitudinal Sense. IDIF is a current input pin fed by the IDIF pin of the ASLIC device.
The current in this pin is used by the ASLAC device for supervisory and diagnostic functions. The IDIF pin has an internal input resistance so an external longitudinal noise filter
capacitor can be connected.
INT
Output, Active
Low
Interrupt. A logic 0 on this pin indicates one or more of the bits in the signaling register
has changed states. An interrupt will be generated when activity is sensed on any signal
in the Signaling Register not masked by the Mask Register. Once an unmasked activity
is sensed, the INT output will be driven Low and held at that state until cleared. See the
description of configuration register 6 for operation.
I/O1, I/O2, I/O3,
I/O4
Input/output
Control Ports. These control lines are TTL compatible and each can be programmed as
an input or an output. When programmed as inputs, they can monitor external, TTL compatible logic circuits. When programmed as outputs, they can control an external logic device or they can be connected to pin C3, C4, or C5 of the ASLIC device to control test
relay drivers RY1OUT, RY2OUT and RY3OUT (I/O3, I/O4, 44-pin PLCC version only). In
the Output mode, these pins are controlled by the I/O1, I/O2, I/O3, and I/O4 bits in the
Channel Control Register, MPI Command 17.
IREF
Reference
Current Reference. An external resistor (RREF) connected between this pin and analog
ground generates an accurate on-chip reference current. This current is used by the
ASLAC device in its DC Feed and loop-supervision circuits.
IRTA, IRTB
Inputs
Ring Trip Sense. These pins are current summing nodes referenced to VREF. They provide terminations for external resistors RSR1 and RSR2, which sense the voltages on
both sides of the ringing feed resistor connected to the ring bus. To determine the ringing current in the loop, the ASLAC device senses the difference between the currents
in these pins.
ISUM
Input
Metallic Sense. ISUM is a current input pin and is fed by the ISUM pin of the ASLIC device. The absolute value of the current in this pin is used by the ASLAC device for supervisory and diagnostic functions.
MCLK
Input
Master Clock. The master clock is used to operate the digital signal processor. MCLK
can be 2.048 MHz, 4.096 MHz or 8.192 MHz. MCLK may be asynchronous to PCLK.
Upon initialization, the MCLK input is disabled and relevant circuitry is driven by a
connection to PCLK. The MCLK connection may be reestablished under user control.
PCLK
Input
PCM Clock. The PCM clock determines the rate at which PCM data is serially shifted into
or out of the PCM ports. PCLK is an integer multiple of the frame sync frequency. The
maximum clock frequency is 8.192 MHz and the minimum clock frequency is 128 kHz for
companded data. The minimum clock frequency for linear or companded data plus signaling data is 256 kHz. The PCLK clock may be asynchronous to MCLK if the initial connection state is disabled under user control.
RST
Input, Active
Low
Reset. A logic 0 on this pin resets the ASLAC device to initial default conditions. It is
equivalent to a hardware reset command. A signal less than 100 ns should not cause
a reset. To ensure proper reset, the minimum length of a reset pulse is 50 µs.
TSCA, TSCB
Open Drain
Outputs
Time Slot Control. The time slot control outputs are open drain (requiring an external
pull-up resistor to VCCD) and are normally inactive (high impedance). TSCA is active
(Low) when PCM data is present on DXA, and TSCB is active (Low) when PCM data is
present on DXB. (TSCB and DRB – 44-pin PLCC only.)
VCCA
Power
Analog Power Supply. VCCA is internally connected to substrate near the analog I/O
section.
VCCD
Power
Digital Power Supply. VCCD is internally connected to substrate near the digital section.
VIN
Input
Analog Input. The analog output (VTX) from the ASLIC device is applied to the ASLAC
device transmit path input, VIN. The signal is sampled, processed, encoded, and transmitted on the PCM Highway.
ASLIC/ASLAC Products
11
12
Pin Names
Type
Description
VLBIAS
Output
Longitudinal Reference. VLBIAS is programmed by VOFF and supplies the longitudinal
reference voltage for the longitudinal control loop to the ASLIC device.
VM
Output
12/16 kHz Metering Signal. For 12/16 kHz teletax, an internally generated and shaped 12
or 16 kHz sine wave metering pulse is output from this pin.
VOUT
Output
Analog Output. The voice data from the received PCM channel (timeslot) is digitally processed and converted to an analog signal which is present on the VOUT pin of the
ASLAC device.
VREF
Output
Analog Reference. This pin provides a voltage reference to be used as the analog zero
level reference on the ASLIC device.
Am79213/Am79C203/031 Data Sheet
ASLIC/ASLAC DEVICES FUNCTIONAL
DESCRIPTION
The ASLIC/ASLAC devices chip set integrates all functions of the subscriber line. The chip set comprises an
ASLIC device and an ASLAC device. The set provides
two basic functions: 1) the ASLIC device, a high-voltage,
bipolar device that drives the subscriber line, maintains
longitudinal balance, and senses line conditions; and 2)
the ASLAC device, a low-voltage CMOS device that
combines CODEC, DC Feed control, and line supervision. A complete schematic of a linecard using the
ASLIC/ASLAC devices chip set is shown in the Figure 7.
The ASLIC device uses reliable, bipolar technology to
provide the power necessary to drive a wide variety of
subscriber lines. It can be programmed by the ASLAC
device to operate in eight different states that control
Power Consumption and Signaling states. This enables
full control over the subscriber loop. The ASLIC device
is customized to be used exclusively with the ASLAC
device, providing a two-chip universal line interface. The
ASLIC device requires only a +5 V power supply and a
negative battery supply for its operation.
The ASLIC device implements a linear loop current
feeding method with the enhancement of thermal management to limit the amount of power dissipated on the
ASLIC device by dissipating excess power in an external
resistor.
The ASLAC device is a high-performance, CMOS CODEC/filter device with additional digital filters and circuits that allow software control of transmission, DC
Feed, and supervision.
The ASLIC device interface unit inside the ASLAC device
processes information regarding line voltages, loop currents, and battery voltage levels. These inputs allow the
ASLAC device to place several key ASLIC device performance parameters under programmable supervision.
The main functions that can be observed and/or controlled
through the ASLAC device control interface are:
Off-hook detection
Metering signal
Longitudinal operating point
Subscriber line voltage and currents
Ring trip
Abrupt and smooth battery polarity reversal
The sum and difference of the currents in each loop
leg, ISUM, and IDIF
Currents proportional to the:
— voltage across the loop (IAB)
— battery voltage (IBAT)
— ringing current in the loop (IRTA – IRTB)
The outputs supplied by the ASLAC device are then:
When used with an ASLIC device, the ASLAC device
provides a complete software-configurable solution to
linecard functions. In addition, the ASLIC/ASLAC devices chip set provides system-level solutions for loop supervisory functions and metering. In total, the ASLIC/
ASLAC devices chip set provides a programmable solution that can satisfy worldwide linecard requirements
by software configuration.
The ASLAC device uses the industry standard microprocessor (MPI) and PCM interfaces to communicate
with the system and for interfacing to the 64 kilobit per
second voice network.
Ground-key detection
To accomplish these functions, the ASLAC device collects the following information from the ASLIC device
and the Central Office system:
Advanced CMOS technology makes the ASLAC device
an economical device that has both the functionality and
the low power consumption required by linecard designers to maximize linecard density at minimum cost.
All software-programmed coefficients and DC Feed parameters are easily calculated with the AmSLAC3ä software. This software is provided free of charge and runs
on an IBM-compatible PC. It allows the designer to enter
a description of system requirements, then the software
returns the necessary coefficients and the predicted
system response.
DC Feed characteristics
A current proportional to the desired DC loop current (IDC)
A voltage proportional to the desired longitudinal offset voltage (VLBIAS)
A 12/16 kHz metering signal (appears on VM for
12/16 kHz teletax)
The ASLAC device performs the CODEC and filter functions associated with the four-wire section of the subscriber line circuitry in a digital switch. These functions
involve converting an analog voice signal into digital
PCM samples and converting digital PCM samples back
into an analog signal. During conversion, digital filters
are used to band-limit the voice signals.
The user-programmable filters set the receive and
transmit gain, perform the transhybrid balancing function, permit adjustment of the two-wire termination impedance, and provide frequency response adjustment
(equalization) of the receive and transmit paths. Adaptive transhybrid balancing is also included.
ASLIC/ASLAC Products
13
The PCM data can be either 8-bit companded A-law
code, 8-bit companded µ-law code, or 16-bit linear
code. Voice data is transmitted and received via the
PCM highway; control information is written to and read
from the ASLAC/ASLIC devices chip set over the microprocessor interface.
Besides the CODEC functions, the ASLAC device provides all the sensing, feedback, and clocking necessary to completely control ASLIC device functions with
programmable parameters. The line status is continuously available in the ASLAC Device Signaling Register, which is continuously available via the MPI
interface, or on the PCM highway via a user-programmable mode. A programmable interrupt provides added flexibility in monitoring line status. System-level
parameters under programmable control include active and disable loop-current limits, feed resistance,
and apparent battery-feed voltage. The longitudinal
operating point is programmable to optimize the ASLIC
device signal swing capability.
14
The ASLAC device provides signals at 12 or 16 kHz for
metering functions. The frequency and level of these
signals are programmable.
The ASLAC device provides extensive loop supervision
capability, including off-hook, ring-trip, and ground-key
detection. Detection thresholds for these functions are
programmable. A programmable debounce timer is
available that eliminates false detection due to contact
bounce. For subscriber line diagnostics, AC and DC line
conditions can be monitored using special test modes.
Results are read using the MPI commands.
Am79213/Am79C203/031 Data Sheet
ELECTRICAL REQUIREMENTS
Power Dissipation
Loop resistance = 0 to ∞ (not including fuse resistors),
2 x 50 Ω fuse resistors, VBAT = QBAT = –48 V, VCC =
+5 V. For power dissipation measurements, DC Feed
conditions are programmed as follows:
VAS (anti-sat activate voltage) = 8.2 V
VAPP (apparent voltage) = 50.2 V
RTMG (thermal management resistor) = 1200 Ω
ILA (Active state current limit) = 42.3 mA
RREF (reference current setting resistor) = 7.87 kΩ
N2 (anti-sat feed resistance factor) = 2
VOFF (longitudinal offset voltage) = 6 V
ILD (Disable state current limit) = 21.2 mA
RFD (feed resistance) = 807 Ω
Description
Table 1. Power Dissipation
Typ
Max
On-hook Disconnect
30
70
On-hook Standby
50
105
On-hook Disable
120
215
On-hook Active
330
450
Off-hook Active RL = 294 Ω
850
1200
Off-hook Disable RL = 600 Ω
800
950
ASLAC device power dissipation
MCLK, PCLK = 2.048 MHz
ASLAC device activated
85
110
ASLAC device inactive, MPI Standby
state command issued
22
25
ASLAC device power dissipation
MCLK, PCLK > 2.048 MHz
ASLAC device activated
95
120
ASLAC device inactive, MPI Standby
state command issued
23
26
ASLIC device power dissipation
Normal polarity
Test Conditions
Min
Unit
mW
Thermal Resistance
The junction-to-air thermal resistance of the ASLIC device in a 32-pin PLCC package will be less than 45°C/W.
The junction-to-air thermal resistance of the ASLAC device in a 32-pin PLCC package will be less than 45°C/W.
The junction-to-air thermal resistance of the ASLAC device in a 44-pin PLCC package will be less than 44°C/W.
ASLIC/ASLAC Products
15
ABSOLUTE MAXIMUM ELECTRICAL
AND THERMAL RATINGS
ASLIC Device
Storage temperature...................–55°C ≤ TA ≤ +150°C
Ambient temperature,
under bias................................–40°C ≤ TA ≤ +85°C
Ambient relative humidity
(noncondensing).................................. 5% to 100%
VCC with respect to AGND/DGND......... –0.4 V to +7 V
VBAT, QBAT with respect to BGND....... +0.4 V to –75 V
VCC with respect to VBAT, QBAT ......................... +80 V
BGND with respect to
AGND/DGND ................................–0.5 V to +0.5 V
Voltage on relay outputs....................................... +7 V
AD or BD to BGND:
Continuous ........................................–75 V to +1 V
10 ms (f = 0.1 Hz).............................. –75 V to +5 V
1 µs (f = 0.1 Hz)............................... –90 V to +10 V
250 ns (f = 0.1 Hz).........................–120 V to +15 V
Current into SA or SB: 10 µs rise to Ipeak;
1000 µs fall to 0.5 Ipeak;
2000 µs fall to I = 0.......................... Ipeak = ±5 mA
Current into SA or SB: 2 µs rise to Ipeak;
10 µs fall to 0.5 Ipeak;
20 µs fall to I = 0 ......................... Ipeak = ±12.5 mA
Current through AD or BD ............................. ±150 mA
C5–C1
to DGND or AGND ............... –0.4 V to VCC + 0.4 V
ASLAC Device
Storage temperature .................. –60°C ≤ TA ≤ +125°C
Ambient temperature,
under bias ............................... –40°C ≤ TA ≤ +85°C
Ambient relative humidity
(noncondensing) .................................. 5% to 100%
VCCA, VCCD with respect to DGND ....... –0.4 V to +6 V
VCCA with respect to VCCD .................................±0.4 V
VIN with respect to DGND ........ –0.4 V to VCCA + 0.4 V
AGND..................................................... DGND ±0.4 V
Latch up immunity (any pin)...........................±100 mA
Any other pin with respect
to DGND ............................... –0.4 V to VCC + 0.4 V
Stresses above those listed under Absolute Maximum Ratings
may cause permanent device failure. Functionality at or above
these limits is not implied. Exposure to Absolute Maximum Ratings for extended periods may affect device reliability.
OPERATING RANGES
Environmental
Ambient temperature .........0°C to +70°C Commercial*
Ambient relative humidity.......................... 15% to 85%
ASLIC Device
VCC ..............................................................+5 V ± 5%
VBAT, QBAT............................................–18 V to –70 V
BGND with respect to GND ....... –100 mV to +100 mV
Maximum power dissipation, TA = 70°C ........... 1.67 W
Load resistance on VTX to ground ............... 10 kΩ min
Note: Thermal limiting circuitry on chip will shut down the circuit at a junction temperature of about 160°C. The device
should never be exposed to this temperature. Operation
above 145°C junction temperature may degrade device reliability. See the SLIC Packaging Considerations for more information.
ASLAC Device
Supplies VCCA, VCCD ...................................+5 V ± 5%
DGND ..................................................................... 0 V
AGND.................................................. DGND ± 50 mV
Operating ranges define those limits over which the functionality of the device is guaranteed by production testing.
* Functionality of the device from 0°C to +70°C is guaranteed
by production testing. Performance from –40°C to +85°C is
guaranteed by characterization and periodic sampling of production units.
16
Am79213/Am79C203/031 Data Sheet
PERFORMANCE SPECIFICATIONS
(See note 1) TA = 0°C to 70°C unless otherwise noted.
Table 2. ASLIC Device DC Specifications
No.
1
Item
2-wire loop voltage
Condition
Min
Typ
Max
QBAT – 1.8
QBAT – 1.1
QBAT – 0.5
Active state, RLAD–BD = 600 Ω
IRSN = 140 µA
19.51
21.1
22.68
Disable state, RLAD–BD = 600 Ω
IRSN = 80 µA
11.34
12.19
13.04
375
Standby state, RL = 1 MΩ
Note
4
V
2
Feed resistance per leg
at pins AD and BD
Standby state
130
250
3
ISUM current
Standby state, RL = 1930 Ω
44.6
56
IDIF current
Standby state
A to QBAT
B to ground
35.4
43.4
4
Unit
Ω
µA
Ternary input voltage boundaries for C2–C1 pins. Midlevel input source must be high impedance or 3-state
Low boundary
0.8
V
High boundary
Logic inputs C2–C1
Input High current
–80
Input Low current
90
3-state voltage
5
VCC – 1
200
µA
IC1 = IC2 = 1 µA
Logic inputs C5–C3
Input High voltage
0.8
200
3.5
4
V
2.0
Input Low voltage
0.8
Input High current
–200
40
Input Low current
–400
40
+50
mV
µA
6
VTX output offset
BAL1 pin open
–50
7
VREF input voltage
IREF = ±1 mA
2.0
2.1
2.2
V
8
β, Ratio of VDC to loop
voltage:
Tj < 145°C, VDC is referenced
to VREF, 35.7 kΩ resistor connected from VDC to VREF.
VSA – VSB = 40 V.
0.0253
0.0242
0.0232
V/V
4.2
VCC – 0.4
5.58
6.0
20
33.3
VDC – VREF
β = -----------------------------------VSA – VSB
9
Thermal shutdown
threshold voltage output
on VDC
10
Gain from VLBIAS pin to
AD or BD pin
11
Input resistance to
AGND, VLBIAS pin
IVDC = 20 µA
V
6.42
4
V/V
kΩ
VLBIAS = 3 V
ASLIC/ASLAC Products
17
Table 2. ASLIC Device DC Specifications (continued)
No.
Item
12
ISUM/ILOOP
13
IDIF/ILONG
14
Input current,
SA and SB pins
15
Input current
HPA and HPB pins
16
IDC input impedance
17
K1
18
Metallic offset current
Condition
Min
Typ
Max
ILOOP = 10 mA
1/333
1/300
1/273
ILONG = 10 mA
1/667
1/600
1/546
1
3
0.1
3
1.8
3
Unit
Note
µA
1.26
Incremental DC current gain
254
4
kΩ
A/A
13
0
–0.4
mA
ASLIC Device Relay Driver Schematic
RINGOUT
RY1OUT
RY2OUT
RY3OUT
BGND
Table 3. ASLIC Device Relay Driver Specifications
Item
Condition
25 mA per relay sink
Min
Typ
Max
1 relay on
0.225
0.3
4 relays on
0.4
0.5
On voltage
Unit
Note
4
V
40 mA per relay sink
Off leakage, each relay driver
VOH = +6 V
1 relay on
0.45
0.7
4 relays on
0.8
1.0
0
4
100
µA
Max
Unit
Note
Ω
4
Table 4. ASLIC Device Transmission Specifications
No.
18
Item
Condition
Min
f = 300 Hz to 3400 Hz
Typ
1
RSN input impedance
1
2
VTX output impedance
3
Gain, BAL1 to VTX
1.4
1.5
1.6
V/V
4
BAL1 input impedance
3.17
5
7.5
kΩ
5
Input impedance
A or B to GND
70
135
Ω
3
Am79213/Am79C203/031 Data Sheet
4
Table 4. ASLIC Device Transmission Specifications (continued)
No.
Item
Condition
Min
Typ
Max
–12.04
–11.89
–11.84
6
2- to 4-wire gain
–10 dBm, 1 kHz
TA = –40°C to 0°C/70°C to 85°C
–12.19
–12.24
7
2- to 4-wire gain variation
with frequency
300 to 3400 Hz relative to 1 kHz
TA = –40°C to 0°C/70°C to 85°C
–0.1
–0.15
+0.1
+0.15
8
2- to 4-wire gain tracking
+3 dBm to –55 dBm
Reference: –10 dBm
TA = –40°C to 0°C/70°C to 85°C
–0.1
+0.1
–0.15
+0.15
9
4- to 2-wire gain
–10 dBm, 1 kHz
TA = –40°C to 0°C/70°C to 85°C
–0.15
–0.20
10
4- to 2-wire gain variation
with frequency
300 to 3400 Hz relative to 1 kHz
TA = –40°C to 0°C/70°C to 85°C
–0.1
–0.15
+0.1
+0.15
11
4- to 2-wire gain tracking
+3 dBm to –55 dBm
Reference: –10 dBm
–0.1
+0.1
–0.15
+0.15
12
13
300 Hz to 3400 Hz
0 dBm
+4 dBm
–50
–40
4-wire
–12 dBm
–8 dBm
–50
–40
2-wire metering overload
level
VLBIAS = 2.4 V, ILOOP = 30 mA,
VBAT = QBAT = –60 V, DC LOAD = 200 Ω,
Load at 16 kHz = 10 kΩ
42
Idle channel noise
C-message
weighted
Active and Disable states
2-wire
TA = –40°C to 0°C/70°C to 85°C
+7
4-wire
–5
2-wire
TA = –40°C to 0°C/70°C to 85°C
–83
4-wire
–95
Longitudinal balance
(IEEE method)
Normal polarity
L-T
200 to 1000 Hz
TA = –40°C to 0°C/70°C to 85°C
1000 to 3400 Hz
TA = –40°C to 0°C/70°C to 85°C
58
53
53
48
T-L
40
200 to 3400 Hz
L - T, IL = 0 50 to 3400 Hz
15
Note
+0.15
+0.20
Total harmonic distortion
2-wire
Psophometric
weighted
14
0
Unit
+11
+15
dB
Vp-p
4
dBrnC
4
4
–79
–75
dBmp
4
63
58
63
4
Reverse polarity
L-T
200 to 1000 Hz
TA = –40°C to 0°C/70°C to 85°C
50
48
PSRR (VBAT, QBAT)
50 to 3400 Hz
25
45
3, 5
3.4 kHz to 50 kHz
25
40
4
ASLIC device in Anti-Sat state
(loop open)
f = 50 Hz, CB = 100 nF
f = 200 to 3400 Hz, CB = 100 nF
2
12
ASLIC/ASLAC Products
dB
4, 8
19
Table 4. ASLIC Device Transmission Specifications (continued)
No.
16
Item
PSRR (VCC)
Condition
Min
Typ
25
45
50 to 3400 Hz
Max
Unit
Note
3, 5
dB
3.4 kHz to 50 kHz
17
Low frequency induction
(REA method)
Active state, VLONG = 30 Vrms,
IL = 20 mA, f = 60 Hz
18
Longitudinal AC current
per wire
f = 15 to 60 Hz
25
35
2, 4
+23
dBrnC
4
20
mArms
Table 5. ASLAC Device DC Specifications
No.
Item
Condition
Min
Typ
Max
1
Input Low voltage
(Any digital input)
–0.5
0.8
2
Input High voltage
(Any digital input)
2.0
VCC + 0.5
3
Input leakage current
(Any digital input)
–10
+10
4
Input hysteresis (FS and
RST only)
5
Ternary output voltages
C2–C1
Unit
Note
V
6
7
8
0.5
High voltage
IOUT = ±200 µA
Low voltage
IOUT = ±200 µA
Output current
Mid level
Output Low voltage on
digital outputs
DXA, DXB, DI/O, TNT,
TSCA, TSCB, I/O1, I/O2,
I/O3, I/O4
IOL = 2 mA
0.4
TSCA, TSCB
IOL = 14 mA
0.4
I/O1, I/O2, I/O3, I/O4
IOL = 10 mA
1.0
Output High voltage (all
digital outputs except
INT in the Open Drain
state and TSC)
IOH = 400 µA
VCC – 0.85
µA
15
V
4
V
0.65
–1
+1
µA
V
VCC – 0.4
DC Feed
ILA = 47.6 mA, RFD = 403 Ω,
N2 = 2, VAS = 10.3 V,
IBAT = 69.9 µA
IDC
Active state,
Normal polarity, IAB = 0,
VAPP = 50.2 V
172.7
188.5
204.9
µA
∆IAB
--------------∆IDC
In resistive-feed region
0.0624
0.0694
0.0764
A/A
IAB
IBAT = 69.9 µA
Adjust IAB until IDC = 0
27.93
29.93
31.93
µA
Measured VAPP
Programmed VAPP = 50.2 V
±2.2
Measured VAS
Programmed VAS = 10.3 V
±1.6
19
V
20
Am79213/Am79C203/031 Data Sheet
19
Table 5. ASLAC Device DC Specifications (continued)
No.
9
Item
IDC error among
programmed ILA, ILD
10
Offset voltage allowed
on VIN
11
VOUT offset voltage
12
Output voltage, VREF
13
Capacitance load on
VREF or VOUT
Condition
Min
Typ
Max
Unit
Note
Any ILA or ILD programmed
value > 20 mA (IDC > 78.7 µA)
±5
%
4, 19
Any ILA or ILD programmed
value ≤ 20 mA (IDC ≤ 78.7 µA)
±4
µA
19
–50
+50
AISN off
–40
+40
AISN on
–80
+80
Load current = 0 to 1 mA
Source or sink
2.0
2.1
10
mV
10, 19
10
2.2
V
200
pF
19
4
Source or sink
–1
+1
mA
18.36
kΩ
6
+1
+2.4
V
18
–5
+5
%
14
Output current VOUT
15
Input resistance
IDIF pin to VREF
16
VLBIAS operating
voltage
Source current < 250 µA or sink
current < 25 µA
17
Percent error of VLBIAS
voltage
For VLBIAS equation see
longitudinal control loop
18
Capacitance load on
VLBIAS
120
19
Capacitance load on
IRTA or IRTB
400
8.84
13.6
pF
ASLIC/ASLAC Products
6
21
Table 6. ASLAC Device Transmission and Signaling Specifications
No.
Item
1
Insertion loss
A-D
D-A
A-D + D-A
2
3
4
Level set error (error between setting and
actual value)
DR to DX gain in Full
Digital Loopback mode
Idle channel noise,
psophometric weighted
(A-law)
Condition
Min
Typ
Max
Input: 1014 Hz, –10 dBm0
RG = AR = AX = GR = GX = 0 dB,
AISN, R, X, B, and Z filters disabled
TA = 0°C to 70°C
TA = –40°C to 0°C/70°C to 85°C
TA = 0°C to 70°C
TA = –40°C to 0°C/70°C to 85°C
TA = 70°C
TA = 0°C –70°C; VCC = 4.75 – 5.25 V
TA = –40°C to 0°C/70°C to 85°C
–0.25
–0.30
–0.25
–0.30
–0.20
–0.25
–0.34
0
0
0
0
0
0
0
+0.25
+0.30
+0.25
+0.30
+0.20
+0.25
+0.34
A-D
AX + GX
–0.1
+0.1
D-A
AR + GR
–0.1
+0.1
–0.3
+0.3
–0.35
+0.4
DR input: 1014 Hz, –10 dBm0
RG = AR = AX = GR = GX = 0 dB,
AISN, R, X, B, and Z filters disabled
TA = –40°C to 0°C/70°C to 85°C
Unit
7
dB
AX = 0 dB
AR = 0 dB
dBm0p
5
Idle channel noise,
C-message weighted
(µ-law)
Note
A-D (PCM output)
–68
D-A (VOUT)
–78
12
AX = 0 dB
AR = 0 dB
dBrnC0
GX = +8 dB
+16
D-A (2 wire),
GR = –8 dB
+12
6
Coder offset decision
value, Xn
A-D, Input signal = 0 V, A-law
7
GX step size
+5
Bits
6
0 ≤ GX < 10 dB
10 ≤ GX ≤ 12 dB
0.1
0.3
dB
4
0.1
dB
4
µs
4, 14
8
GR step size
–12 ≤ GR ≤ 0 dB
9
PSRR (VCC)
Image frequency
Input: 4800 to 7800 Hz
200 mV p-p
Measure 8000 Hz input frequency
10
22
A-D (PCM output),
Group delay
PCLK ≥ 1.53 MHz
PCLK ≤ 1.03 MHz
–5
A-D
37
D-A
37
1014 Hz; –10 dBm0
B, X, R, and Z filters set to default
Am79213/Am79C203/031 Data Sheet
590
655
Table 6. ASLAC Device Transmission and Signaling Specifications (continued)
No.
Item
Condition
11
Switchhook thresholds
All TSH settings
Switchhook hysteresis
All TSH settings
Ground-key thresholds
All TGK settings
12
13
14
Ground-key hysteresis
All TGK settings
Voltage that sets
thermal shutdown bit
Voltage on ASLIC device VDC with
RAB = 35.7 kΩ
IDIF fault-current
thresholds
Tip-to-battery fault current
(mA)
FT, pkFT
19.3, 50.6
Min
–0.45
or
–10
Max
Unit
+0.45
or
+10
mA
–10
+0.90
or
+10
–0.90
or
–10
–10
Note
%
9, 16,
19
%
4
mA
%
9, 16,
19
%
4
+4.19
V
–10
FT, pkFT hysteresis
15
Typ
+10
16,
19
–10
AISN gain accuracy
GAISN = ±0.0625
–16
+16
GAISN = ±0.125
–8
+8
GAISN = ±0.1875
–6
+6
GAISN = ≤ –0.25 or GAISN ≥ +0.25
–4
+4
+7
16
Metering voltage
(MTRA) accuracy
Measured at ASLAC device VM pin
–7
17
Metering voltage noise
Wide-band signal to noise
40
18
Ring-trip accuracy
19
Ring-trip hysteresis
VZX
IZX
20
Power-cross accuracy
During transmission
–10
+10
During ringing
–10
+10
%
4
dB
–5
5
4
5
%
4, 17,
20
V
µA
4, 17
%
17,
20
Notes:
1. Unless otherwise specified, test conditions are:
VCC = 5 V, RTMG = 1200 Ω, QBAT = BAT = –51 V, RAB = 35.7 kΩ, RBAT1 = RBAT2 = 365 kΩ, RREF = 7.87 kΩ, RRX = 75 kΩ, RL
= 600 Ω, RSA = RSB = 200 kΩ, CHP = 220 nF, CDC1 = 1.0 µF, 50 Ω fuse resistors, RSR1 = RSR2 = 750 kΩ,
CAD = CBD = 22 nF, CB = 100 nF and the following network is connected between VTX and RSN:
RT1
18.75 K
RT2
18.75 K
VTX
RSN
CT
430 pF
ASLIC/ASLAC Products
23
Ambient temperature = 70°C
Active state, normal polarity for transmission performance
0 dBm = 1 mW @ 600 Ω (0.775 Vrms)
Programmed DC Feed conditions:
VAPP (apparent battery voltage) = 50.2 V
ILA (Active state loop-current limit) = 47.6 mA
ILD (Disable state loop-current limit) = 21.2 mA
RFD (DC Feed resistance) = 403 Ω
VAS (anti-sat activate voltage) = 10.3 V
N2 (anti-sat feed resistance factor) = 2
VOFF (longitudinal offset voltage) = 8.4 V
RG = GX = GR = AX = AR = 0 dB
R, X, B, and Z filters set to default
AISN = 0
TSH < ILD
TSH = Programmed switchhook detect threshold current
ILD = Programmed disable limit current
DC Feed conditions are normally set by the ASLAC device. When the ASLIC device is tested by itself, its operating conditions
must be simulated as if it were connected to an ideal ASLAC device. When the ASLAC device is tested by itself, its operating
conditions must simulate as if it were connected to an ideal ASLIC device.
2. These tests are performed with the following load impedances:
Frequency < 12 kHz - longitudinal impedance = 500 Ω; metallic impedance = 300 Ω
Frequency > 12 kHz - longitudinal impedance = 90 Ω; metallic impedance = 135 Ω
3. This parameter is tested at 1 kHz in production. Performance at other frequencies is guaranteed by characterization.
4. Not tested or partially tested in production. This parameter is guaranteed by characterization or correlation to other tests.
5. When the ASLIC/ASLAC devices are in the anti-sat operating region, this parameter will be degraded. The exact degradation
will depend on system design.
6. Guaranteed by design.
7. Overall 1.014 kHz insertion loss error of the ASLIC/ASLAC devices kit is guaranteed to be ≤ 0.34 dB.
8. These VBAT/QBAT, PSRR specifications are valid only when the ASLIC device is used with the ASLAC device that generates
the anti-sat reference. Since the anti-sat reference depends upon the battery voltage sensed by the IBAT pin of the ASLAC
device, the PSRR of the kit will depend upon the amount of battery filtering provided by CB.
9. Must meet at least one of these specifications.
10. These voltages are referred to VREF.
11. These limits refer to the two-wire output of an ideal ASLIC device but reflect only the capabilities of the ASLAC device.
12. When relative levels (dBm0) are used, the specification holds for any setting of (AX + GX) gain from 0 to 12 dB or
(AR + GR + RG) from 0 to –12 dB.
13. This parameter tested by inclusion in another test.
14. The group delay specification is defined as the sum of the minimum values of the group delays for the transmit and the receive
paths when the transmit and receive time slots are identical and the B, X, R, and Z filters are disabled with null coefficients.
For PCLK frequencies between 1.03 MHz and 1.53 MHz, the group delay may vary from one cycle to the next. See also Figure
2, Group Delay Distortion.
15. I/O1 and I/O2 have an additional circuit that pulls the pin High during 3-state.
16. These limits reflect only the capabilities of the ASLAC device.
17. RSR1 = RSR2 = 750 kΩ, RGFD1 = 510 Ω.
18. DC Feed performance derates by 5% when operating from –40°C to 0°C and 70°C to 85°C.
19. Threshold values derate by 5% when operating from –40°C to 0°C and 70°C to 85°C.
20. Power cross and ring trip values derate by 5% when operating from –40°C to 0°C and 70°C to 85°C.
24
Am79213/Am79C203/031 Data Sheet
In the following section, the transmit path is defined as the section between the analog input to the ASLAC device
(VIN) and the PCM voice output of the ASLAC device A-law/µ-law speech compressor (shown in the technical overview
document). The receive path is defined as the section between the PCM voice input to the ASLAC device speech
expander and the analog output of the ASLAC device (VOUT). All limits defined in this section are tested with B = 0,
Z = 0 and X = R = RG = 1.
When RG is enabled, a nominal gain of –6.02 dB is added to the digital section of the receive path.
When AR is enabled, a nominal gain of –6.02 dB is added to the analog section of the receive path.
When AX is enabled, a nominal gain of +6.02 dB is added to the analog section of the transmit path.
When the gains in the transmit path are set to AX = 0 dB and GX = 0 dB, a 1014 Hz sine wave with a nominal voltage
of 0.596 Vrms for µ-law and 0.6 Vrms for A-law at the ASLAC device analog input will correspond to a level of 0
dBm0 at the PCM voice output. Under these conditions, the overload level of the transmit path is 1.25 Vpeak referenced
to VREF.
When the gains in the receive path are set to AR = GR = 0 dB, a 1014 Hz sine wave with a level of 0 dBm0 at the
PCM voice input will correspond to a nominal voltage of 0.596 Vrms for µ-law and 0.6 Vrms for A-law at the analog
output of the ASLAC device. Under these conditions, the maximum receive output level is 1.25 Vpeak referenced
to VREF.
When relative levels (dBm0) are used in any of the following transmission characteristics, the specification holds for
any setting of (AX + GX) gain from 0 to 12 dB or (AR + GR + RG) from 0 to –12 dB.
These transmission characteristics are valid for 0°C to 70°C and for VCC = +5 V ± 0.25 V.
ASLIC/ASLAC Products
25
Attenuation Distortion
The deviations from nominal attenuation will stay within the limits shown in Figure 1. The reference frequency is 1014
Hz and the signal level is –10 dBm0. Minimum transmit attenuation at 60 Hz is 24 dB.
2
ASLAC Device Specification
1
0.80
0.6
0.65
Attenuation (dB)
0.2
0.125
0
–0.125
Receive path
0 200 300 600
Frequency (Hz)
3000 3200 3400
Figure 1. Transmit and Receive Path Attenuation vs. Frequency
26
Am79213/Am79C203/031 Data Sheet
Group Delay Distortion
For either transmission path, the group delay distortion is within the limits shown in Figure 2. The minimum value of
the group delay is taken as the reference. The signal level should be –10 dBm0.
ASLAC Device Specification
(Either Path)
420
Delay (µs)
150
90
0
500 600
1000
2600 2800
Frequency (Hz)
Figure 2. Group Delay Distortion
Single Frequency Distortion
The output signal level at any single frequency in the range of 300 Hz to 3400 Hz, other than that due to an applied
0 dBm0 sine wave signal with frequency f0 in the same frequency range, is less than –46 dBm0. With f0 swept between
0 to 300 Hz and 3400 Hz to 12 kHz, any generated output signals other than f0 are less than –28 dBm0. This
specification is valid for either transmission path.
Intermodulation Distortion
Two sine wave signals of different frequencies f1 and f2 (not harmonically related) in the range 300 Hz to 3400 Hz
and of equal levels in the range –4 dBm0 to –21 dBm0 will not produce 2 • (f1 – f2) products having a level greater
than –42 dB relative to the level of the two input signals.
A sine wave signal in the frequency band 300 Hz to 3400 Hz with input level –9 dBm0 and a 50 Hz signal with input
level –23 dBm0 will not produce intermodulation products exceeding a level of –56 dBm0. These specifications are
valid for either transmission path.
ASLIC/ASLAC Products
27
Gain Linearity
The gain deviation relative to the gain at –10 dBm0 is within the limits shown in Figure 3 (A-law) and Figure 4 (µlaw) for either transmission path when the input is a sine wave signal of 1014 Hz.
ASLAC Device Specification
1.5
0.55
0.25
Gain (dB)
0
–55 –50
–40
–10
0 +3
–0.25
Input
Level
(dBm0)
–0.55
–1.5
Note:
Relax specification by 0.05 dB at –40°C.
Figure 3. A-law Gain Linearity with Tone Input (Both Paths)
ASLAC Device Specification
1.4
0.45
0.25
Gain (dB)
0
–55 –50
–37
–10
0 +3
–0.25
Input
Level
(dBm0)
–0.45
–1.4
Note:
Relax specification by 0.05 dB at –40°C.
Figure 4. µ-law Gain Linearity with Tone Input (Both Paths)
28
Am79213/Am79C203/031 Data Sheet
Total Distortion, Including Quantizing Distortion
The signal-to-total distortion ratio will exceed the limits shown in Figure 5 for either path when the input signal is a
sine wave signal of frequency 1014 Hz.
Improved distortion at lower levels in LSSGR applications can be obtained by proper selection of the GX and GR
ranges.
A-law
ASLAC Device Specification
A
B
C
µ-law
A
35.5 dB 35.5 dB
B
35.5 dB 35.5 dB
C
30 dB
31 dB
D
25 dB
27 dB
D
Signal-to-Total
Distortion (dB)
–45
–40
0
–30
Input Level (dBm0)
Figure 5. Total Distortion with Tone Input (Both Paths)
ASLIC/ASLAC Products
29
Overload Compression
Figure 6 shows the acceptable region of operation for input signal levels above the reference input power (0 dBm0).
The conditions for this figure are:
(1) 1 dB < transmit path ≤ +12 dB; (2) –12 dB ≤ receive path < –1 dB; (3) digital voice output connected to digital
voice input; and (4) measurement analog-to-analog.
Fundamental
Output Power
(dBm0)
9
8
7
6
Acceptable
Region
5
4
3
2.6
2
1
1
2
3
4
5
6
7
8
Fundamental Input Power (dBm0)
Figure 6. A/A Overload Compression
30
Am79213/Am79C203/031 Data Sheet
9
SWITCHING CHARACTERISTICS
Microprocessor Interface
Min. and Max. values are valid for all digital outputs with a 100 pF load, except DI/O, DXA, and DXB, which are valid
with 150 pF loads.
Table 7. Microprocessor Interface
No.
Symbol
Parameter
Min
Typ
Max
Units
Note
1
tDCY
Data clock period
244
ns
2
tDCH
Data clock High pulse width
97
ns
1
3
tDCL
Data clock Low pulse width
97
ns
1
4
tDCR
Rise time of clock
25
ns
5
tDCF
Fall time of clock
25
ns
6
tICSS
Chip select setup time, Input mode
70
tDCY – 10
ns
7
tICSH
Chip select hold time, Input mode
0
tDCH – 20
ns
8
tICSL
Chip select pulse width, Input mode
9
tICSO
Chip select off time, Input mode
5
µs
1, 7
10
tIDS
Input data setup time
30
ns
6
11
tIDH
Input data hold time
30
ns
12
tOLH
SLIC output latch valid
0
13
tOCSS
Chip select setup time, Output mode
14
tOCSH
Chip select hold time, Output mode
15
tOCSL
Chip select pulse width, Output mode
16
tOCSO
Chip select off time, Output mode
17
tODD
Output data turn on delay
18
tODH
Output data hold time
19
tODOF
Output data turn off delay
20
tODC
Output data valid
0
21
tRST
Reset pulse width
50
8tDCY
1.2
ns
1.9
µs
70
tDCY – 10
ns
0
tDCH – 20
ns
8tDCY
ns
5
µs
50
3
ASLIC/ASLAC Products
1, 7
ns
ns
50
ns
50
ns
µs
31
Table 8. PCM Interface
No.
Symbol
Parameter
Min
Typ
Units
Note
7.8125
µs
2
22
tPCY
PCM clock period
23
tPCH
PCM clock High pulse width
48
ns
24
tPCL
PCM clock Low pulse width
48
ns
25
tPCF
Fall time of clock
15
ns
26
tPCR
Rise time of clock
15
ns
27
tFSS
FS setup time
30
tPCY – 35
ns
28
tFSH
FS hold time
0
ns
29
tFCH
FS High pulse width
tPCY
ns
30
tTSD
Delay to TSC valid
5
80
ns
3
31
tTSO
Delay to TSC off
5
80
ns
3, 4
32
tDXD
PCM data output delay
5
80
ns
5
33
tDXH
PCM data output hold time
5
80
ns
5
34
tDXZ
PCM data output delay to High-Z
5
80
ns
5
35
tDRS
PCM data input setup time
25
ns
36
tDRH
PCM data input hold time
5
ns
32
0.122
Max
Am79213/Am79C203/031 Data Sheet
Master Clock
For 2.048 MHz ± 100 ppm, 4.096 MHz ± 100 ppm, or 8.192 MHz ± 100 ppm operation:
Table 9. Master Clock
No.
Symbol
37
tMCY
Parameter
Min.
Typ.
Max.
Units
Note
Master clock period (2.048 MHz)
488.23
488.28
488.33
ns
2
Master clock period (4.096 MHz)
244.11
244.14
244.17
ns
Master clock period (8.192 MHz)
122.05
122.07
122.09
ns
38
tMCR
Rise time of clock
15
ns
39
tMCF
Fall time of clock
15
ns
40
tMCH
MCLK High pulse width
48
ns
41
tMCL
MCLK Low pulse width
48
ns
Notes:
1. DCLK may be stopped in the High or Low state indefinitely without loss of information.
2. The PCM clock (PCLK) frequency must be an integer multiple of the frame sync (FS) frequency with an accuracy of 800 ppm
relative to the MCLK frequency. This allowance includes any jitter that may occur between the PCM signals (FS, PCLK) and
MCLK. The actual PCLK rate is dependent on the number of channels allocated within a frame. The ASLAC device supports
2 to128 channels. The minimum clock frequency is 128 kHz. A PCLK of 1.544 MHz may be used for standard U.S. transmission
systems.
3. TSC is delayed from FS by a typical value of N • tPCY, where N is the value stored in the time/clock slot register.
4. t TSO is defined as the time at which the output driver turns off. The actual delay time is dependent on the load circuitry.
The maximum load capacitance on TSC is 150 pF and the minimum pullup resistance is 360 Ω.
5. There is special circuitry that will prevent high-power dissipation from occurring when the DXA or DXB pins of two ASLAC
devices are tied together and one ASLAC device starts to transmit before the other has gone into a high-impedance state.
6. The first data bit is enabled on the falling edge of Chip Select or on the falling edge of DCLK, whichever occurs last. If chip
select is held Low for less than eight clocks, no command or data is accepted. If chip select is held Low for more than eight
clocks, the last 8 data bits are used as command or data.
7. The ASLAC device requires 40 cycles of the 8 MHz internal clock (5 µs) between SIO operations. If the MPI is being accessed
while the MCLK (or PCLK if in combined clock mode) input is not active, a Chip Select Off time of 20 µs is required.
ASLIC/ASLAC Products
33
SWITCHING WAVEFORMS
Input and Output Waveforms for AC Tests
2.4
2.0
0.8
0.45
}
{
Test
Points
2.0
0.8
Master Clock Timing
37
41
VIH
VIL
40
38
39
34
Am79213/Am79C203/031 Data Sheet
Microprocessor Interface (Input Mode)
1
2
5
VIH
VIL
DCLK
VIL
VIH
3
7
9
4
6
CS
8
10
11
Data
Valid
Data
Valid
DIN
Data
Valid
12
Data
Valid
In/Outputs
Data
Valid
C1, C2, I/O1, I/O2, I/O3*, I/O4*
* Available on 44-pin version only
Microprocessor Interface (Output Mode)
VIH
DCLK
VIL
13
14
16
15
CS
20
18
19
17
D OUT Three-State
VOH
VOL
Data
Valid
Data Valid
Data
Valid
ASLIC/ASLAC Products
Three-State
35
PCM Highway Timing for XE = 0 (Transmit on Negative PCLK Edge)
Time Slot Zero
Clock Slot Zero
22
27
25
26
VIH
PCLK
VIL
23
24
28
29
FS
30
31
TSCA/
TSCB
See Note 4
32
33
34
VOH
DXA/DXB
First Bit
VOL
35
VIH
DRA/DRB
36
First
Bit
36
Second
Bit
VIL
Am79213/Am79C203/031 Data Sheet
PCM Highway Timing for XE = 1 (Transmit on Positive PCLK Edge)
Time Slot Zero
Clock Slot Zero
22
27
25
VIH
PCLK
26
VIL
23
24
28
29
FS
30
31
TSCA/
TSCB
See Note 4
32
33
34
VOH
DXA/DXB
First Bit
VOL
35
36
VIH
DRA/DRB
First
Bit
Second
Bit
VIL
ASLIC/ASLAC Products
37
Table 10. User-Programmable Components
Z T = 63.5 • ( Z2WIN – 2RF )
ZT is connected between the VTX and RSN pins. The fuse resistors are RF. Z2WIN is the desired 2-wire AC input impedance. When computing ZT, the internal current amplifier pole
and any external stray capacitance between VTX and RSN
must be taken into account.
ZL
254 • Z T
Z RX = ------------ • --------------------------------------------------------G 42L Z T + 63.5 • ( Z L + 2R F )
ZRX is connected from VRX to RSN. ZT is defined above, and
G42L is the desired receive gain.
Thermal Management Equations (Normal Active and Tip Open States)
RTMG is connected from TMG to VBAT and is used to reduce
power dissipation within the ASLIC device in normal Active
and Tip Open states.
V BAT – VOFF
R TMG = -----------------------------------ILOOP
Power dissipated in the thermal management resistor, RTMG,
during normal Active and Tip Open states
2
( VBAT – VOFF – ( ILOOP • R L ) )
P RTMG = ---------------------------------------------------------------------------------R TMG
2
P SLIC = V BAT • I LOOP – P RTMG – R L • ( I LOOP ) + 0.12 W
Power dissipated in the ASLIC device while in normal Active
and Tip Open states
Thermal Management equations (Polarity Reverse State)
Note: ASLIC device die temperature should not exceed 140°C.
2
P SLIC = V BAT • I LOOP – ( R L • ( I LOOP ) ) + 0.12 W
Power dissipated in the ASLIC device while in the Polarity
Reverse state
T SLIC = P SLIC • θ jA + T AMBIENT
Total die temperature
ThetajA ( θ jA ) = 43° ⁄ watt
Thermal impedance of the 32-pin plastic leaded chip carrier
package
38
Am79213/Am79C203/031 Data Sheet
ASLIC/ASLAC DEVICES LINECARD SCHEMATIC
+5 V
ASLIC
(32-/44-Pin PLCC)
ASLIC
(32-Pin PLCC)
+5 V
+5 V
VCCA VCCD
AGND
VCC GND
VREF
VREF
RSA
CDC1
SA
RFA
K1A
A
K2A
VOUT
U2
U1
+
VCC
RRX
RSN
AD
CAD
DGND
IDC
IDC
K1
RINGOUT
K2
RY1OUT
K3
RY2OUT
K4
RY3OUT
CM
DRA
R
T
TEST E
BUS S
T
C.O.
BATTERY
DXA
RM
3 U3 1
4
2
BAL1
VM
VTX
VIN
ISUM
CS +
RAB
VDC
CHP
RSB
CDIF
VREF
C5
C4
C3
RFB
K2B
BD
K1B
CBD
MCLK
DCLK
DI/O
*I/O4
*I/O3
I/O2
I/O1
C2
C2
C1
+
FS
PCLK
IDIF
VLBIAS
SB
B
*DXB
*TSCB
IAB
VLBIAS
HPB
*DRB
ISUM
IDIF
HPA
TSCA
RT
RST
C1
INT
RSVD NC
CS
QBAT
BGND
(32-/44-Pin PLCC)
IBAT
RBAT2
RBAT1
CB +
VBAT
TMG
MPI & PCM
Highway
Dual PCM Highway
RTMG
CBAT
+
RGFD1
RSR1
RSR2
RING BUS
+
Polarized
Capacitor
+
Non polarized
Capacitor
+ indicates bias
D1
IRTA
IREF
IRTB
(–) C.O.
BATTERY
RREF
*These pins are unavailable for 32-pin PLCC option.
Battery
Ground
Analog
Ground
Digital
Ground
Notes:
1. This application ckt is valid only to 2.2 V metering.
2. If the RSB sense resistor is moved so that it is exposed to the ringing voltage, see the discussion in the Line Fault
Alarm section.
Figure 7. ASLIC/ASLAC Typical Linecard Schematic
ASLIC/ASLAC Products
39
Table 11. ASLIC/ASLAC Devices Linecard Parts List
Item
Type
Value
Tol.
Rating
Comments
U1
ASLIC device
U2
ASLAC device
U3
TCM1060
D1
Diode
RFA, RFB
Resistor
50 Ω
2%
2W
RSA, RSB
Resistor
200 kΩ
2%
1/4 W
Sense resistors
RSR1, RSR2
Resistor
750 kΩ
2%
1/4 W
Matched to within 0.2% for initial tolerance and
0 to 70°C ambient temperature range.
Transient Voltage Suppressor, Texas Instruments
100 mA
100 V
1N4002
Fusible protection resistors
17 mW typ
RGFD1
Resistor
510 Ω
2%
2W
RRX*
Resistor
51.1 kΩ
1%
1/8 W
<1 mW
RT*
Resistor
51.1 kΩ
1%
1/8 W
<1mW
RBAT1, RBAT2
Resistor
365 kΩ
1%
1/8 W
<5 mW
RAB
Resistor
35.7 kΩ
1%
1/8 W
<1 mW
RREF
Resistor
7.87 kΩ
1%
1/8 W
<1 mW
RTMG *
Resistor
1600 Ω
5%
4W
Application dependent
RM*
Resistor
3.16 kΩ
1%
1/8 W
Application dependent
RTEST
Resistor
3 kΩ
1%
5W
Used only if ringing tests are required.
CDIF
Capacitor
6.8 nF
20%
5V
Ceramic
CAD, CBD *
Capacitor
22 nF
10%
100 V
Ceramic, not voltage sensitive
CBAT
Capacitor
150 nF
20%
100 V
Ceramic, VBAT Typ.
CHP
Capacitor
220 nF
20%
100 V
Ceramic, VBAT Typ.
CB
Capacitor
100 nF
20%
100 V
Ceramic, 0.5 VBAT Typ
CDC1
Capacitor
1.0 µF
20%
5V
Ceramic
CM*
Capacitor
1.8 nF
10%
5V
Ceramic
CS *
Capacitor
100 nF
20%
100 V
K1
Relay
5 V coil
≤200 mW
DPDT ring relay
K2
Relay
5 V coil
≤200 mW
DPDT (optional) line circuit test
K3, K4
Relay
5 V coil
≤200 mW
optional
1.2 W typ
Protector speed up capacitor
Note:
* Value can be adjusted to suit application.
40
Am79213/Am79C203/031 Data Sheet
PROGRAMMABLE FILTERS
General Description of CSD Coefficients
The filter functions are performed by a series of multiplications and accumulations. A multiplication is accomplished
by repeatedly shifting the multiplicand and summing the result with the previous value at that summation node. The
method used in the ASLAC device is known as Canonic Signed Digit (CSD) multiplication and splits each coefficient
into a series of CSD coefficients.
Each programmable FIR filter section has the following general transfer function:
HF ( z ) = h 0 + h 1 z
–1
+ h2 z
–2
+ … + hn z
–n
Equation (1)
where the number of taps in the filter = n + 1.
The transfer function for IIR part of Z and B filters is:
1
Hl ( Z ) = --------------------------------–1
1 – h(n + 1 )z
Equation (2)
The values of the user-defined coefficients (hi) are assigned via the MPI. Each of the coefficients (hi) is defined in
the following general equation:
hi = B1 2
–M1
+ B2 2
–M2
+ + … + BN 2
–MN
Equation (3)
where:
Mi = the number of shifts = Mi ≤ Mi + 1
Bi = sign = ±1
N = number of CSD coefficients.
The value of hi in Equation 3 represents a decimal number which is broken down into a sum of successive values of:
±1.0 multiplied by 2–0, or 2–1, or 2–2 … 2–7 …
or
±1.0 multiplied by 1, or 1/2, or 1/4 … 1/128 …
The limit on the negative powers of 2 is determined by the length of the registers in the ALU.
The coefficient hi in Equation 3 can be considered to be a value made up of N binary 1s in a binary register where
the left part represents whole numbers, the right part represents decimal fractions, and a decimal point separates
them. The first binary 1 is shifted M1 bits to the right of the decimal point; the second binary 1 is shifted M2 bits to
the right of the decimal point; the third binary 1 is shifted M3 bits to the right of the decimal point, and so on.
Note that when M1 is 0, the resulting value is a binary 1 in front of the decimal point, that is, no shift. If M2 is also 0,
the result is another binary 1 in front of the decimal point, giving a total value of binary 10 in front of the decimal point
(i.e., a decimal value of 2.0). The value of N, therefore, determines the range of values the coefficient hi can take
(e.g., if N = 3 the maximum and minimum values are ±3, and if N = 4 the values are between ±4).
Detailed Description of ASLAC Device Coefficients
The CSD coding scheme in the ASLAC device uses a value called mi, where mi represents the distance shifted right
of the decimal point for the first binary 1. m2 represents the distance shifted to the right of the previous binary 1, and
m3 represents the number of shifts to the right of the second binary 1. Note that the range of values determined by
N is unchanged. Equation 3 is now modified (in the case of N = 4) to:
hi = B1 2
hi = C1 2
hi = C1 2
–M1
–m1
+ B2 2
–M2
+ C1 C2 2
–m1 ì
í 1 + C2 2
î
+ B3 2
–M3
–( m1 + m 2 )
–m 2
+ B4 2
–M4
+ C1 C 2 C 3 2
[ 1 + C3 2
–m 3
Equation (4)
–( m1 + m 2 + m 3 )
( 1 + C4 2
–m 4
+ C1 C2 C3 C4 2
– ( m 1 + m2 + m3 + m 4 )
ü
)] ý
þ
ASLIC/ASLAC Products
Equation (5)
Equation (6)
41
where:
M1 = m1
B1 = C1
M2 = m1+m2
B2 = C1 • C2
M3 = m1+m2+m3
B3 = C1 • C2 • C3
M4 = m1+m2+m3+m4
B4 = C1 • C2 • C3 • C4
In the ASLAC device, a coefficient, hi, consists of N CSD coefficients, each being made up of 4 bits and formatted
as Cxymxy, where Cxy is one bit (MSB) and mxy is 3 bits. Each CSD coefficient is broken down as follows:
Cxy
is the sign bit (0 = positive, 1 = negative).
mxy
is the 3-bit shift code. It is encoded as a binary number as follows:
000:
0 shifts
001:
1 shifts
010:
2 shifts
011:
3 shifts
100:
4 shifts
101:
5 shifts
110:
6 shifts
111:
7 shifts
y
is the coefficient number (the i in hi).
x is the position of this CSD coefficient within the hi coefficient. The most significant binary 1 is represented by x = 1.
The next most significant binary 1 is represented by x = 2, and so on.
Thus, C13m13 represents the sign and the relative shift position for the first (most significant) binary 1 in the 4th (h3)
coefficient.
The number of CSD coefficients, N, is limited to 4 in the GR, GX, R, X, Z, and the IIR part of the B filter, and 3 for
the FIR part of the B filter. Note also that the GX-filter coefficient equation is slightly different from the other filters.
Equation (7)
h iGX = 1 + h i
Please refer to the Am79213/Am79C203/031 Technical Reference, PID 21325A detailing the commands for complete
details on programming the coefficients.
42
Am79213/Am79C203/031 Data Sheet
PHYSICAL DIMENSION
PL032
.485
.495
.447
.453
.009
.015
.585
.595
.042
.056
.125
.140
Pin 1 I.D.
.080
.095
.547
.553
SEATING
PLANE
.400
REF.
.490
.530
.013
.021
.050 REF.
.026
.032
TOP VIEW
16-038FPO-5
PL 032
DA79
6-28-94 ae
SIDE VIEW
PL044
.685
.695
.650
.656
.062
.083
.042
.056
Pin 1 I.D.
.685
.695
.650
.656
.500 .590
REF .630
.013
.021
.026
.032
.050 REF
.009
.015
.090
.120
.165
.180
TOP VIEW
SEATING PLANE
SIDE VIEW
ASLIC/ASLAC Products
16-038-SQ
PL 044
DA78
6-28-94 ae
43
REVISION SUMMARY
Revision A to Revision B
•
Fixed the figure numbering.
•
Minor changes were made to the data sheet style and format to conform to Legerity standards.
Revision B to Revision C
•
The physical dimension (PL032 and PL044) was added to the Physical Dimension section.
•
Updated the Pin Description table to correct inconsistencies.
•
Minor changes were made to the data sheet style and format to conform to Legerity standards.
Revision C to Revision D
•
44
Page 26, Attenuation Distortion, The sentence “The attenuation of the signal in either path is nominally independent of the frequency” was deleted.
Am79213/Am79C203/031 Data Sheet
Notes:
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Notes:
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