Agere LUCL8576BP-D Dual ringing slic Datasheet

Data Sheet
May 2001
L8576B Dual Ringing SLIC
Features
Applications
■
Two SLIC channels for multiple tip/ring interfaces
■
POTS for ISDN
■
On-chip balanced ringing generator, no ring relay
required
■
Terminal adapters (TA)
■
Digital loop carrier (DLC) systems
■
Single battery operation or optional automatic battery switch
■
PABX
■
Quiet battery reversal for on-hook signaling
■
Disconnect state
■
Distortion-free, on-hook transmission
■
24 mA loop current limiter
■
Ring trip detector
■
Switchhook detector
■
Immune to channel crosstalk and impulse noise
■
Allows rail overvoltages for ease of protection
■
Thermal protection
■
44-pin, surface-mount, plastic package (PLCC)
Description
The Agere Systems Inc. L8576B electronic dual subscriber line interface circuit (SLIC) provides all the
functions that are necessary to interface a codec to
the tip and ring of a subscriber loop, integrating two
battery feeds and ringing generators in one low-cost
package. The L8576B device is optimized to meet
the needs of short loop, customer premises applications and features balanced ringing from the single
battery supply. The device is built using a 90 V complementary bipolar (CBIC) process. It is available in a
44-pin PLCC package.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Table of Contents
Contents
Page
Features ......................................................................1
Applications .................................................................1
Description...................................................................1
Pin Information ............................................................5
Functional Description .................................................7
General .....................................................................7
Protection..................................................................7
Tip/Ring Drivers ........................................................7
Battery Operation......................................................7
Transmit and Receive Interface ................................7
Data Interface ...........................................................8
Loop Current Detector ..............................................8
Operating States..........................................................8
Absolute Maximum Ratings ........................................9
Electrical Characteristics ...........................................10
Test Configurations .................................................. 14
Applications ..............................................................15
Characteristic Curves..............................................15
dc Design ................................................................17
Power Ringing.........................................................18
ac Design ................................................................19
Use of an Auxiliary Battery Supply..........................24
Outline Diagram ........................................................25
44-Pin PLCC ...........................................................25
Ordering Information .................................................26
Tables
Page
Table 1. Pin Descriptions ............................................5
Table 2. Input State Coding ........................................9
Table 3. Operating Conditions and Powering ...........10
Table 4. Ring Trip Detector ......................................10
Table 5. Battery Feed ...............................................11
Table 6. Analog Signal Pins .....................................12
Table 7. ac Feed Characteristics ..............................12
Table 8. Isolation Between Channels .......................13
Table 9. Data Interface and Logic ............................13
2
Figures
Page
Figure 1. Architectural Diagram ................................. 3
Figure 2. Typical 600 Ω Application Circuit (Only
One Channel Shown) ................................. 4
Figure 3. 44-Pin PLCC Pin Diagram .......................... 5
Figure 4. Pretrip Circuit ............................................ 11
Figure 5. Basic Test Circuit ..................................... 14
Figure 6. Metallic PSRR .......................................... 14
Figure 7. Longitudinal PSRR ................................... 14
Figure 8. Longitudinal Balance ................................ 15
Figure 9. Longitudinal Impedance ........................... 15
Figure 10. ac Gains ................................................. 15
Figure 11. Receive Gain and Hybrid Balance vs.
Frequency .............................................. 15
Figure 12. Transmit Gain and Return Loss vs.
Frequency .............................................. 15
Figure 13. Loop Current vs. Loop Voltage ............... 16
Figure 14. Loop Current vs. Loop Resistance ......... 16
Figure 15. SLIC Power Dissipation vs. Loop
Resistance (VBAT = –48 V) ...................... 16
Figure 16. SLIC Power Dissipation vs. Loop
Resistance (VBAT = –65 V) ...................... 16
Figure 17. Loop Current vs. Loop Voltage ............... 17
Figure 18. Ringing Waveform Crest Factor = 1.6 .... 18
Figure 19. Ringing Waveform Crest Factor = 1.2 .... 18
Figure 20. ac Equivalent Circuit Using a T8503
Codec ..................................................... 20
Figure 21. ac Interface Circuit Using FirstGeneration Codec (Blocking Capacitors
Not Shown) ............................................. 22
Figure 22. ac Interface Circuit Using FirstGeneration Codec (Including Blocking
Capacitors) ............................................. 23
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
CF2
CF1
AGND
VCC
BGND
VBAT
Description (continued)
POWER CONDITIONING & REFERENCE
RTTH
RING
TRIP
RTFLT
RECTIFIER
DCOUT
ac
CONDITIONING
VITR
AX
TG1
TG2
PT
–
A=6
+
X1
RCVN
RCVP
B2
PR
–X1
BATTERY FEED
STATE CONTROL
RNGNG
NDISC
VCC
RPWR
VCC
IPROG
CURRENT-LIMIT
CIRCUIT
DCOUT
LOOP CLOSURE
DETECTOR
+
–
NSTAT
12-3362(F).c
Figure 1. Architectural Diagram
Agere Systems Inc.
3
Data Sheet
May 2001
L8576B Dual Ringing SLIC
B2a
VBAT
NDISCa
RNGNGa
Description (continued)
RDCT*
300 kΩ
VCC VBAT
RPWRa
2.2 kΩ
5%,
2W
CVCC
0.1 µF
10 V
CF1a, 0.22 µF, 100 V
10% POLYESTER
43
40 38 41
24 1 37
RGX1a RGX2a
16.9 kΩ 7.5 kΩ
32 TG1
CTG1a
470 pF
10 V
CBa
0.33 µF
10 V
33 TG2
GAIN = 125 V/A
CF2a, 0.22 µF, 100 V
10% POLYESTER
44
ac
CONDITIONER
+
AX
–
1/2 L8576
SLIC
34
VITRa
RECTIFIER
TIP
RPT1a
30
PTa
X1
36
8
1
CH 0
7
2
6 L7591 3 VBAT
5
4
FGND
PRa
35
RING
+
–
–X1
VCCa
75 µA
(130 µA
RINGING)
DCOUTa 29
CPROGa
0.056 µF
50 V
RRCVa
143 kΩ
CC1A
0.1 µF
10 V
–
+
RHBa
309 kΩ
CC2a
33 nF
10 V
RGNa
27.4 kΩ
19 GSX1
VFXIN1
20
+2.4 V
VFRO1
17
RGa
27.4 kΩ
RPR1a
30
RPROGa
51.1 kΩ
RT2a
40.2 kΩ
RCVNa
26
VCC
TO DTMF
RECEIVER
RXa
154 kΩ
RT1a
41.2 kΩ
27
RCVPa
+
–
A=6
CVBATa
0.1 µF
100 V
RGX3a
10 kΩ
LCTHa
23
1/2 T8503
CODEC
RRNG
28.7 kΩ
GNDA1 18
RRNG
NSTATa
39
+
–
NSTATa
VDD
VCC
+5 V
VBAT
–65 V
6
DX
11
DR
12
MCLK
9
FSX1
13
VDD
DX
DR
MCLK
FS0
FSR1
14
10 DGND
IPROGa 28
30 RTTHa
31 RTFLTa
25
42
BGNDa
RDCR*
300 kΩ
RTTHa
52.3 kΩ
VBAT
RTFLTa
383 kΩ
CRTa
0.1 µF
50 V
AGNDa
AGND
BGND
DGND
FGND
GND
5-8414a (F)
* RDCT and RDCR (optional) are only required to keep the NSTAT output at a steady state during the disconnect state.
Notes:
TX = –2 dB.
RX = –4 dB.
Termination = 600 Ω.
Hybrid balance = 600 Ω.
Ring trip optimized for 20 Hz.
Figure 2. Typical 600 Ω Application Circuit (Only One Channel Shown)
4
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
RNGNGb
B2b
BGNDb
CF1b
CF2b
VBAT
CF2a
CF1a
BGNDa
B2a
RNGNGa
Pin Information
6
5
4
3
2
1
44
43
42
41
40
RPWRa
PTb
10
36
PTa
PRb
11
35
PRa
VITRb
12
34
VITRa
TG2b
13
33
TG2a
TG1b
14
32
TG1a
RTFLTb
15
31
RTFLTa
RTTHb
16
30
RTTHa
DCOUTb
17
29
DCOUTa
18
19
20
21
22
23
24
25
26
27
28
IPROGa
37
RCVPa
9
RCVNa
RPWRb
AGNDa
NDISCa
VCCa
38
RRNG
8
VCCb
NDISCb
AGNDb
NSTATa
RCVNb
39
RCVPb
7
IPROGb
NSTATb
12-3361(F).a
Figure 3. 44-Pin PLCC Pin Diagram
Table 1. Pin Descriptions
Pin,
Pin,
Circuit Circuit Symbol Type
a
b
1
44
43
42
41
1
2
3
4
5
VBAT*
CF2
CF1
BGND*
B2
—
—
—
—
Iu
Name/Function
Office Battery Supply. Negative high-voltage power supply, nominally –65 V.
Filter Capacitor 2. Connect 0.22 µF capacitor to AGND.
Filter Capacitor 1. Connect 0.22 µF capacitor to AGND.
Battery Ground. Ground return for the battery supply and fault ground.
State Input. Refer to Operating States section. A pull-up device is included.
* On the printed-wiring board (PWB), make the leads to BGND and VBAT as wide as possible for thermal and electrical reasons. Also, maximize the amount of PWB copper on all leads connected to this device for the lowest operating temperature.
Note: Iu and Ou indicate a pull-up device is included on this lead.
Agere Systems Inc.
5
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Pin Information (continued)
Table 1. Pin Descriptions (continued)
Pin,
Pin,
Circuit Circuit Symbol Type
a
b
40
6
RNGNG
Iu
39
7
NSTAT
Ou
38
8
NDISC
Iu
37
9
RPWR
—
36
10
PT
I/O
35
11
PR
I/O
34
12
VITR
O
33
13
TG2
—
32
14
TG1
—
31
15
RTFLT
—
30
16
RTTH
—
29
17
DCOUT
O
28
18
IPROG
I
27
19
RCVP
I
26
20
RCVN
I
25
24
23
21
22
23
AGND
VCC
RRNG
—
—
—
Name/Function
Ringing Input. Refer to Operating States section. A pull-up device is
included.
Loop Detector Output/Ring Trip Detector Output. When low, this lead indicates an off-hook condition. When in ringing mode, a low output on this lead
indicates a ring trip. A pull-up device is included.
Disconnect Input. Refer to Operating States section. A pull-up device is
included.
Power Resistor. Connect a resistor between this pin and VBAT. A 2.2 kΩ, 2 W
resistor should be used for a VBAT of –68.5 V. See the Applications section to
calculate resistor values for other VBAT potentials.
Protected Tip. The input to the tip fault protection and output of tip current
drive amplifier. Connect this pin to the tip of the loop through a 30 Ω overvoltage protection resistor.
Protected Ring. The input to the ring fault protection and output of ring current drive amplifier. Connect this pin to the ring of the loop through a 30 Ω
overvoltage protection resistor.
Transmit ac Output Voltage. This output is a voltage that is directly proportional to the differential tip/ring current.
Transmit Gain 2. Transmit gain and current limiting for ringing is set by the
value of RGX2. RGX2 is connected between TG2 and VITR.
Transmit Gain 1. Transmit gain is set by the series resistor combination of
RGX1 and RGX2 from this lead to TG2.
Ring Trip Filter. Connect this lead to RTTH via a resistor and to AGND with a
capacitor to filter the ring trip circuit to prevent spurious responses.
Ring Trip Threshold. Connect this lead to DCOUT via a resistor to set the ring
trip threshold.
dc Voltage Out. This output is a voltage that is directly proportional to the
absolute value of the differential tip/ring current.
Current-Limit Program Input. A resistor to DCOUT sets the dc current limit of
the circuit.
Receive Signal Input (+). This high-impedance input controls the ac differential voltage on tip/ring.
Receive Signal Input (–). This high-impedance input controls the ac differential voltage on tip/ring.
Analog Signal Ground.
Analog 5 V Power Supply.
Ringing Slope Resistor. Connect this lead to AGND with a resistor to set the
slope of the ringing waveform. Note that this pin is shared with both sections.
* On the printed-wiring board (PWB), make the leads to BGND and VBAT as wide as possible for thermal and electrical reasons. Also, maximize the amount of PWB copper on all leads connected to this device for the lowest operating temperature.
Note: Iu and Ou indicate a pull-up device is included on this lead.
6
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Functional Description
Tip/Ring Drivers
Refer to the architectural and application diagrams
(Figures 1 and 2, respectively).
The L8576B has two tip/ring drivers whose outputs are
PT and PR. Each driver operates as a current source
capable of sinking or sourcing adequate ac signal bias
current. In the normal talk operating mode, these drivers are current-limited at a nominal 24 mA to minimize
the power dissipation of short loops. These amplifiers
are also used to drive balanced ringing. During ringing,
the current limit is raised to approximately 85 mA.
General
The L8576B is a dual subscriber line interface circuit
with each half of the device providing battery feed,
supervision, and balanced ringing. It is designed to
support short loops, typically on customer premises.
The use of a single battery for both battery feed and
ringing makes this device particularly advantageous
where it is desirable to minimize power supply costs in
small systems, such as terminal adapters. The tip and
ring drive amplifiers are used with a very relaxed current limit to develop a trapezoidal, balanced ringing signal. Use of a nominal –65 V power supply allows for
ringing of normal phones, whether equipped with a
mechanical ringer, or a peak-detection type of ringing
detector. While balanced ringing is not the norm worldwide, its use in short, customer premises loops is gaining popularity.
In addition to the ringing and battery functions, the
L8576B device provides the ac receive and transmit
paths. Also, integral within the device is an off-hook
detection circuit and a ring trip detection circuit that
have their outputs multiplexed on a single lead.
Thermal protection within the device is also provided,
and an external resistor is used to drop the high battery
voltage before applying loop current, thus allowing a
significant portion of the power to be dissipated outside
of the device. Removing much of this power makes it
possible to incorporate two complete circuits in a
44-pin, surface-mount package.
Protection
The L8576B contains some overvoltage protection in
addition to the thermal protection within the device.
This protection, along with the associated tip and ring
protection resistors, may be sufficient in some benign
environments. However, if power line cross or lightning
protection is desired, the use of an external protection
circuit (such as the L7591 device from Agere) is highly
recommended.
The integrated thermal protection consists of a thermal
shutdown circuit which places the tip/ring drivers in a
high-impedance state when the temperature of the die
exceeds 160 °C. In thermal shutdown, all supervision
states are undefined.
Agere Systems Inc.
The external resistor connected to the RPWR pin is used
to dissipate power externally and also to drop the battery voltage which is higher than normal in order to
support balanced ringing. Note that this external power
dissipation is present during both ringing or normal battery feed operation. Power limitations restrict the dual
device to actively ringing only one channel at a time;
thus, ringing cadence must be used to ensure that only
one channel is actively ringing at any given instant of
time. In other words, to ring both channels at the same
time, ring each channel during the quiet interval of the
other channel.
Battery Operation
There are two VBAT inputs to the device. Pin 1 (VBAT)
provides voltage to the entire SLIC and pins 9 and 37
(RPWR) provide voltage to the individual tip and ring
amplifiers of each channel through RPWR resistors. A
shared current sourcing scheme is employed within the
device. For loop currents below 20 mA, the V BAT
applied to pin 1 sources all of the loop current in addition to driving internal circuitry. For loop currents
greater than 20 mA, loop current is primarily provided
through the RPWR resistors and the pin 1 VBAT mainly
powers internal circuitry. The RPWR resistors can be
replaced by a lower-voltage auxiliary battery. Operation
with an auxiliary battery is described in the Applications
section of this document.
Transmit and Receive Interface
The interface is suitable for direct coupling to a ±5 V
only codec. When interfacing a 5 V only codec, coupling capacitors are required.
The transmit interface circuitry couples the differential
voltage on tip and ring to transmit output VITR. The
inverting input of the driving amplifier is available on
lead TG1, so connecting a resistance between VITR
and TG1 allows adjustment of the transmit gain
(transconductance).
7
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Functional Description (continued)
Operating States
Transmit and Receive Interface (continued)
The L8576B device has four operating states:
■
Talk state—normal battery:
— Normal talk state.
— Battery feed is connected to the battery supply
(VBAT).
— Both receive and transmit transmission paths are
powered up.
— dc loop and instantaneous current limiters are
powered up and active.
— NSTAT reflects the status of the switchhook
detector.
— PR is negative with respect to PT.
■
Talk state—reverse battery:
— Normal talk state.
— Battery feed is connected to the battery supply
(VBAT).
— Both receive and transmit transmission paths are
powered up.
— dc loop current limiter is powered up and active.
— NSTAT reflects the status of the switchhook
detector.
— PR is positive with respect to PT.
■
Ringing state:
— Normal ringing state.
— Both receive and transmit transmission paths are
inactive.
— Balanced ringing is applied to PR and PT, in
accordance with B2.
— Current limiter is set for ringing limit.
— NSTAT reflects the status of the ring trip detector.
— Only one channel should be in this state at a time
to control power dissipation.
■
Disconnect state:
— Tip and ring drive amplifiers are powered down.
— Pins PT and PR are high impedance (>100 kΩ).
— NSTAT is undefined.
— PT and PR voltage is undefined.
A second gain setting is provided to accommodate ring
trip. A switch is built into TG2. In ringing mode, TG1
and TG2 are internally connected, thus shorting out the
external gain resistor RGX1. This provides a lower transmit gain for ringing since ring trip is accomplished by
monitoring the voltage at DCOUT. This lower gain sets
DCOUT at the appropriate level to accommodate the
higher currents of the ring trip.
The receive interface circuitry couples the differential
signal on receive inputs RCVP and RCVN to the
tip/ring drivers.
Data Interface
A 4-wire parallel interface (B2, RNGNG, NDISC, and
NSTAT) is provided for each channel to control signals
to and from the system controller. B2 controls the forward/reverse battery in normal talk mode while
RNGNG enables the balanced ringing mode of operation, and NDISC performs a disconnect state. NSTAT
reflects either the loop detector output or the ring trip
detector output, depending on the mode of the section.
It is the responsibility of the system controller to recognize ring trip detection and set RNGNG to a logic 0
state to terminate ringing. The system controller should
also use RNGNG to set ringing cadence.
Loop Current Detector
Each section of the device has an integral loop current
detector set at a nominal 12 mA of dc current. This is
used to detect off-hook transitions in the normal talk
state. When current less than the current threshold
(including no current) is flowing, NSTAT is at logic 1.
When loop current exceeds 12 mA, the output NSTAT
switches to a logic 0. No hysteresis is included.
8
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Operating States (continued)
These states are selected using three logic inputs, B2, RNGNG, and NDISC. B2 sets normal operation, either with
forward or reverse battery. RNGNG overrides B2 and applies ringing with the polarity of tip and ring reversed on
edges of the B2 signal. The slope of the waveform is determined by a resistor from RRNG to AGND. Logic input
NDISC puts the device into a loop current denial state (disconnect). Tip and ring amplifiers are saturated against
ground with about a 100 µA current source. This creates a level in the loop current sensing circuitry that
approaches a loop closed state. Some conditions on the tip and ring could cause the circuit to indicate loop closed
even though the loop is open. This situation can be prevented by connecting a 300 k Ω resistor from VBAT to each of
the outputs of the tip and ring amplifiers (see Figure 2). This will pull the amplifier output to about 30 V above VBAT,
keeping the NSTAT output at a steady high (on-hook indication) level. If the disconnect state is not used or the
NSTAT output during the disconnect state is not recognized or used, then the resistors are not needed.
Table 2 below summarizes the operating input state coding.
Table 2. Input State Coding
NDISC RNGNG B2
1
1
1
0
0
1
1
1
0
0/1
State
1 Forward Battery, Normal Talk, and Feed State. Pin PT is positive with respect to PR.
0 Reverse Battery, Normal Talk, and Feed State. Pin PT is negative with respect to PR.
1 ↑ Ringing Is Applied to PT and PR. On the transition, PT starts towards a positive voltage (with respect to PR). The endpoint of this state is PT at BGND and PR at VBAT.
0 ↓ Ringing Is Applied to PT and PR. On the transition, PT starts towards a negative voltage (with respect to PR). The endpoint of this state is PT at VBAT and PR at BGND.
0/1 Disconnect State. The tip and ring amplifiers are turned off, and the SLIC goes into a
high-impedance state (>100 kΩ).
Absolute Maximum Ratings (at TA = 25 °C)
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 the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect device reliability.
Parameter
Symbol
Min
Typ
Max
Unit
5 V dc Supplies
Office Battery Supply
Logic Input Voltage
Logic Input Clamp Diode Current, per Pin
Logic Output Voltage
Logic Output Current, per Pin
Analog Input Voltage
Maximum Junction Temperature
Storage Temperature Range
Relative Humidity Range (noncondensing)
Ground Potential Difference (BGND to AGND)
PT or PR Fault Voltage (dc)
PT or PR Fault Voltage (10 µs x 1000 µs)
VCC
VBAT
—
—
—
—
—
—
Tstg
—
—
—
—
–0.5
–75
–0.5
—
–0.5
—
–7.0
—
–40
5
—
VBAT – 5
VBAT – 15
—
—
—
±20
—
±35
—
165
—
—
±3
—
—
7.0
0.5
VCC + 0.5
—
VCC + 0.5
—
7.0
—
125
95
—
3
15
V
V
V
mA
V
mA
V
°C
°C
%
V
V
V
Note: The IC can be damaged unless all ground connections are applied before, and removed after, all other connections. Furthermore, when
powering the device, the user must guarantee that no external potential creates a voltage on any pin of the device that exceeds its ratings. For example, inductance in a supply lead could resonate with the supply filter capacitor to cause a destructive overvoltage.
Agere Systems Inc.
9
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Electrical Characteristics
Generally, minimum and maximum values are testing requirements. However, some parameters may not be tested
in production because they are guaranteed by design and device characterization. Typical values reflect the design
center or nominal value of the parameter; they are for information only and are not a requirement. Minimum and
maximum values apply across the entire temperature range (0 °C to 70 °C) and entire battery range (to –72 V).
Unless otherwise specified, typical values are defined as 20 °C, VCC = 5.0 V, VBAT = –68.5 V. Positive currents flow
into the device.
Table 3. Operating Conditions and Powering
Parameter
Temperature Range
Humidity Range
Supply Voltages:
VCC
VBAT
Loop Closure Threshold—Detection Range
ac Termination Impedance Programming Range
On- and Off-hook 2-wire Signal Level
Power Supply—Powerup, No Loop Current (per section):
ICC
IBAT (VBAT = –65 V)
Total power (one channel, VBAT = –65 V)
Power-supply Rejection (See Figures 6 and 7.):
VCC (1 kHz)
VBAT (500 Hz—3 kHz)
Thermal4:
Thermal Resistance (still air) Tj
Operating Tj
Thermal Shutdown Temperature
1.
2.
3.
4.
Min
Typ
Max
Unit
0
5
—
—
70
951
°C
%RH
4.75
–242
9.5
300
—
5.0
–65
12
600
3.14
5.25
–72
14.5
10003
—
V
V
mA
Ω
dBm
—
—
—
4.5
3.0
230
5.5
4.0
290
mA
mA
mW
35
45
—
—
—
—
dB
dB
—
—
—
47
—
160
—
150
—
°C/W
°C
°C
Noncondensing.
The L8576B will operate below –24 V; –24 V is used for production test.
The termination impedance can be programmed up to 1200 Ω; 1000 Ω are used for production test.
This parameter is not tested in production. It is guaranteed by design and device characterization.
Table 4. Ring Trip Detector1
Parameter2
Ringing Source:
Frequency (ƒ) RRNG = 28.7 kΩ, RTTH = 52.3 kΩ
Frequency (ƒ) Contact Agere for Specific Component Values
C-message Weighted Noise (900 Ω)
REN Load (1386 Ω + 40 µF) with Loop Resistance = 30 Ω, RPT = 30 Ω, RPR = 30 Ω
Detection Interval:
20 Hz
≥25 Hz
Min Typ
Max
Unit
17
20
—
—
20
—
—
—
23
50
90
40
Hz
Hz
dBrnC
Vrms
—
—
—
—
200
150
ms
ms
1. This table is provided for information purposes only.
2. These parameters are not tested in production.
10
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Electrical Characteristics (continued)
Pretrip will not occur for the circuits shown below, per GR-909, 4.5.9.
200 Ω
TIP
RING
SWITCH CLOSES FOR LESS THAN 12 ms
6 µF
TIP
RING
10 kΩ
12-2572(F).d
Figure 4. Pretrip Circuit
Table 5. Battery Feed
Parameter
Min
Typ
Max
Unit
—
15
—
—
Ω
mArms
24
60
—
—
—
28
70
—
—
—
mA
mA
mA
mArms
V
—
—
60
1
—
70
mA
kΩ
Ω
67
62
—
—
dB
dB
—
—
dB
1
Loop Resistance Range
(3.17 dBm overload into 600 Ω):
1000
ILOOP = 20 mA at VBAT = –65 V
8.5
Longitudinal Current Capability per Wire2
3 RLOOP = 100
Current Limit
Ω:
20
dc Loop
50
Instantaneous 4
Tip or Ring Drive Current = dc + Longitudinal + Signal Currents
65
Signal Current
5
|VBAT + 10|
Powerup Open Loop Voltage Level
Differential Voltage (RNGNG = 0, NDISC = 1, B2 = 1,
VBAT = –65 V)
Disconnect State:
–1
PT or PR Current (VBAT < VPT < 0 V)
100
PT or PR Resistance (VBAT < VPT < 0 V)
dc Feed Resistance
—
5
6
Longitudinal to Metallic Balance—IEEE Standard 455 :
200 Hz to 1 kHz
54
1 kHz to 3 kHz
48
Metallic to Longitudinal (Harm) Balance7:
200 Hz to 4 kHz
35
1. Assumes 2 x 30 Ω external protection resistors. Note the useful range of the device may be determined by the ringing or supervision range
rather than the ac characteristics.
2. The longitudinal current is independent of dc loop current.
3. Current limit ILIM is programmed by a resistor, RPROG, from pin IPROG to pin DCOUT RPROG (kΩ) = 3.5 x (ILIM – 9.2) mA. The current limit has a
slope vs. loop voltage of 6 kΩ. To control power dissipation, it is recommended that the default current limits be utilized, i.e., RPROG = 51.1 kΩ
for 24 mA nominal loop current limit.
4. Instantaneous current limit minimizes inrush current at the onset of an off-hook condition. Inrush current is only limited when in the forward
battery state. The device will settle into a dc loop current-limit value within 400 ms after off-hook.
5. IEEE is a registered trademark of The Institute of Electrical and Electronics Engineers, Inc.
6. Assumes the external protection resistors are matched to 1%.
7. This parameter is not tested during production. It is guaranteed by design and device characterization.
Agere Systems Inc.
11
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Electrical Characteristics (continued)
Table 6. Analog Signal Pins
Parameter
Differential PT/PR Current Sense (DCOUT)
Gain (PT/PR to DCOUT):
Forward Battery (RGX1 = 16.9 kΩ, RGX2 = 7.5 kΩ)
Reverse Battery (RGX1 = 16.9 kΩ, RGX2 = 7.5 kΩ)
PT/PR to VITR Gain with
RGX1 = 16.9 kΩ, RGX2 = 7.5 kΩ:
Forward Battery
Reverse Battery
Loop Closure Detector Threshold:
Programming Accuracy
RCVN, RCVP:
Input Bias Current
Gain RCVP to PT/PR
Gain RCVN to PT/PR
RCVN, RCVP Input Compliance
Min
Typ
Max
Unit
–235
235
–250
250
–265
265
V/A
V/A
–121
121
–125
125
–129
129
V/A
V/A
—
—
±20
%
—
11.62
–11.62
–2.5
—
12
–12
—
–1.0
12.38
–12.38
VCC
µA
—
—
V
Min
Typ
Max
Unit
300
600
1000
Ω
—
—
—
—
0.3
1.0
%
%
–3.0
–0.24
0
0
3.0
0.24
%
dB
–3.0
–0.24
—
0
0
—
3.0
0.24
3.14
%
dB
dBm
–1.00
–0.30
–3.0
—
0
0
–0.1
—
0.05
0.05
2.0
2.0
dB
dB
dB
dB
Table 7. ac Feed Characteristics
Parameter1
ac Termination Impedance2
Total Harmonic Distortion (200 Hz—4 kHz)3:
Off-hook
On-hook
Transmit Gain (ƒ = 1 kHz) (See Figure 5.):
Transmit Accuracy in Percent
Transmit Accuracy in dB (relative to 2/3)
Receive Gain (ƒ = 1 kHz) (See Figure 5.):
Receive Accuracy in Percent
Receive Accuracy in dB
Tip/Ring Signal Level (600 Ω reference)
Gain vs. Frequency (transmit and receive; 1 kHz reference)3:
200 Hz—3.4 kHz
300 Hz—3.4 kHz
3.4 kHz—20 kHz
3.4 kHz—266 kHz
1. Requires external components connected as shown in the Applications section. Transmission characteristics are specified assuming a 600 Ω
resistive termination and ±1% external resistors.
2. Transmission characteristics are specified assuming a 600 Ω resistive termination; however, feedback using external components allows the
user to adjust the termination impedance from 600 Ω. Any complex impedance R1 + R2 || C between 300 Ω and 1000 Ω can be synthesized
using external components.
3. This parameter is not tested in production. It is guaranteed by design and device characterization.
12
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Electrical Characteristics (continued)
Table 7. ac Feed Characteristics (continued)
Parameter1
Gain vs. Level (transmit and receive; 0 dBV reference)2:
–50 dB to +3 dB
Return Loss3:
200 Hz—500 Hz
500 Hz—3400 Hz
Transhybrid Loss3:
200 Hz—500 Hz
500 Hz—2500 Hz
2500 Hz—3400 Hz
Idle-channel Noise (Tip/Ring):
Psophometric2
C-message
3 kHz Flat2
Idle-channel Noise (XMT):
Psophometric2
C-message
3 kHz Flat2
Min
Typ
Max
Unit
–0.05
0
0.05
dB
20
26
24
29
—
—
dB
dB
20
26
26
24
29
29
—
—
—
dB
dB
dB
—
—
—
—
—
—
–77
12
20
dBmp
dBrnC
dBrn
—
—
—
—
—
—
–77
12
20
dBmp0
dBrnC0
dBrn0
1. Requires external components connected as shown in Figure 2. Transmission characteristics are specified assuming a 600 Ω resistive termination and ±1% external resistors.
2. This parameter is not tested in production. It is guaranteed by design and device characterization.
3. Return loss and transhybrid loss are functions of device gain accuracies and the external hybrid circuit. Guaranteed performance assumes
1% tolerance components.
Table 8. Isolation Between Channels
Parameter1
Min
Typ
Max
Unit
Interchannel Small-signal Crosstalk. (Both channels in forward or reverse
battery state.) (2-wire to 2-wire, 2-wire to 4-wire, 4-wire to 4-wire.)
Impulse Noise. (One channel ringing, other channel in forward or reverse
battery state.)
—
–90
–80
dB
—
40
47
dBrnC0
1. These parameters are not tested in production. They are guaranteed by design and device characterization.
Table 9. Data Interface and Logic
Parameter1
Symbol
Min
Typ
Max
Unit
High-level Input Voltage (B2, RNGNG, and NDISC)
Low-level Input Voltage (B2, RNGNG, and NDISC)
Input Bias Current (high) (B2, RNGNG, and NDISC)
Input Bias Current (low) (B2, RNGNG, and NDISC)
High-level Output Voltage (NSTAT, open collector with internal pull-up resistor):
(IOUT = –20 µA)
(IOUT = –1 µA)
Low-level Output Voltage (NSTAT, open collector with internal
pull-up resistor) (IOUT = 200 µA)
VIH
VIL
IIH
IIL
2
0
–40
–75
—
—
—
—
VCC
0.7
–100
–200
V
V
µA
µA
VOH
VOH
VOL
2.4
—
0
4.3
5.0
0.2
VCC
—
0.4
V
V
V
1. All logic voltages are referenced to AGND.
Agere Systems Inc.
13
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Test Configurations
VBAT
VCC
0.1 µF
0.1 µF
VBAT
TIP
BGND VCC
RPT
25 Ω
RPR
25 Ω
RGX3
10 kΩ
CTG
100 pF
RGX2
RGX1
TG1
PT
RLOOP
600 Ω
AGND
16.9 kΩ 7.5 kΩ
TG2
0.22 µF
VITR
XMT
RT1
127 kΩ
PR
RING
L8576
DCOUT
RCVP
RRCV
442 kΩ
RCVN
RG
88.7 kΩ
RCV
SLIC
RPROG
51.1 kΩ
IPROG
RTTH
52.3 kΩ
RTFLT
383 kΩ
RTTH
RTFLT
RNGNG
RPWR
VBAT
0.056 µF
B2
RPWR
NSTAT
2.2 kΩ
0.1 µF
CF1
RRNG
RRNG
28.7 kΩ
CF1
0.22 µF
CF2
CF2
0.22 µF
12-3360(F)a
Figure 5. Basic Test Circuit
V BAT OR VCC
100 Ω
V BAT OR VCC
100 Ω
4.7 µF
DISCONNECT
BYPASS CAPACITOR
4.7 µF
VS
VS
VBAT OR
VCC
V BAT OR
VCC
67.5 Ω
PT
PT
+
900 Ω
VT/R
–
DISCONNECT
BYPASS CAPACITOR
10 µF
BASIC
TEST CIRCUIT
+
VM
–
PR
PSRR = 20log
VS
VT/R
BASIC
TEST CIRCUIT
67.5 Ω
56.3 Ω
10 µF
PR
PSRR = 20log
VS
VM
12-2583a(F)
12-2582a(F)
Figure 6. Metallic PSRR
14
Figure 7. Longitudinal PSRR
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Test Configurations (continued)
Applications
Characteristic Curves
100 µF
Figures 11—16 display typical room temperature readings.
TIP
VS
365 Ω
+
BASIC
TEST CIRCUIT
VM
365 Ω
–
0
RING
VS
LONGITUDINAL BALANCE = 20log ------VM
12-2584(F)b
Figure 8. Longitudinal Balance
DECIBELS (dB)
100 µF
RECEIVE GAIN
–10
–20
HYBRID BALANCE
–30
–40
–50
–60
0.1k
ILONG
10k
1k
FREQUENCY (Hz)
PT
+
12-3507(F)
VPT
–
Note: Gain is normalized to 0 dB.
BASIC
TEST CIRCUIT
–
ILONG
100k
Figure 11. Receive Gain and Hybrid Balance vs.
Frequency
VPR
+
PR
ZLONG =
∆ VPR
∆ VPT
OR
∆ ILONG
∆ ILONG
0
12-2585(F).r1
–5
Figure 9. Longitudinal Impedance
TRANSMIT GAIN
–10
DECIBELS (dB)
–15
XMT
PT
–
RETURN LOSS
–30
–35
–45
BASIC
TEST CIRCUIT
VT/R
–25
–40
+
600 Ω
–20
PR
–50
–55
0.1k
RCV
VS
1k
10k
100k
FREQUENCY (Hz)
12-3508
Note: Gain is normalized to 0 dB.
VXMT
GXMT = VT/R
VT/R
GRCV =
VRCV
12-2587(F)
Figure 12. Transmit Gain and Return Loss vs.
Frequency
Figure 10. ac Gains
Agere Systems Inc.
15
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
Characteristic Curves (continued)
50
1500
SLIC POWER DISSIPATION (mW)
45
LOOP CURRENT (mA)
40
35
30
VBAT = –65 V
25
20
15
VBAT = –48 V
10
2 CH
1000
500
1 CH
5
0
0
0
10
20
30
40
0
60
50
200
400
600
800 1000 1200 1400 1600 1800 2000
LOOP RESISTANCE (Ω)
LOOP VOLTAGE (V)
12-3504 (F)
12-3503 (F)
Note: RPROG = 51.1 kΩ.
Figure 13. Loop Current vs. Loop Voltage
Figure 15. SLIC Power Dissipation vs. Loop
Resistance (VBAT = –48 V)
SLIC POWER DISSIPATION (mW)
50
45
LOOP CURRENT (mA)
40
35
30
VBAT = –65 V
25
20
15
VBAT = –48 V
10
5
1500
2 CH
1000
1 CH
500
0
0
0
0
200
400
600
200
400
600
800 1000 1200 1400 1600 1800 2000
800 1000 1200 1400 1600 1800 2000
LOOP RESISTANCE (Ω)
LOOP RESISTANCE (Ω)
12-3505 (F)
12-3506 (F)
Note: RPROG = 51.1 kΩ.
Figure 16. SLIC Power Dissipation vs. Loop
Resistance (VBAT = –65 V)
Figure 14. Loop Current vs. Loop Resistance
16
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
Region 2: Current limit. The dc current is limited to a value determined by external resistor RPROG. This region of
the dc template has a high resistance (6 kΩ).
dc Design
Calculate the external resistor as follows:
Battery Feed
RPROG (kΩ) = 3.5 x (ILIM – 9.2) mA*
The dc feed characteristic can be described by:
V T/R =
IL =
To control power dissipation, it is recommended that a
51.1 kΩ RPROG resistor be used to set a default currentlimit value of 24 mA.
( V B AT – V O H ) × R L
-------------------------------------------R L + 2R P + R d c
RPWR
VBAT – VOH
---------------------------------R L + 2R P + R dc
Where:
IL = dc loop current.
VT/R = dc loop voltage.
|VBAT| = battery voltage magnitude.
VOH = overhead voltage. This is the difference between
the battery voltage and the open loop tip/ring
voltage.
RL = loop resistance, not including protection resistors.
RP = protection resistor value.
Rdc = SLIC internal dc feed resistance.
The design begins by drawing the desired dc template.
An example is shown in Figure 17.
50
45
RPWR =
V B AT – 22.3
----------------------------I L I M – 0.003
Power dissipation of the resistor is:
WRPWR = (ILIM – 0.003)2 RPWR.
For the recommended –68.5 V VBAT and 24 mA ILIM
design, a 2.2 kΩ, 2 W resistor is suitable. 2 W resistors
are available as surface-mount components.
Overhead Voltage
40
LOOP CURRENT (mA)
The RPWR resistors dissipate the excess power associated with a single power supply, short-loop application.
The resistor provides VBAT to tip and ring amplifiers.
There is one resistor associated with each channel.
The value of RPWR is dependent upon the battery
potential and the current-limit value. The value of RPWR
can be determined by using the following equation:
In order to drive an on-hook ac signal, the SLIC must
set up the tip and ring voltage to a value less than the
battery voltage. The amount that the open loop voltage
is decreased relative to the battery is referred to as the
overhead voltage and is expressed as:
35
30
1
6 kΩ
25
VBAT = –65 V
20
VOH = |VBAT| – (VPT – VPR)
15
VBAT = –48 V
10
–1
Rdc
5
0
0
10
20
30
40
50
60
LOOP VOLTAGE (V)
12-3503.a (F)
Figure 17. Loop Current vs. Loop Voltage
Starting from the on-hook condition and going through
to a short circuit, the curve passes through two regions:
Region 1: On-hook and low loop currents. In this
region, the slope corresponds to the dc resistance of
the SLIC, Rdc (typically 60 Ω). The open circuit voltage
is the battery voltage less the overhead voltage of the
device, VOH (default is 7.1 V typical). These values are
suitable for most applications.
Agere Systems Inc.
Without this buffer voltage, amplifier saturation will
occur and the signal will be clipped. The L8576 is automatically set at the factory to allow undistorted on-hook
transmission of a 3.17 dBm signal into a 900 Ω loop
impedance.
The drive amplifiers are capable of 4 Vrms minimum
(VAMP). So, the maximum signal the device can guarantee is:
Z T/R
V T/R = 4 V  --------------------------
 Z T/R + 2R P
For normal forward or reverse battery operation, overhead voltage is internally set to about 8 V. In ringing
mode, the overhead voltage is automatically decreased
to about 4 V to permit passage of a larger ring signal.
* During the balanced ringing mode, the current limit is increased
from the value predicted by this equation by a factor of 3.5.
17
Data Sheet
May 2001
L8576B Dual Ringing SLIC
dc Design (continued)
Off-Hook Detection
The loop closure comparator has built-in longitudinal
rejection, eliminating the need for an external 60 Hz filter. The loop closure detection threshold is internally
set at 12 mA.
Power Ringing
CF1 and CF2 must exhibit a stable capacitance value
over its voltage range to ensure a properly shaped
waveform. Do not use a ceramic capacitor for CF1 and
CF2; use a capacitor with a polyester, polypropylene,
polycarbonate, or polystyrene dielectric.
80
60
VOLTS (V)
Applications (continued)
40
20
0
–20
–40
The L8576B is designed to generate a balanced trapezoidal power ring signal to tip and ring. Because the
L8576B generates the power ringing signal, no ring
relay is needed in this mode of operation. Alternatively,
the L8576B SLIC can be used in a battery-backed,
unbalanced ringing application. In this case, the ring
signal is generated by a central ring generator and is
bused to individual tip/ring pairs. A ringing relay is used
during ringing to disconnect the L8576B from, and
apply the ring generator to, the tip and ring pair.
This section discusses in detail the use of the L8576B
in the balanced mode of operation.
–60
–80
0.00 0.04 0.08 0.12 0.16 0.20
0.02 0.06 0.10 0.14 0.18
TIME (s)
12-3346a (F)
Notes:
Slew rate = 5.65 V/ms.
trise = tfall = 23 ms.
pwidth = 2 ms.
period = 50 ms.
Figure 18. Ringing Waveform Crest Factor = 1.6
Crest Factor
80
18
60
VOLTS (V)
The balanced ring signal is generated by simply toggling between the powerup forward and reverse battery
states. The state change is done by applying a square
wave (whose frequency is the desired ring frequency)
to logic input B2. Capacitors CF1 and CF2 and resistor
RRNG are used to control or ramp the speed of the transition of the battery reverse, thus shaping the balanced
ring signal. Setting capacitor CF1 = CF2 = 0.22 µF and
setting RRNG to 28.7 kΩ provides a crest factor of 1.3
for a 20 Hz ring frequency. This satisfies the Telcordia*
GR-909 requirement of ringing waveform crest factor
between 1.2 and 1.6. Crest factor is defined as the
peak to rms voltage ratio of the ring signal. Ringing
waveforms of crest factors 1.6 and 1.2 are shown in
Figures 18 and 19. The crest factor can be adjusted by
the value of RRNG and will be influenced slightly by the
value of VBAT. The CF1 and CF2 capacitors should not
be changed because these affect the dc feedback loop
stability in current limit. An RRNG value of 22.6 kΩ will
lower the crest factor to about 1.2 with a –65 V or
–72 V battery for a 20 Hz ring frequency. Likewise, an
RRNG value of 34.8 kΩ will raise the crest factor to
about 1.4. For ring frequencies greater than 20 Hz, the
RRNG value should be lowered until the desirable crest
factor is achieved. Note the RRNG is common to both
sections of the device.
40
20
0
–20
–40
–60
–80
0.00 0.04 0.08 0.12 0.16 0.20
0.02 0.06 0.10 0.14 0.18
TIME (s)
12-3347a (F)
Notes:
Slew rate = 10.83 V/ms.
trise = tfall = 12 ms.
pwidth = 13 ms.
period = 50 ms.
Figure 19. Ringing Waveform Crest Factor = 1.2
* Telcordia is a registered trademark of Telcordia Technologies, Inc.
Agere Systems Inc.
Data Sheet
May 2001
Applications (continued)
L8576B Dual Ringing SLIC
To determine the low-pass pole:
1
f(Hz) = ----------------------------------------------2π ( R TFLT ) ( C RT )
Power Ringing (continued)
Power Ringing Load
Telcordia GR-909 specifies that a minimum 40 Vrms
must be delivered to a 5 REN ringing load of 1386 Ω +
40 µF. For 5 REN load, it is recommended that VBAT be
set to –68.5 Vdc. During the power ring state, the dc
current limit is automatically boosted by a factor of 3.5
over the current limit set by resistor RPROG. Both of
these factors are necessary to ensure delivery of
40 Vrms to the North American 5 REN ringing load of
1386 Ω + 40 µF.
Ring Trip
Ring trip is accomplished by filtering the voltage seen
at node DCOUT and applying it to the integrated ring trip
comparator. DCOUT is a voltage proportional to the tip/
ring current, and under short dc loop conditions, onhook ringing current and off-hook current provide sufficient voltage differential at DCOUT to distinguish that a
ring trip condition has occurred. The ring trip comparator threshold is set via a resistor between the ring trip
comparator and DCOUT.
The output of NSTAT is automatically set to detect ring
trip during the balanced ring mode. During quiet intervals of ringing, the output of NSTAT is automatically
determined by the loop closure detector.
Refer to Figure 2 for the following discussion.
Capacitor CRT in conjunction with resistor RTFLT form a
single-pole, low-pass filter that smooths the voltage
seen at DCOUT. The pole of the filter will influence both
the ripple seen at DCOUT and the speed of the transition of the voltage at DCOUT from the pretrip to the
tripped level.
Agere Systems Inc.
Using the recommended 383 kΩ RTFLT resistor and
the 0.1 µF CRT capacitor, the low-pass pole is set at
4.15 Hz.
The loop current at ring trip is given by:
R TTH
ILOOP(TRIP) = 7.76 mA  ---------------
R GX2
Using the recommended 52.3 kΩ RTTH resistor and the
7.5 kΩ RGX2 resistor in a 20 Hz ringing application, the
ring trip threshold current is set for 54 mA.
Reference Design for ISDN TA Applications
For a complete reference design, please refer to the
POTS for ISDN, WLL, and FITL/FITH Applications,
Featuring Ringing SLIC Solutions Application Note,
which provides a detailed discussion of the reference
design functionality. The design presented utilizes a dc
to dc converter and requires only a +5 V and a +12 V
supply to operate. The schematic in Figure 2 of this
document portrays the SLIC and codec portions of that
design.
ac Design
There are four key ac design parameters. Termination
impedance is the impedance looking into the 2-wire
port of the line card. It is set to match the impedance of
the telephone loop in order to minimize signal reflections back to the telephone set. Transmit gain is measured from the 2-wire port to the PCM highway, while
receive gain is measured from the PCM highway to
the 2-wire port or telephone loop. Finally, the hybrid
balance circuit cancels the unwanted amount of the
received signal that appears at the transmit port.
19
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
Transmit gain:
V GSX
G TX = --------------V T/R
ac Design (continued)
R X 125
G TX = ---------- × ----------R T2 Z T/R
Example 1, Real Termination
The following design equations refer to the circuit in
Figure 20. Use these to synthesize real termination
impedance.
Hybrid balance:
V G SX
h bal = 20 log  -----------
 V T/R 
Termination impedance:
V T/R
To optimize the hybrid balance, the sum of the currents
at the VFXIN input of the codec op amp should be set
to 0. The following expressions assume the hybrid balance network is the same as the termination impedance:
---------– I T/R
Zt =
1500
Z t = 2R P + ----------------------------------RT1
RT1
1 + --------- + -----------RGP RRCV
RHB =
Receive gain:
GRCV =
G RC V =
V T/R
VFRO
-----------
RX
G RC V × G T X
--------------------------
RX
h ba l = 20 log  -------- RHB
– G R C V × G TX

12
-----------------------------------------------------------------Zt
R CV
RRCV
1 + R
+ ------------  1 + ---------
----------


RT1
RGP
Z T/R
RX
GSX
TG
1/2 L8576
SLIC
125 V/A
AX
ZT/R
VS
ZT
RP
PT
IT/R
+
VT/R
–
RP PR
RT2
VITR
–
–
AV = 1
+
AV = 6
+
CURRENT
SENSE
RGX
VFXIN –
+
RT1
RCVN
RHB
RRCV
RCVP
+2.4 V
VFRO
RGP
+
AV = –1
–
1/2 T8503 CODEC
12-2554.o (F)
Figure 20. ac Equivalent Circuit Using a T8503 Codec
20
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
RX/RT2: With other components set, the transmit gain
(for complex and resistive terminations) RX and RT2 are
varied to give specified transmit gain.
ac Design (continued)
Example 2, Complex Termination
The gain shaping required of a complex termination
impedance can be synthesized using the internal AX
amplifier. The following discussion and equations
present a method for selecting proper component values for the SLIC/codec interface when using a complex
termination.
Complex termination is usually of the form:
R2
RT1/RRCV/RGP: For both complex and resistive terminations, the ratio of these resistors set the receive gain.
For resistive terminations, the ratio of these resistors
set the return loss characteristic. For complex terminations, the ratio of these resistors set the low-frequency
return loss characteristic.
CN/RN1/RN2: For complex terminations, these components provide high-frequency compensation to the
return loss characteristic. For resistive terminations,
these components are not used. RCVN is connected to
ground via a resistor.
RHB: Sets hybrid balance for all terminations.
R1
Set ZTG — gain shaping:
C
5-6396(F)
To work with this application, convert termination to the
form:
R1´
R 2´
ZTG = RTGP || RTGS + CTGS which is a scaled version of
ZT/R (the specified termination resistance) in the
R1´ || R2´ + C´ form.
RTGP must be 24.4 kΩ to set SLIC transconductance to
125 V/A.
RTGP = 24.4 kΩ
C´
5-6397(F)
where:
At dc, CTGS and C´ are open.
R1´ = R1 + R2
RTGP = M x R1´
R1
R2´ = ------- (R1 + R2)
R2
where M is the scale factor.
2
R2
C´ =  --------------------- C
R1 + R2
For the following discussion, refer to Figure 21.
RTGP/RTGS/CTGS (ZTG): These components give gain
shaping to get good gain flatness. These components
are a scaled version of the specified complex termination impedance. Note for pure (600 Ω) resistive terminations, components RTGS and CTGS are not used.
Resistor RTGP is used and is the series resistance combination of RGX1 and RGX2 or 24.4 kΩ.
Agere Systems Inc.
24.4 kΩ
M = -----------------------R1′
It can be shown:
RTGS = M x R2´
and
CTGS =
C′
-----M
21
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
ac Design (continued)
RTGS CTGS
Rx
RTGP = 24.4 kΩ
–IT/R
195
RT2
–
+
AX
VITR
CODEC
OP AMP
CN
RN1
RT1
RHB
RCVN
RRCV
RCVP
RN2
RGP
CODEC
OUTPUT
DRIVE
AMP
5-6400a(F)
Figure 21. ac Interface Circuit Using First-Generation Codec (Blocking Capacitors Not Shown)
Transmit Gain
Transmit gain will be specified as a gain from T/R to
PCM, TX (dB). Since PCM is referenced to 600 Ω and
assumed to be 0 dB, and in the case of T/R being referenced to some complex impedance other than 600 Ω
resistive, the effects of the impedance transformation
must be taken into account.
Again specified complex termination impedance at T/R
is of the form:
600
----------- represents the power loss/gain
R EQ
due to the impedance transformation.
Note in the case of a 600 Ω pure resistive termination
600
----------- = 20log
R EQ
600
---------- = 0.
600
at T/R 20log
C
Thus, there is no power loss/gain due to impedance
transformation and TX (dB) = TX (specified[dB]).
5-6396(F)
First calculate the equivalent resistance of this network
at the midband frequency of 1000 Hz.
REQ =
Finally, convert TX (dB) to a ratio, GTX:
TX (dB) = 20log GTX
The ratio of RX/RT2 is used to set the transmit gain:
2
+ R1 +
2
 (---------------------------------------------------------------------------- +  --------------------------------------------------

1 + ( 2 πf ) 2 R 2 2 C 1 2
1 + ( 2 πf ) 2 R 2 2 C 1 2
πf R 2 2 C 1
R 2 2
2
Using REQ, calculate the desired transmit gain, taking
into account the impedance transformation:
TX (dB) = TX (specified[dB]) + 20log
22
the T/R. 20log
R2
R1
πf ) 2 C 1 2 R 1 R 2 2
TX (specified[dB]) is the specified transmit gain. 600 Ω is the
impedance at the PCM and R EQ is the impedance at
600
----------R EQ
RX
R T2
195
M
---------- = GTX x ----------
with a dual Agere codec such as T8503
RX < 200 kΩ
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
ZTER(low) is the specified termination impedance assuming low frequency (C or C´ is open).
ac Design (continued)
RP is the series protection resistor.
Receive Gain
These two equations are best solved using a computer
spreadsheet.
Ratios of RRCV, RT1, RGP will set both the low-frequency
termination and receive gain for the complex case. In
the complex case, additional high-frequency compensation, via CN, RN1, and RN2, is needed for the return
loss characteristic. For resistive termination, CN, RN1,
and RN2 are not used and RCVN is tied to ground and a
resistor.
Next, solve for the high-frequency return loss compensation circuit, CN, RN1, and RN2:
2R P
CN x RN2 = ------------- CTGS x RTGP
1500
1500 R TGS
RN1 = RN2 -------------  -------------- – 1
2R P  R TGP
Determine the receive gain, GRCV, taking into account
the impedance transformation in a manner similar to
transmit gain.
RX (dB) = RX (specified[dB]) + 20log
There is an input offset voltage associated with nodes
RCVN, RCVP. To minimize the effect of the mismatch of
this voltage at T/R, the equivalent resistance to ac
ground at RCVN should be approximately equal to that
at RCVP. Refer to Figure 22 (schematic with dc blocking
capacitors). To meet this requirement, RN2 = RGP || RT1.
R EQ
----------600
RX (dB) = 20log GRCV
Then:
6
GRCV = -----------------------------------------------R RCV R RCV
1 + --------------- + --------------R T1
R GP
Hybrid Balance
Set the hybrid cancellation via RHB.
RX
RHB = ---------------------------------G RCV × G TX
and low-frequency termination
1500
ZTER(low) = -------------------------------------------- + 2RP
R T1 R T1
1 + ------------ + --------------R GP R RCV
RTGS
If a +5 V only codec such as an Agere T8503 is used,
dc blocking capacitors must be added as shown in
Figure 22. This is because the codec is referenced to
+2.5 V and the SLIC to ground. With the ac coupling, a
dc bias at T/R is eliminated and power associated with
this bias is not consumed.
CTGS
RX
–IT/R
195
RTSP = 24.4 kΩ
CB
RT2
CC1
AX
VITR
–
+
CODEC
OP AMP
CN
RN1
RT1
RN2
RGP
RHB
RCVN
RCVP
RRCV
CC2
CODEC OUTPUT
DRIVE AMP
5-8413 (F)
Figure 22. ac Interface Circuit Using First-Generation Codec (Including Blocking Capacitors)
Agere Systems Inc.
23
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Applications (continued)
ac Design (continued)
Typically, values of 0.1 µF to 0.47 µF capacitors are
used for dc blocking. The addition of blocking capacitors will cause a shift in the return loss and hybrid balance frequency response toward higher frequencies,
degrading the lower-frequency response. The lower
the value of the blocking capacitor, the more pronounced the effect is, but the cost of the capacitor is
lower. It may be necessary to scale resistor values
higher to compensate for the low-frequency response.
This effect is best evaluated via simulation. A PSPICE *
model for the L8576B is available.
Design equation calculations seldom yield standard
component values. Conversion from the calculated
value to standard value may have an effect on the ac
parameters. This effect should be evaluated and optimized via simulation.
Use of an Auxiliary Battery Supply
A second lower-voltage battery supply can be used
with the L8576B in order to lower the overall power
consumption on a short-loop design. For long loops,
any power savings will be negated, since long loops
are supplied by the main battery voltage. The auxiliary
battery would be connected to pins 9 and 37 in lieu of
the RPWR resistors. When the external RPWR resistors
are removed, more power will be dissipated in the SLIC
so internal SLIC power dissipation must be examined.
First, determine the auxiliary battery voltage:
The auxiliary battery should be set 8 V greater than the
maximum tip/ring loop voltage on the longest allowed
loop, when both channels are off-hook and in current
limit.
Aux Bat(MAX) = [(ILIM x RLOOP) + VOH] TOLVBAT
Where:
ILIM = dc current limit set by RPROG (usually 0.024).
RLOOP = maximum loop resistance supported (telephone plus line resistance plus protection
resistors).
VOH = overhead voltage.
TOLVBAT = battery tolerance, for a battery tolerance of
±5%, use 1.1.
For example, using the recommended 24 mA current
limit, an overhead voltage of 8 V, and a maximum loop
length of 550 Ω, the maximum auxiliary battery voltage
is 23.3 V.
24
Next, calculate the power dissipated in the SLIC:
Components of the SLIC power dissipation are quiescent power of VCC and VBAT and loop current associated with VBAT and Aux Bat. These can be calculated
as follows:
WVCC(quiescent) = VCC x ICC(Max)(quiescent) x 2 channels.
WVBAT(quiescent) = |VBAT(Max)| x IBAT(Max)(quiescent) x 2 channels.
WVBAT(loop current) = (|VBAT(Max)| – 4 V) x 3 mA x 2 channels.
WAux Bat(loop current) = (|Aux Bat(Max)| – 4 V) x (ILIM – 3 mA)
x 2 channels.
Where:
4 V is the minimum overhead voltage, and 3 mA is
VBAT’s contribution to loop current.
For example, substituting values from the data sheet:
VCC = 5 V
ICC(Max)(quiescent) = 5.5 mA
VBAT(Max) = –70 V
IBAT(Max)(quiescent) = 4 mA
Aux Bat(Max) = –23.3 V
ILIM = 24 mA
The following powers are calculated:
WVCC(quiescent) = 5 x 0.0055 x 2 = 0.055
WVBAT(quiescent) = |–70| x 0.004 x 2 = 0.56
WVBAT(loop current) = (|–70| – 4) x 0.003 x 2 = 0.396
WAux Bat(loop current) = (|–23.3| – 4) x (0.024 – 0.003) x 2 =
0.8106
The sum of the four powers is 1.822 W.
Finally, calculate the maximum ambient temperature allowed for the calculated power dissipation:
TA(max) = Tj – (RθJA x PDISS SLIC(max))
The L8576’s 44-pin PLCC exhibits a 43 °C/W thermal
resistance if in an enclosure with natural airflow. The
maximum operating temperature of the SLIC is 150 °C.
Thermal shutdown occurs typically at 160 °C.
For example:
TA(max) = 150 – (43 x 1.822)
= 150 – 78.4
= 71.7 °C
The above scenario would allow operation up to 70 °C.
* PSPICE is a registered trademark of Cadence Design Systems, Inc.
Agere Systems Inc.
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Outline Diagram
44-Pin PLCC
Dimensions are in millimeters.
17.65 MAX
16.66 MAX
PIN #1 IDENTIFIER
ZONE
6
1
40
7
39
16.66
MAX
17.65
MAX
29
17
18
28
4.57
MAX
1.27 TYP
0.53
MAX
0.51 MIN
TYP
SEATING PLANE
0.10
5-2506(F).r8
Agere Systems Inc.
25
Data Sheet
May 2001
L8576B Dual Ringing SLIC
Ordering Information
Device Part No.
LUCL8576BP-D
LUCL8576BP-DT
Description
Dual SLIC
Dual SLIC
Package
44-Pin PLCC (Dry-bagged)
44-Pin PLCC (Tape and Reel, Dry-bagged)
Comcode
108131285
108131293
For additional information, contact your Agere Systems Account Manager or the following:
INTERNET:
http://www.agere.com
E-MAIL:
[email protected]
N. AMERICA: Agere Systems Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18109-3286
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA PACIFIC: Agere Systems Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256
Tel. (65) 778 8833, FAX (65) 777 7495
CHINA:
Agere Systems (Shanghai) Co., Ltd., 33/F Jin Mao Tower, 88 Century Boulevard Pudong, Shanghai 200121 PRC
Tel. (86) 21 50471212, FAX (86) 21 50472266
JAPAN:
Agere Systems 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: DATALINE: Tel. (44) 7000 582 368, FAX (44) 1189 328 148
Technical Inquiries: GERMANY: (49) 89 95086 0 (Munich), UNITED KINGDOM: (44) 1344 865 900 (Ascot),
FRANCE: (33) 1 40 83 68 00 (Paris), SWEDEN: (46) 8 594 607 00 (Stockholm), FINLAND: (358) 9 3507670 (Helsinki),
ITALY: (39) 02 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Agere Systems Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liab ility is assumed as a result of their use or application.
Copyright © 2001 Agere Systems Inc.
All Rights Reserved
May 2001
DS01-199ALC (Replaces DS01-112ALC)