ETC LUCL8560CAU-DT

Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Features
■
Full-feature set for central office applications
■
Also ideal for ISDN terminal adapters, pair gain,
and cable telephony applications
■
Auxiliary input for second battery, and internal
switch to enable its use to save power in short telephone loops
■
5 V only operation or optional ±5 V operation for
reduced power consumption
■
Low active power (85 mW typical) and scan power
(61 mW typical) with 5 V only operation
■
Low active power (68 mW typical with auxiliary battery) and scan power (45 mW typical) with ±5 V
operation
■
Quiet tip/ring polarity reversal
■
Per-line ringing available for short loops
■
Reduced overhead and increased current limit during ring mode for lower-battery operation or
increased ring loop length
■
Supports meter pulse injection
■
Distortion-free full duplex from 0 mA dc loop current on-hook transmission
■
Convenient operating states:
— Forward powerup
— Polarity reversal powerup
— Forward sleep
— Ground start
— Disconnect
■
Adjustable supervision functions:
— Off-hook detector with longitudinal rejection
— Ground key detector with longitudinal rejection
— Ring trip detector
■
Independent, adjustable dc and ac parameters:
— dc feed resistance (44-pin PLCC version)
— Loop current limit
— Termination impedance
■
Thermal protection
Description
The L8560 full-feature, low-power subscriber line
interface circuit (SLIC) is optimized for low power
consumption while providing an extensive set of features. This part is ideal for ISDN terminal adapter
applications and short-loop, power-sensitive applications such as pair gain and cable telephony. This part
is also designed for PBX, DLC, or CO applications.
The SLIC includes an auxiliary battery input and a
battery switch. In short-loop applications, SLICs can
be used in high battery to present a high on-hook
voltage, and then switched to low battery to reduce
off-hook power.
To help minimize the required auxiliary battery voltage, the dc feed resistance and overhead voltage are
set at 55 Ω and 6.7 V, respectively. This allows an
undistorted on-hook transmission of a 3.14 dBm signal into a 900 Ω loop impedance.
The device offers the reverse battery function. Using
the reverse battery, the device can provide a balanced power ring signal to tip and ring. In this
mode of operation, the battery switch is used to
apply a high-voltage battery during ringing and a
lower-voltage battery during the talk and idle states.
Also included in the L8560 is a dc current-limit
switch, which increases the dc current limit during
power ringing. In addition, dc overhead voltage is
reduced during the ring state. With the battery and
current-limit switches, and overhead reduction, the
L8560 can provide sufficient power to ring a true
North American 5 REN load of 1386 Ω + 40 µF.
The device offers ring trip and loop closure supervision with 0.3 V and 2 mA hysteresis, respectively. It
also includes the ground start state and ring ground
detection. A summing node for meter pulse injection
to 2.2 Vrms is also included. The 44-pin PLCC version also has a spare uncommitted op amp, which
may be used for ac gain setting or meter pulse filtering.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Table of Contents
Contents
Page
Features .................................................................... 1
Description ................................................................. 1
Pin Information ........................................................... 6
Functional Description ................................................ 9
Absolute Maximum Ratings ..................................... 10
Recommended Operating Conditions ...................... 11
Electrical Characteristics .......................................... 11
Ring Trip Requirements ......................................... 16
Test Configurations .................................................. 17
Applications ............................................................. 19
Characteristic Curves............................................. 19
dc Applications ...................................................... 21
Battery Feed...................................................... 21
Overhead Voltage ............................................ 22
Adjusting Overhead Voltage ............................. 23
Adjusting dc Feed Resistance........................... 23
Adjusting Overhead Voltage and dc Feed
Resistance Simultaneously.............................. 24
Loop Range....................................................... 24
Off-Hook Detection ........................................... 24
Ring Ground Detection...................................... 25
Longitudinal Balance.............................................. 25
Power Derating ..................................................... 25
Battery Switch ....................................................... 26
VCC/VEE Supplies ................................................... 27
Power Ringing ....................................................... 27
Ringing SLIC Balanced Ring Signal
Generation ....................................................... 27
POTS for ISDN Terminal Adapters ................... 27
2
Contents
Page
Power Ringing Load .......................................... 28
Crest Factor....................................................... 28
Current-Limit Switch .......................................... 29
Ring Trip............................................................ 29
Reference Designs for ISDN TA Applications ... 31
Design Considerations .......................................... 33
Unbalanced Bused Ring Signal Application ...... 33
Ring Trip Detection............................................ 33
ac Design .............................................................. 37
First-Generation Codecs ................................... 37
Second-Generation Codecs .............................. 37
Third-Generation Codecs .................................. 37
Design Examples ................................................... 39
Example 1, Real Termination ............................ 39
Example 2, Complex Termination ..................... 39
Example 3, Complex Termination Without
Spare Op Amp ................................................. 39
Complex Termination Impedance Design
Example Using L8560 Without Spare
Op Amp ............................................................ 40
ac Interface Using First-Generation Codec ....... 40
Transmit Gain.................................................... 41
Receive Gain..................................................... 42
Hybrid Balance .................................................. 42
Blocking Capacitors........................................... 43
Outline Diagrams...................................................... 44
32-Pin PLCC ......................................................... 44
44-Pin PLCC ......................................................... 45
Ordering Information................................................. 46
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Table of Contents (continued)
Figures
Page
Figure 1. Functional Diagram ..................................... 5
Figure 2. 32-Pin Diagram (PLCC Chip) ...................... 6
Figure 3. 44-Pin Diagram (PLCC Chip) ...................... 6
Figure 4. Ring Trip Circuits....................................... 16
Figure 5. Basic Test Circuit ...................................... 17
Figure 6. Metallic PSRR ........................................... 17
Figure 7. Longitudinal PSRR .................................... 17
Figure 8. Longitudinal Balance ................................. 18
Figure 9. RFI Rejection............................................. 18
Figure 10. Longitudinal Impedance .......................... 18
Figure 11. ac Gains .................................................. 18
Figure 12. L8560 Receive Gain and Hybrid
Balance vs. Frequency .......................... 19
Figure 13. L8560 Transmit Gain and Return Loss
vs. Frequency ........................................ 19
Figure 14. L8560 Typical VCC Power Supply
Rejection ................................................ 19
Figure 15. L8560 Typical VBAT Power Supply
Rejection ................................................ 19
Figure 16. Loop Closure Program Resistor
Selection ................................................ 20
Figure 17. Ring Ground Detection Programming ..... 20
Figure 18. Loop Current vs. Loop Voltage................ 20
Figure 19. Loop Current vs. Loop Resistance .......... 20
Figure 20. L8560 Typical SLIC Power Dissipation
vs. Loop Resistance............................... 21
Figure 21. Power Derating........................................ 21
Figure 22. Loop Current vs. Loop Voltage................ 21
Figure 23. SLIC 2-Wire Output Stage....................... 23
Figure 24. Equivalent Circuit for Adjusting the
Overhead Voltage .................................. 23
Figure 25. Equivalent Circuit for Adjusting the
dc Feed Resistance ............................... 23
Figure 26. Adjusting Both Overhead Voltage and
dc Feed Resistance ............................... 24
Figure 27. Off-Hook Detection Circuit....................... 24
Figure 28. POTS Controlled from an ISDN
Terminal Adapter ................................... 28
Figure 29. Ringing Waveform Crest Factor = 1.6 ..... 28
Figure 30. Ringing Waveform Crest Factor = 1.2 ..... 28
Figure 31. Equivalent Ring Trip Circuit for
Balanced Ringing SLIC ......................... 29
Lucent Technologies Inc.
Figure 32. Thevenin Equivalent Ring Trip Circuit
for Balanced Ringing SLIC..................... 29
Figure 33. POTS Interface with Balanced Ringing
Using L8560 SLIC and T8503 Codec .... 31
Figure 34. Ring Trip Equivalent Circuit and
Equivalent Application ........................... 33
Figure 35. Basic Loop Start Application Circuit
Using T7504 Codec and Bused
Ringing................................................... 34
Figure 36. Ground Start Application Circuit .............. 35
Figure 37. ac Equivalent Circuit Not Including
Spare Op Amp ....................................... 38
Figure 38. ac Equivalent Circuit Including Spare
Op Amp.................................................. 38
Figure 39. Interface Circuit Using First-Generation
Codec (Blocking Capacitors Not
Shown) ................................................... 41
Figure 40. ac Interface Using First-Generation
Codec (Including Blocking Capacitors)
for Complex Termination Impedance ..... 43
Tables
Page
Table 1. L8560 Product Family Feature Summary ..... 4
Table 2. Pin Descriptions............................................ 7
Table 3. Input State Coding........................................ 9
Table 4. Supervision Coding ...................................... 9
Table 5. Power Supply ............................................. 12
Table 6. 2-Wire Port ................................................. 13
Table 7. Analog Pin Characteristics ......................... 14
Table 8. Uncommitted Op Amp
Characteristics (44-Pin PLCC Only).......... 14
Table 9. ac Feed Characteristics .............................. 15
Table 10. Logic Inputs and Outputs.......................... 16
Table 11. Parts List for Balanced Ringing Using
T8503 Codec .......................................... 32
Table 12. Parts List for Loop Start with Bused
Ringing and Ground Start Applications .. 35
Table 13. 600 Ω Design Parameters ........................ 37
3
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Description (continued)
The L8560 product family is graded by different features, specifications, and package options. The
L8560Axx is the basic full-feature SLIC that operates
with 5 V and a battery supply, and is available in the
32-pin PLCC (AAU) package and the 44-pin PLCC
package (AP). This part is graded as the 54 dB longitudinal balance part. Additional features (spare op amp
and overhead voltage programming) are available in
the 44-pin PLCC package.
The L8560CAU is available only in the 32-pin PLCC
package and has a feature set similar to the AAU version, except the CAU version requires +5 V, –5 V, and
battery power supplies. With this option, power consumption is greatly reduced.
The L8560DAU and L8560EP are available in the
32-pin and 44-pin PLCC packages and have feature
sets identical to the L8560AAU and L8560AP, respectively, with the following modifications. These parts are
graded as high longitudinal balance (63 dB), and have
an additional logic state (scan with low battery) which
allows for low on-hook power dissipation.
The L8560FAU and L8560GP are available in the
32-pin and 44-pin PLCC packages and have feature
sets identical to the L8560AAU and L8560AP, respectively, with the following modifications. These parts are
graded for lower longitudinal balance (50 dB), and
have an additional logic state (scan with battery) which
allows for low on-hook power dissipation.
Table 1 below summarizes the features in the L8560
product family.
Table 1. L8560 Product Family Feature Summary
Feature
32-Pin PLCC
44-Pin PLCC
5 V Operation
±5 V Operation (reduced power consumption)
Operational VBAT1 (V)
Battery Switch
Balanced Ring Mode
Adjustable Overhead
Spare Op Amp
Reverse Battery
Scan Mode
Scan Mode with Low Battery
Longitudinal Balance (dB)*
On-hook Transmission
Ground Start
Loop Start
Ring Trip Detector
Programmable Current Limit
Thermal Protection
L8560
AAU
AP
CAU
DAU
EP
FAU
GP
X
NA
X
NA
–70
X
X
NA
NA
X
X
NA
54
X
X
X
X
X
X
NA
X
X
NA
–70
X
X
X
X
X
X
NA
54
X
X
X
X
X
X
X
NA
NA
X
–70
X
X
NA
NA
X
X
NA
54
X
X
X
X
X
X
X
NA
X
NA
–70
X
X
NA
NA
X
X
X
63
X
X
X
X
X
X
NA
X
X
NA
–70
X
X
X
X
X
X
X
63
X
X
X
X
X
X
X
NA
X
NA
–70
X
X
NA
NA
X
X
X
50
X
X
X
X
X
X
NA
X
X
NA
–70
X
X
X
X
X
X
X
50
X
X
X
X
X
X
* More information is provided in the Applications section of this document.
4
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
VBAT1
INTERNAL SWITCH
DECISION
VREG
BATTERY
SWITCH
FB2
FB1
AGND
VCC
BGND
VBAT2
VBAT1
BS2
BS1
VBAT1
VBAT2
SEE ENLARGED DETAIL
VEE (OPTIONAL
ON L8560C)
Description (continued)
POWER CONDITIONING
& REFERENCE
BATTERY SWITCH
2
RECTIFIER
ENLARGED DETAIL
AX
+
PR
44-PIN
PLCC
ONLY
DCR
IPROG
CF2
TG
–
PT
CF1
VTX
TXI
19.2
0.1 µF
CEXTERNAL
SPARE
OP AMP
A=4
A = –4
DCOUT
VITR
SN
–
XMT
44-PIN
PLCC
ONLY
+
–
RCVN
+
RCVP
1
dc RESISTANCE
ADJUST
B0
BATTERY FEED
STATE CONTROL
CURRENT-LIMIT
ADJUST
B1
B2
BR
LCTH
LOOP CLOSURE DETECTOR
+
NSTAT
–
+
RTSP
RTSN
ICM
RING TRIP DETECTOR
RING GROUND
DETECTOR
–
RGDET
12-2569.c (F)
Figure 1. Functional Diagram
Lucent Technologies Inc.
5
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
2
TG
3
VTX
VITR
NC (L8560A/D/F)
VEE (L8560C)
NSTAT
4
TXI
RCVP
Pin Information
RCVN
5
1 32 31 30
29
BR
FB2
6
28
B0
FB1
7
27
B1
LCTH
8
26
B2
32-PIN PLCC
11
23
BS1
CF1
12
22
BS2
21
13
14 15 16 17 18 19 20
ICM
VBAT1
AGND
RTSP
RTSN
BGND
PT
CF2
RGDET
24
VBAT2
PR
10
9
VCC
25
IPROG
DCOUT
12-2548.L (F)
NC
2
FB2
IPROG
3
FB1
CF2
4
LCTH
CF1
5
DCR
SN
6
DCOUT
XMT
Figure 2. 32-Pin Diagram (PLCC Chip)
RTSN
7
1 44 43 42 41 40
39
RCVN
RTSP
8
38
RCVP
NC
9
37
VITR
AGND
10
36
NC
35
NSTAT
34
TXI
NC
11
VCC
12
VBAT1
13
33
VTX
44-PIN PLCC
VBAT2
14
32
TG
BGND
15
31
NC
RGDET
16
30
NC-NTP
NC
BR
B0
B1
B2
PR
NC
PT
NC
NC
BS1
17
29
18 19 20 21 22 23 24 25 26 27 28
BS2
ICM
12-2548.f (F)
Figure 3. 44-Pin Diagram (PLCC Chip)
6
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Pin Information (continued)
Table 2. Pin Descriptions
32-Pin 44-Pin Symbol Type
Description
DCOUT
O
dc Output Voltage. This output is a voltage that is directly proportional to the
9
1
absolute value of the differential tip/ring current.
IPROG
I
Current-Limit Program Input. A resistor to DCOUT sets the dc current limit of
10
2
the device.
11
3
CF2
— Filter Capacitor 2. Connect a 0.1 µF capacitor from this pin to AGND.
12
4
CF1
— Filter Capacitor 1. Connect a 0.47 µF capacitor from this pin to pin CF2.
SN
I
Summing Node. The inverting input of the uncommitted operational amplifier.
—
5
A resistor or network to XMT sets the gain (44-pin PLCC only).
XMT
O
Transmit ac Output Voltage. The output of the uncommitted operational
—
6
amplifier (44-pin PLCC only).
RTSN
I
Ring Trip Sense Negative. Connect this pin to the ringing generator signal
13
7
through a high-value resistor.
8
RTSP
I
Ring Trip Sense Positive. Connect this pin to the ring relay and the ringer
14
series resistor through a high-value resistor.
—
9
NC
— No Connection. May be used as a tie point.
15
10
AGND
— Analog Signal Ground.
—
11
NC
— No Connection. May be used as a tie point.
16
12
VCC
— 5 V Power Supply.
17
13
VBAT1
—
Battery Supply. Negative high-voltage battery, higher in magnitude than VBAT2.
18
14
VBAT2
—
Auxiliary Battery Supply. Negative high-voltage battery, lower in magnitude
than VBAT1, used to reduce power dissipation on short loops.
19
15
BGND
—
Battery Ground. Ground return for the battery supply.
20
16
RGDET
O
21
17
ICM
I
Ring Ground Detect. When high, this open-collector output indicates the presence of a ring ground. To use, connect a 100 kΩ resistor to VCC.
Common-Mode Current Sense. To program ring ground sense threshold,
connect a resistor to VCC and connect a capacitor to AGND to filter 50/60 Hz. If
unused, the pin should be connected to ground.
22
18
BS2
—
Battery Switch Slowdown. Connect a 0.22 µF capacitor to pin BS1.
23
19
BS1
—
Battery Switch Slowdown. Connect a 0.22 µF capacitor to pin BS2. Also, connect a 0.1 µF capacitor in series with a 100 Ω resistor from BS1 to VBAT1 for stability.
—
20
NC
—
No Connection. May be used as a tie point.
—
21
NC
—
No Connection. May be used as a tie point.
24
22
PT
I/O
25
23
PR
I/O
Protected Tip. The output of the tip driver amplifier and input to loop sensing.
Connect to loop through overvoltage protection.
Protected Ring. The output of the ring driver amplifier and input to loop sensing circuitry. Connect to loop through overvoltage protection.
Lucent Technologies Inc.
7
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Pin Information (continued)
Table 2. Pin Descriptions (continued)
32-Pin 44-Pin
—
24
25
26
8
Symbol
NC
Type
Description
— No Connection. May be used as a tie point.
B2
I
State Control Input. B0, B1, B2, and BR determine the state of the SLIC.
See Table 3. Pin B2 has a 40 kΩ pull-up.
27
26
B1
I
State Control Input. B0, B1, B2, and BR determine the state of the SLIC.
See Table 3. Pin B1 has a 40 kΩ pull-up.
28
27
B0
I
State Control Input. B0, B1, B2, and BR determine the state of the SLIC.
See Table 3. Pin B0 has a 40 kΩ pull-up.
29
28
BR
I
State Control Input. B0, B1, B2, and BR determine the state of the SLIC.
See Table 3. Pin BR has a 40 kΩ pull-up.
—
29
NC
—
No Connection. May be used as a tie point.
—
30
NC-NTP
—
No Connection. May not be used as a tie point.
—
31
NC
—
No Connection. May be used as a tie point.
30
32
TG
—
Transmit Gain. Connect a 4.32 kΩ resistor from this pin to VTX.
31
32
1
33
34
35
VTX
TXI
O
—
The voltage at this pin is directly proportional to the differential tip/ring current.
ac/dc Separation. Connect a 0.1 µF capacitor from this pin to VTX.
NSTAT
O
Loop Detector Output/Ring Trip Detector Output. This output is a wiredOR of the NLC/NRDET outputs. When low, this logic output indicates that an
off-hook condition exists or that ringing has been tripped.
2
—
VEE
—
–5 V Power Supply L8560C.
2
—
NC
—
No Connection L8560A/D/F. May be used as a tie point.
—
36
NC
—
No Connection. May be used as a tie point.
3
37
VITR
O
4
38
RCVP
I
5
39
RCVN
I
—
6
40
41
NC
—
ac Output Voltage. This output is a voltage that is directly proportional to the
differential ac tip/ring current.
Receive ac Signal Input (Noninverting). This high-impedance input controls the ac differential voltage on tip and ring.
Receive ac Signal Input (Inverting). This high-impedance input controls the
ac differential voltage on tip and ring.
No Connection. May be used as a tie point.
FB2
—
Polarity Reversal Slowdown. Connect a capacitor to ground.
7
42
FB1
—
8
43
LCTH
I
—
44
DCR
I
Polarity Reversal Slowdown. Connect a capacitor to ground.
Loop Closure Threshold Input. Connect a resistor to DCOUT to set offhook threshold.
dc Resistance. Short to analog ground for dc feed resistance of 55 Ω. The dc
feed resistance can be increased to a nominal 760 Ω by shorting DCR to
DCOUT. Intermediate values can be set by a simple resistor divider from
DCOUT to ground with the trip at DCR (44-pin PLCC only).
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Functional Description
Table 3. Input State Coding
B0
1
B1
1
B2
0
1
0
0
1
1
1
1
0
1
0
1
1
0
0
1
0
1
0
0
0
0
1
1/0
1
BR
State/Definition
1 Powerup, Forward Battery VBAT2. Pin PT is positive with respect to pin PR. VBAT2 is applied
to the tip/ring drive amplifiers. On-hook transmission capability. All supervision active—an
off-hook condition or a ring trip causes output NSTAT to go low.
1 Powerup, Reverse Battery VBAT2. Pin PR is positive with respect to pin PT. VBAT2 is applied
to the tip/ring drive amplifiers. On-hook transmission capability. All supervision active—an
off-hook condition or a ring trip causes output NSTAT to go low.
1 Powerup, Forward Battery VBAT1. Pin PT is positive with respect to pin PR. VBAT1 is applied
to the tip/ring drive amplifiers. On-hook transmission capability. All supervision active—an
off-hook condition or a ring trip causes output NSTAT to go low.
1 Powerup, Reverse Battery VBAT1. Pin PR is positive with respect to pin PT. VBAT1 is applied
to the tip/ring drive amplifiers. On-hook transmission capability. All supervision active—an
off-hook condition or a ring trip causes output NSTAT to go low.
1 Ground Start. Tip drive amplifier is turned off. The device presents a high impedance
(>100 kΩ) to pin PT and a current-limited battery (VBAT1) to pin PR. Output pin RGDET indicates current flowing in the ring lead.
1 Low-Power Scan. Except for off-hook supervision, all circuits are shut down to conserve
power. Only the off-hook detector affects output pin NSTAT. VBAT1 is applied to the tip/ring
drive amplifiers. Pin PT is positive with respect to pin PR. On-hook transmission is disabled.
1 Low-Power Scan (L8560D/E/F/G Only). Except for off-hook supervision, all circuits are shut
down to conserve power. Only the off-hook detector affects output pin NSTAT. V BAT2 is applied to the tip/ring drive amplifiers. Pin PT is positive with respect to pin PR. On-hook transmission is disabled.
1 Forward Disconnect. The tip and ring amplifiers are turned off and the SLIC goes into a
high-impedance state (>100 kΩ). VBAT2 is applied to the SLIC.
0 Ring State. SLIC is powered up. VBAT1 is applied to the tip and ring amplifiers. Current limit
is increased by a factor of 2.8. Overhead voltage is reduced to approximately 2.4 V. These
conditions are necessary to supply sufficient power to drive a true North American 5 REN
ringing load (1386 Ω + 40 µF). Loop closure detector is disabled—only the ring trip detector
affects output pin NSTAT. To apply a balanced ring signal to pins PR and PT, apply a 0 V to
5 V square wave to input pin B1. Ringing frequency is the frequency of the input wave at B1.
To shape the ring signal at pins PR and PT, connect a capacitor from pin FB1 to ground and
from pin FB2 to ground.
Table 4. Supervision Coding
Pin NSTAT
0 = off-hook or ring trip
1 = on-hook and no ring trip
Lucent Technologies Inc.
Pin RGDET
1 = ring ground
0 = no ring ground
9
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Absolute Maximum Ratings (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
5 V Power Supply
–5 V Power Supply (L8560C)
Battery (talking) Supplies
VBAT2 Magnitude
Logic Input Voltage
Analog Input Voltage
Maximum Junction Temperature
Storage Temperature Range
Relative Humidity Range
Ground Potential Difference (BGND to AGND)
PT or PR Fault Voltage (dc)
PT or PR Fault Voltage (10 x 1000 µs)
Current into Ring Trip Inputs
Symbol
VCC
VEE
VBAT1, VBAT2
IVBAT2I
—
—
TJ
Tstg
RH
—
VPT, VPR
VPT, VPR
IRTSP, IRTSN
Value
7.0
–7.0
–75
IVBAT1I + 0.4
–0.5 to +7.0
–7.0 to +7.0
165
–40 to +125
5 to 95
±3
(VBAT1 – 5) to +3
(VBAT1 – 15) to +15
±240
Unit
V
V
V
V
V
V
°C
°C
%
V
V
V
µA
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 the
device ratings. Some of the known examples of conditions that cause such potentials during powerup are 1) an inductor connected to tip
and ring can force an overvoltage on VBAT through the protection devices if the VBAT connection chatters, and 2) inductance in the VBAT
lead could resonate with the VBAT filter capacitor to cause a destructive overvoltage.
10
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Recommended Operating Conditions
Parameter
Ambient Temperature
Loop Closure Threshold-detection Programming Range
dc Loop Current-limit Programming Range
On- and Off-hook 2-wire Signal Level (@ ZLOOP = 200 Ω)
ac Termination Impedance Programming Range
VBAT1
VBAT2
VCC
VEE (L8560C)
dc Feed Resistance Programming Range (excl. RP)
Min
–40
5
5
—
150
–24
–16
4.5
–4.75
55
Typ
—
10
40
—
600
–48
—
5.0
–5.0
55
Max
85
ILIM
50
2.2
1300
–70
VBAT1
5.5
–5.5
760
Unit
°C
mA
mA
Vrms
Ω
V
V
V
V
Ω
Electrical Characteristics
Minimum and maximum values are testing requirements in the temperature range of 25 °C to 85 °C and battery
range of –24 V to –70 V. These minimum and maximum values are guaranteed to –40 °C based on component
simulations and design verification of samples, but devices are not tested to –40 °C in production. The test circuit
shown in Figure 5 is used, unless otherwise noted. Positive currents flow into the device.
Typical values are characteristics of the device design at 25 °C based on engineering evaluations and are not part
of the test requirements. Supply values used for typical characterization are VCC = 5.0 V, VEE = –5.0 V, VBAT1 =
–48 V, VBAT2 = –25.5 V, unless otherwise noted.
Lucent Technologies Inc.
11
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Electrical Characteristics (continued)
Table 5. Power Supply
VCC = 5.0 V, VEE = –5.0 V, VBAT1 = –48 V, VBAT2 = –19 V, unless otherwise noted.
Parameter
Power Supply Rejection 500 Hz to 3 kHz
(See Figures 6, 7, 14, and 15.)1:
VCC (1 kHz), VEE (1 kHz)2
VBAT1, VBAT2 (500 Hz—3 kHz)
Thermal Protection Shutdown (Tjc)
Thermal Resistance, Junction to Ambient (θJA), Still Air, 44-pin PLCC
Thermal Resistance, Junction to Ambient (θJA), Still Air, 32-pin PLCC
Power Supply—Powerup, No Loop Current, VBAT2 Applied
L8560A/D/E/F/G:
ICC
IBAT1
IBAT2
Power Supply—Powerup, No Loop Current, VBAT1 Applied:
ICC (L8560A/D/E/F/G)
IBAT1 (L8560A)
IBAT1 (L8560D/E/F/G)
IBAT2 (L8560D/E/F/G)
Power Supply—Scan Mode, Forward Battery, No Loop Current,
VBAT1 Applied:
ICC (L8560A/D/E/F/G)
IBAT1 (L8560A)
IBAT1 (L8560D/E/F/G)
IBAT2 (L8560D/E/F/G)
Power Supply—Scan Mode, Forward Battery, No Loop Current,
VBAT2 Applied:
ICC
IBAT1 (VBAT1 = –65 V)
IBAT2 (VBAT2 = –30 V)
Power Supply—Powerup, No Loop Current, L8560C Only:
ICC
IEE
IBAT1 (VBAT1 applied)
IBAT2 (VBAT2 applied)
IBAT1 (VBAT2 applied)
Power Supply—Scan, Forward Battery, No Loop Current, VBAT1
Applied, L8560C Only:
ICC
IEE
IBAT (VBAT1 applied)
Power Supply—Ring Mode, No Loop Current:
ICC
IBAT1
Min
Typ
Max
Unit
35
45
—
—
—
—
—
165
47
60
—
—
—
—
—
dB
dB
°C
°C/W
°C/W
—
—
—
6.0
120
2.6
7.2
200
3.2
mA
µA
mA
—
—
—
—
6.0
2.8
1.65
1.0
7.2
3.3
2.0
1.3
mA
mA
mA
mA
—
—
—
—
4.0
1.3
0.5
0.9
5.2
1.6
0.75
1.2
mA
mA
mA
mA
—
—
—
4.1
200
1.2
—
—
—
mA
µA
mA
—
—
—
—
—
5.8
0.9
1.65
1.50
120
7.2
1.26
2.2
1.96
200
mA
mA
mA
mA
µA
—
—
—
4.1
0.81
0.43
5.5
1.1
0.56
mA
mA
mA
—
—
6.45
2.2
—
—
mA
mA
1. This parameter is not tested in production. It is guaranteed by design and device characterization.
2. VEE used for L8560C version only.
12
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Electrical Characteristics
(continued)
Table 6. 2-Wire Port
Parameter
Min
65
Typ
—
Max
—
Unit
Tip or Ring Drive Current = dc + Longitudinal + Signal Currents
Signal Current
15
—
—
mArms
8.5
15
—
mArms
5
—
—
—
50
±5
mA
%
Longitudinal Current Capability per
Wire1
dc Loop Current Limit2:
Programmability Range3
Accuracy (B0 = BR = 5 V, RLOOP = 100 Ω, VBAT1 = –48 V
or VBAT2 = –25.5 V active)
Powerup Open Loop Voltage Levels:
Differential Voltage – V BAT2 (VBAT2 = –25.5 V)
Differential Voltage – V BAT1 (VBAT1 = –48 V)4
Differential Voltage – VBAT1 (ring mode)
Ground Start State:
PT Resistance
dc Feed Resistance (for ILOOP below current limit)
Loop Resistance Range (3.17 dBm overload into 600 Ω; not including protection):
ILOOP = 20 mA at VBAT1 = –48 V
ILOOP = 20 mA at VBAT2 = –24 V
Longitudinal to Metallic Balance—IEEE 5 Std. 455 (See Figure
8.)6, 7:
L8560A/C:
200 Hz to 2999 Hz Forward/Reverse Battery
3000 Hz to 3400 Hz Forward/Reverse Battery
L8560D/E:
200 Hz to 2999 Hz Forward Battery
3000 Hz to 3400 Hz Forward Battery
200 Hz to 2999 Hz Reverse Battery
3000 Hz to 3400 Hz Reverse Battery
L8560F/G:
200 Hz to 2999 Hz Forward/Reverse Battery
3000 Hz to 3400 Hz Forward/Reverse Battery
Metallic to Longitudinal Balance:
200 Hz to 4 kHz
mA
|VBAT2 + 6.9| |VBAT2 + 6.5| |VBAT2 + 6.1|
|VBAT1 + 7.1| |VBAT1 + 6.7| |VBAT1 + 6.3|
|VBAT1 + 5.5| |VBAT1 + 2.4|
—
V
V
V
100
—
—
kΩ
—
55
80
Ω
1940
760
—
—
—
—
Ω
Ω
54
49
59
54
—
—
dB
dB
63
58
58
54
68
63
63
59
—
—
—
—
dB
dB
dB
dB
50
45
55
50
—
—
dB
dB
46
—
—
dB
—
–55
–45
dBV
9.)3:
RFI Rejection (See Figure
0.5 Vrms, 50 Ω Source, 30% AM Mod. 1 kHz
500 kHz to 100 MHz
1. The longitudinal current is independent of dc loop current.
2. Current-limit ILIM is programmed by a resistor, RPROG, from pin IPROG to DCOUT. ILIM is specified at the loop resistance where current limiting
begins (see Figure 22). Select RPROG (kΩ) = 0.616 x ILIM (mA) – onset of current limit with input BR high. When input BR is low, the current
will be increased by a factor of 2.8.
3. This parameter is not tested in production. It is guaranteed by design and device characterization.
4. Specification is reduced to |VBAT1 + 10.5 V| minimum when VBAT1 = –70 V at 85 °C.
5. IEEE is a registered trademark of The Institute of Electrical and Electronics Engineers, Inc.
6. Longitudinal balance of circuit card will depend on loop series protection resistor matching and magnitude.
7. Tested at 1000 Hz only. Full frequency specifications guaranteed by design and device characterization.
Lucent Technologies Inc.
13
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Electrical Characteristics (continued)
Table 7. Analog Pin Characteristics
Parameter
Min
Typ
Max
Unit
—
–200
–41.7
—
—
200
V/A
mV
Loop Closure Detector Threshold1:
Programming Accuracy at 10 mA
—
—
±20
%
Ring Ground Detector Threshold2:
RICM = 83 kΩ
Programming Accuracy
3
—
6
—
10
±25
kΩ
%
—
–8.6
–6.1
IN – 0.5
±10
–8.2
–5.7
IN
—
–7.6
–5.1
IN + 0.5
mV
V
V
µA
RCVN, RCVP:
Input Bias Current
—
–0.2
–1
µA
Loop Closure Detector Hysteresis
Variation
—
—
2
15
—
—
mA
%
THD3 at VPT/PR = 2.2 Vrms, VOH = 12 V, ZT = 200 Ω
—
—
–35
dB
VITR Output Impedance
—
5
—
Ω
VITR Output Offset Voltage
—
20
—
mV
Average/dc Current to FB1 and FB2
Tested as:
(|FB1 (FB) (–5 V)| + |FB1 (FB) (–63 V)| + 2|FB1 (FB) (–35 V)| +
|FB2 (FB) (–5 V)| + |FB2 (FB) (–63 V)| + 2|FB2 (FB) (–35 V)| +
|FB1 (RB) (–5 V)| + |FB1 (RB) (–63 V)| + 2|FB1 (RB) (–35 V)| +
|FB2 (RB) (–5 V)| + |FB2 (RB) (–63 V)| + 2|FB2 (RB) (–35 V)|)/16
—
29
—
µA
Accuracy
—
—
±8
%
Differential PT/PR Current Sense (DCOUT):
Gain (PT/PR to DCOUT)
Offset Voltage @ ILOOP = 0
Ring Trip Comparator:
Input Offset Voltage3
Internal Voltage Source (L8560A/D/E/F)
Internal Voltage Source (L8560C)
Current at Input RTSP4
1. Loop closure threshold is programmed by resistor RLCTH from pin LCTH to pin DCOUT.
2. Ring ground threshold is programmed by resistor RICM2 from pin ICM to VCC.
3. This parameter is not tested in production. It is guaranteed by design and device characterization.
4. IN is the sourcing current at RTSN. Guaranteed if IN is within 5 µA to 30 µA.
Table 8. Uncommitted Op Amp Characteristics (44-Pin PLCC Only)
Parameter
Min
Typ
Max
Unit
Input Offset Voltage
Input Offset Current
Input Bias Current
Differential Input Resistance
—
—
—
—
±5
±10
200
1.5
—
—
—
—
mV
nA
nA
MΩ
Output Voltage Swing (RL = 10 kΩ)
Output Resistance (AVCL = 1)
—
—
±3.5
2.0
—
—
Vpk
Ω
Small-signal GBW
—
700
—
kHz
14
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Electrical Characteristics
(continued)
Table 9. ac Feed Characteristics
Parameter
Min
Typ
Max
Unit
150
—
1300
Ω
—
0
—
Ω
—
—
—
—
0.3
1.0
%
%
Transmit Gain, f = 1 kHz (PT/PR to VITR; see Figure 11.)
–392
–400
–408
V/A
Receive + Gain, f = 1 kHz (RCVP to PT/PR)
Receive – Gain, f = 1 kHz (RCVN to PT/PR)
7.76
–7.76
8.00
–8.00
8.24
–8.24
—
—
—
—
1
0.5
—
—
µs
µs
Gain vs. Frequency (transmit and receive)
(600 Ω termination; reference 1 kHz, 1 Vrms)2:
200 Hz to 300 Hz
300 Hz to 3.4 kHz
3.4 kHz to 16 kHz
16 kHz to 266 kHz
–1.00
–0.3
–3.0
—
0.0
0.0
–0.1
—
0.05
0.05
0.3
2.5
dB
dB
dB
dB
Gain vs. Level (transmit and receive)(reference 0 dBV)2:
–55 dB to +3 dB
–0.05
0
0.05
dB
Return Loss2, 3:
200 Hz to 500 Hz
500 Hz to 3400 Hz
—
—
30
36
—
—
dB
dB
2-wire Idle-channel Noise (600 Ω termination):
Psophometric2
C-message
3 kHz Flat2
—
—
—
–87
2
10
–77
12
20
dBmp
dBrnC
dBrn
4-wire Idle-channel Noise:
Psophometric2
C-message
3 kHz Flat2
—
—
—
–82
7
15
–77
12
20
dBmp
dBrnC
dBrn
Transhybrid Loss3:
200 Hz to 500 Hz
500 Hz to 3400 Hz
—
—
30
36
—
—
dB
dB
ac Termination
Impedance1
Longitudinal Impedance
2
Total Harmonic Distortion—200 Hz to 4 kHz :
Off-hook
On-hook
Group Delay2:
Transmit, Powerup
Receive
1. Set by external components. Any complex impedance R1 + R2 || C between 150 Ω and 1300 Ω can be synthesized.
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 external components. Not tested in production.
Lucent Technologies Inc.
15
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Electrical Characteristics (continued)
Table 10. Logic Inputs and Outputs
Symbol
Min
Typ
Max
Unit
Input Voltages:
Low Level (permissible range)
High Level (permissible range)
Parameter
VIL
VIH
–0.5
2.0
0.4
2.4
0.7
VCC
V
V
Input Currents:
Low Level (VCC = 5.25 V, VI = 0.4 V)
High Level (VCC = 5.25 V, VI = 2.4 V)
IIL
IIH
–75
–40
–115
–60
–300
–100
µA
µA
VOL
VOH
0
2.4
0.2
—
0.4
VCC
V
V
Output Voltages (open collector with internal pull-up resistor):
Low Level (VCC = 4.75 V, IOL = 360 µA)
High Level (VCC = 4.75 V, IOH = –20 µA)
Ring Trip Requirements
■
■
■
200 Ω
Ringing signal:
— Voltage, minimum 35 Vrms, maximum 100 Vrms.
— Frequency, 17 Hz to 23 Hz.
— Crest factor, 1.4 to 2.
TIP
Ringing trip:
— ≤100 ms (typical), ≤250 ms (VBAT = –33 V, loop
length = 530 Ω).
TIP
RING
SWITCH CLOSES < 12 ms
6 µF PER TA 909
8 µF PER TR 57
RING
10 kΩ
Pretrip:
— The circuits in Figure 4 will not cause ringing trip.
2 µF
100 Ω
TIP
RING
12-2572.e (F)
Figure 4. Ring Trip Circuits
16
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Test Configurations
VBAT2
0.1 µF
VCC
0.1 µF
VBAT1
0.1 µF
FOR 44-PIN PLCC
VBAT2 VBAT1
TIP
BGND
VCC
AGND
VITR
100 Ω
20 kΩ
PT
SN
20 kΩ
XMT
XMT
RLOOP
RING
66.5 kΩ
100 Ω
RCVN
PR
30.9 kΩ
RCV
RCVP
13.7 kΩ
DCOUT
L8560
SLIC
23.7 kΩ
IPROG
VITR
66.5
kΩ
8.25 kΩ
LCTH
RCV
30.9 kΩ
2 MΩ
RTSP
BS1
402 kΩ
2 MΩ
FOR 32-PIN PLCC
BS2
RTSN
274 kΩ
13.7
kΩ
B0
ICM
100 Ω
100 Ω
B1
VBAT
TG
VTX
TXI FB2
FB1 RGDET NSTAT
0.1 µF
4.32 kΩ
BR
B2
100 Ω
100 Ω
12-2570.f (F)
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
V CC
67.5 Ω
TIP
TIP
+
900 Ω
VT/R
–
DISCONNECT
BYPASS CAPACITOR
10 µF
BASIC
TEST CIRCUIT
+
VM
–
RING
PSRR = 20log
VS
VT/R
BASIC
TEST CIRCUIT
67.5 Ω
56.3 Ω
RING
10 µF
PSRR = 20log
VS
VM
12-2583.b (F)
12-2582.b (F)
Figure 6. Metallic PSRR
Lucent Technologies Inc.
Figure 7. Longitudinal PSRR
17
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Test Configurations (continued)
ILONG
100 µF
TIP
+
VPT
–
TIP
VS
368 Ω
+
BASIC
TEST CIRCUIT
VM
368 Ω
–
ILONG
RING
BASIC
TEST CIRCUIT
–
VPR
+
100 µF
RING
LONGITUDINAL BALANCE = 20 log
VS
VM
ZLONG =
∆VPR
∆ VPT
OR
∆ ILONG
∆ ILONG
12-2585.a (F)
12-2584.c (F)
Figure 10. Longitudinal Impedance
Figure 8. Longitudinal Balance
0.01 µF
82.5 Ω
TIP
600 Ω
50 Ω
VS
1
6, 7
0.01 µF
L7590
2.15 µF
4
2
VBAT
XMT (44-PIN PLCC)
TIP
BASIC TEST
CIRCUIT
RING
600 Ω
VT/R
–
82.5 Ω
VITR (32-PIN PLCC)
+
BASIC
TEST CIRCUIT
RCV
RING
HP * 4935A
TIMS
VS
5-6756.a (F)
* HP is a registered trademark of Hewlett-Packard Company.
Notes:
VS = 0.5 Vrms 30% AM 1 kHz modulation.
f = 500 kHz—1 MHz.
VXMT
GXMT = VT/R
GRCV =
VT/R
VRCV
Device in powerup mode 600 Ω termination.
12-2587.d (F)
Figure 11. ac Gains
Figure 9. RFI Rejection
18
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications
Characteristic Curves
0
0
–10
SPEC. RANGE
–20
PSRR (dB)
–10
RECEIVE GAIN
(dB)
–20
–30
CURRENT
LIMIT
–30
–40
BELOW
–50 CURRENT
LIMIT
–60
HYBRID BALANCE
–40
–50
100
–70
–80
10
1000
104
100
1000
105
104
105
106
FREQUENCY (Hz)
FREQUENCY (Hz)
12-2830.a (F)
12-2828.c (F)
Figure 12. L8560 Receive Gain and Hybrid Balance
vs. Frequency
Figure 14. L8560 Typical VCC Power Supply
Rejection
0
–10
0
–20
PSRR (dB)
TRANSMIT GAIN
–10
(dB)
–20
CURRENT
LIMIT
–30
–40
SPEC. RANGE
–50
–60
–30
BELOW
CURRENT
LIMIT
–70
RETURN LOSS
–80
–40
10
–50
100
100
1000
104
105
106
FREQUENCY (Hz)
1000
10 4
10 5
12-2871.a (F)
FREQUENCY (Hz)
12-2829.b (F)
Figure 15. L8560 Typical VBAT Power Supply
Rejection
Figure 13. L8560 Transmit Gain and Return Loss
vs. Frequency
Lucent Technologies Inc.
19
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Characteristic Curves (continued)
20
40
LOOP CURRENT (mA)
50
OFF-HOOK THRESHOLD LOOP CURRENT
(mA)
25
15
10
ILIM TESTED
1
12.5 kΩ
30
ILIM ONSET
20
–1
R dc1
10
5
0
0
0
0
10
20
40
30
50
10
60
20
30
LOOP VOLTAGE (V)
40
50
12-3050.k (F)
LOOP CLOSURE THRESHOLD RESISTOR, RLCTH (kΩ)
12-3015 (F)
Note: VBAT1 = –48 V; ILIM = 22 mA; Rdc1 = 55 Ω.
Note: VBAT1 = –48 V, ITR = 1.2 x 10–3 RLCTH (kΩ).
Figure 18. Loop Current vs. Loop Voltage
Figure 16. Loop Closure Program Resistor
Selection
LOOP CURRENT (mA)
THRESHOLD RING GROUND CURRENT (mA)
50
35
30
25
20
40
30
20
10
15
10
0
0
5
500
1000
1500
2000
LOOP RESISTANCE, RLOOP (Ω)
0
12-3051 (F)
0
20
40
60
80
100
120
140
RING GROUND CURRENT
DETECTION RESISTOR, RICM (kΩ)
Note: VBAT1 = –48 V; ILIM = 22 mA; Rdc1 = 55 Ω.
Figure 19. Loop Current vs. Loop Resistance
12-3016.f (F)
Note: Tip lead is open; VBAT1 = –48 V.
Figure 17. Ring Ground Detection Programming
20
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
dc Applications
Characteristic Curves (continued)
Battery Feed
The dc feed characteristic can be described by:
SLIC POWER DISSIPATION (mW)
1500
V T/R =
IL =
1000
( V B AT – V O H ) × R L
-------------------------------------------R L + 2R P + R d c
VBAT – VOH
---------------------------------
R L + 2R P + R dc
where:
IL = dc loop current.
VT/R = dc loop voltage.
|VBAT| = battery voltage magnitude.
500
0
0
500
1000
1500
2000
LOOP RESISTANCE, RLOOP (Ω)
12-3052 (F)
Note: VBAT1 = –48 V; ILIM = 22 mA; Rdc1 = 55 Ω.
Figure 20. L8560 Typical SLIC Power Dissipation
vs. Loop Resistance
Note: The L8560 has a battery switch circuit that
allows use of a primary battery, VBAT1, or an auxiliary battery, VBAT2. |VBAT| is the battery, VBAT1 or
VBAT2, that is active. See the Battery Switch section for more information.
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 22.
2000
1750
50
300 cu. ft./min.
44-PIN PLCC
1250
LOOP CURRENT (mA)
POWER (mW)
1500
STILL AIR
44-PIN PLCC
1000
750
STILL AIR
32-PIN PLCC
500
250
40
ILIM TESTED
1
12.5 kΩ
30
ILIM ONSET
20
–1
R dc1
10
0
20
40
60
80
100
120
140
160 180
0
0
AMBIENT TEMPERATURE, TA (°C)
12-2825.e (F)
10
20
30
LOOP VOLTAGE (V)
50
40
12-3050.k (F)
Figure 21. Power Derating
Note: VBAT1 = –48 V; ILIM = 22 mA; Rdc1 = 55 Ω.
Figure 22. Loop Current vs. Loop Voltage
Lucent Technologies Inc.
21
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Tip/ring voltage where current-limit onsets (VT/Ronset):
dc Applications (continued)
( V BAT – V OH ) × R Lonset
VT/Ronset = ------------------------------------------------------------------R Lonset + 2R P + Rdc
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,
Rdc1 (default is 55 Ω typical). The open circuit voltage
is the battery voltage less the overhead voltage of the
device, VOH (default is 6.7 V typical). These values are
suitable for most applications but can be adjusted if
needed. For more information, see the sections titled
Adjusting dc Feed Resistance or Adjusting Overhead
Voltage.
Region 2: Current limit. The dc current is limited to a
starting value determined by external resistor RPROG, an
internal current source, and the gain from tip/ring to pin
DCOUT. Current limit is set by the equation:
IPROG x RPROG = ILIM x BDCOUT
Where:
IPROG = the current from an internal current source
RPROG = the external resistor used to set the current
limit
BDCOUT = the transconductance from tip/ring to
DCOUT, which is nominally 41.67 V/A
During nonringing modes, the internal current source is
set at 75 µA, thus:
IPROG x RPROG = ILIM x BDCOUT
RPROG = ILIM x BDCOUT/IPROG
RPROG (K) = ILIM (mA) x 0.04167 (V/mA)/75e–3 (mA)
Tip/ring voltage when loop resistance is Rloop (VT/Rloop):
VT/Rloop (V) = Iloop (mA) x RLOOP (Ω)/1000
Loop current is now given by:
Iloop (mA) = ILonset (mA) + (VT/Ronset – VT/Rloop)
(V)/12.5 (kΩ)
or
I Lonset ( mA ) + V T ⁄ Ronset ( V ) ⁄ 12.5 ( kΩ )
Iloop (mA) = -----------------------------------------------------------------------------------------------------------1 + R loop ( Ω ) ⁄ 12500 ( kΩ )
Current limit is not sensitive to temperature variation.
Overhead Voltage
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:
VOH = |VBAT| – (VPT – VPR)
Without this buffer voltage, amplifier saturation will
occur and the signal will be clipped. The L8560 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
VT/R = 4 V  ---------------------------------
Z T/R + 2R P
RPROG (K) = 0.556 x ILIM (mA)
Testing data shows that:
RPROG (K) = 0.616 x ILIM (mA)
This equation is a first-order estimation of the loop current at current-limit range.
For more precise loop current at current-limit range, the
loop current is also determined by loop length, protection resistance, and battery voltage. It can be shown
through calculations as follows:
Current-limit onset (ILonset):
For applications where higher signal levels are needed,
e.g., periodic pulse metering, the 2-wire port of the
SLIC can be programmed with pin DCR (pin DCR is
not available in the 32-pin PLCC package). The first
step is to determine the amount of overhead voltage
needed. The peak voltage at output of tip and ring
amplifiers is related to the peak signal voltage by:
Λ
Λ
V A MP = V T/R  1 +

2R P 
----------Z T/R 
R PROG ( K )
ILonset (mA) = --------------------------------0.616
Loop resistance where current-limit onsets (RLonset):
( V BAT – V OH ) ( V )
RLonset (Ω) = -------------------------------------------------- x 1000 – 2RP – Rdc
I Lonset ( mA )
22
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
the case of –5 V, the overhead voltage will be independent of the battery voltage. Figure 24 shows the equivalent input circuit to adjust the overhead.
dc Applications (continued)
RP
VT/R
R1
+
+
[ZT/R]
VAMP
–
DCR
–
R2
RP
12-2563.c (F)
–5 V
Figure 23. SLIC 2-Wire Output Stage
In addition to the required peak signal level, the SLIC
needs about 2 V from each power supply to bias the
amplifier circuitry. It can be thought of as an internal
saturation voltage. Combining the saturation voltage
and the peak signal level, the required overhead can
be expressed as:
VOH
12-2562.b (F)
Figure 24. Equivalent Circuit for Adjusting the
Overhead Voltage
The overhead voltage is programmed by using the following equation:
VOH = 7.1 – 18.18 VDCR
R1
= 7.1 – 18.18  – 5 ×  --------------------- 
R2 + R1
2R P Λ
= V S AT +  1 + ----------- V T/R

Z T/R 
2R P
Z T/R
= V SA T +  1 + ----------- 2-------------- x 10dBm/20
Z T/R
1000
where VSAT is the combined internal saturation voltage
between the tip/ring amplifiers and VBAT (4.0 V typ.). RP
(Ω) is the protection resistor value. ZT/R (Ω) is the ac
loop impedance.
Example 1, On-Hook Transmission of a Meter
Pulse:
Signal level: 2.2 Vrms into 200 Ω
35 Ω protection resistors
ILOOP = 0 (on-hook transmission of the metering signal)
2 × 35
VOH = 4.0 +  1 + ----------------- 2 (2.2)
200
Adjusting dc Feed Resistance
The dc feed resistance may be adjusted with the help
of Figure 25.
44-PIN PLCC
R1
DCR
R3
DCOUT
= 8.2 V
Accounting for VSAT tolerance of 0.5 V, a nominal overhead of 8.7 V would ensure transmission of an undistorted 2.2 V metering signal.
12-2560.c (F)
Figure 25. Equivalent Circuit for Adjusting the dc
Feed Resistance
∆V DCR
∆V DCOUT
Adjusting Overhead Voltage
Rdc = 55 Ω + 705 Ω --------------------------
To adjust the open loop 2-wire voltage, pin DCR
(44-pin PLCC only) is programmed at the midpoint of a
resistive divider from ground to either –5 V or VBAT. In
R1
= 55 Ω + 705 Ω  ---------------------
R3 + R1
Lucent Technologies Inc.
23
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Off-Hook Detection
dc Applications (continued)
The loop closure comparator has built-in longitudinal
rejection, eliminating the need for an external 60 Hz filter. This applies in both powerup and low-power scan
states. The loop closure detection threshold is set by
resistor RLCTH. Referring to Figure 27, NLC is high in an
on-hook condition (ITR = 0, VDCOUT = 0) and
VLCTH = 0.05 mA x RLCTH. The off-hook comparator
goes low when VLCTH crosses zero and then goes negative:
VLCTH = 0.05 mA x RLCTH + VDCOUT
= 0.05 x RLCTH – 0.04167 V/mA x ITR
RLTCH (kΩ) = 0.833 ITR (mA)
Adjusting Overhead Voltage and dc Feed
Resistance Simultaneously
The above paragraphs describe the independent setting of the overhead voltage and the dc feed resistance. If both need to be set to customized values,
combine the two circuits as shown in Figure 26.
Testing data shows that:
RLTCH (kΩ) = 0.899 ITR (mA)
R1
DCR
R2
R3
RP
–5 V
TIP
ITR
DCOUT
+
RL
–0.04167 V/mA
DCOUT
–
RLCTH
RING
12-2561.d (F)
LCTH
RP
Figure 26. Adjusting Both Overhead Voltage and dc
Feed Resistance
This is an equivalent circuit for adjusting both the dc
feed resistance and overhead voltage together.
The adjustments can be made by simple superposition
of the overhead and dc feed equations:
VOH
R 1 || R 3
= 7.1 + 40  -----------------------------------
R 2 + R 1 || R 3
R1
Rdc = 55 kΩ + 705 Ω  ---------------------
R2 + R1
Lower-value resistors can be used; the only disadvantage is the power consumption of the external resistors.
Loop Range
The equation below can be rearranged to provide the
loop range for a required loop current:
RL =
24
V BA T – V O H
--------------------------- – 2R P – R d c
IL
0.05 mA
+
–
NLC
12-2553.d (F)
Figure 27. Off-Hook Detection Circuit
Note that NLC is internally wired-OR with the output of
the ring trip detector (NRDET). The wired-OR, NSTAT,
is a package output pin.
Note that if NSTAT is used to directly control logic input
B2, connect a 0.01 µF capacitor from node LCTH to
ground for filtering purposes. In this mode of operation,
the L8560 will automatically switch to the lower-voltage
battery under off-hook conditions.
Also note that NSTAT will toggle low with a ring ground
in the ground start application. Under a ring ground,
one-half of the current appears as differential. This total
ring ground current is approximately two times the current limit; thus, the differential current is approximately
equal to the current limit, which typically exceeds the
loop closure threshold. Thus, in the ground start application, if RGDET trips, NSTAT will also trip. Under this
condition, via software, ignore the NSTAT transition.
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Derating
dc Applications (continued)
Thermal considerations can affect the choice of a
32-pin PLCC or a 44-pin PLCC package. Operating
temperature range, maximum current limit, maximum
battery voltage, minimum dc loop, and protection resistor values will influence the overall thermal performance. This section shows the relevant design
equations and considerations in evaluating the SLIC
thermal performance.
Ring Ground Detection
Pin ICM sinks a current proportional to the longitudinal
loop current. It is also connected to an internal comparator whose output is pin RGDET. In a ground start
application where tip is open, the ring ground current is
half differential and half common mode. In this case, to
set the ring ground current threshold, connect a resistor RICM from pin ICM to VCC. Select the resistor
according to the following relation:
V CC × 120
---------------------I RG ( mA )
RICM (kΩ) =
The above equation is shown graphically in Figure 17.
It applies for the case of tip open. The more general
equation can be used in ground key applications to
detect a common-mode current ICM:
RICM (kΩ) =
V CC × 60
---------------------ICM ( mA )
Longitudinal Balance
First, consider the L8560 SLIC in a 44-pin PLCC package. The still-air thermal resistance is 47 °C/W; however, this number implies zero airflow as if the L8560
were totally enclosed in a box. A more realistic number
would be 43 °C/W. This is an experimental number that
represents a thermal impedance with no forced airflow
(i.e., from a muffin fan) but from the natural airflow as
seen in a typical switch cabinet.
The SLIC will enter the thermal shutdown state at typically 165 °C. The thermal shutdown design should
ensure that the SLIC temperature does not reach
165 °C under normal operating conditions.
Assume a maximum ambient operating temperature of
85 °C, a maximum current limit of 45 mA, and a maximum battery of –52 V. Further, assume a (worst case)
minimum dc loop of 100 Ω and that 100 Ω protection
resistors are used at both tip and ring.
The SLICs are graded with different codes to represent
different longitudinal balance specifications. The numbers are guaranteed by testing (Figures 5 and 8). However, for specific applications, the longitudinal balance
may also be determined by termination impedance,
protection resistance, and especially by the mismatch
between protection resistors at tip and ring. This can
be illustrated by:
2. Allowed thermal rise = package thermal
impedance • SLIC power dissipation.
80 °C = 43 °C/W • SLIC power dissipation
SLIC power dissipation (PD) = 1.9 W
( 368 + RP ) × ( 368 + ZT – RP )
LB = 20 x log ------------------------------------------------------------------------------------------368 × ( 2 × [ ZT – 2 × RP ] × ∆ + ε )
where:
Thus, if the total power dissipated in the SLIC is less
than 1.9 W, it will not enter the thermal shutdown state.
Total SLIC power is calculated as:
LB: longitudinal balance
RP: protection resistor value in Ω
ZT: magnitude of the termination impedance in Ω
ε : protection resistor mismatch in Ω
∆: SLIC internal tip/ring sensing mismatch
The ∆ can be calculated using the above equation with
these exceptions: ε = 0, ZT = 600 Ω, RP = 100 Ω, and
the longitudinal balance specification on a specific
code.
1. TTSD – TAMBIENT(max) = allowed thermal rise.
165 °C – 85 °C = 80 °C
Total PD = maximum battery • maximum
current limit + SLIC quiescent power.
For the L8560, SLIC quiescent power (P Q) is approximated at 0.167 W. Thus,
Total PD = (–52 V • 45 mA) + 0.167 W
Total PD = 2.34 W + 0.167 W
Total PD = 2.507 W
Now with ∆ available, the equation will predict the
actual longitudinal balance for RP, ZT, and ε .
Be aware that ZT may vary with frequency for complex
impedance applications.
Lucent Technologies Inc.
25
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Derating (continued)
The power dissipated in the SLIC is the total power dissipation less the power that is dissipated in the loop.
SLIC PD = Total power – Loop power
Loop power = (ILIM)2 • (RLOOP(dc) min + 2RP)
Loop power = (45 mA)2 • (100 Ω + 200 Ω)
Loop power = 0.61 W
SLIC power = 2.507 W – 0.61 W
SLIC power = 1.897 W < 1.9 W
Thus, in this example, the thermal design ensures that
the SLIC will not enter the thermal shutdown state.
The next example uses the 32-pin PLCC package and
demonstrates the technique used to determine the
maximum allowed current.
In this example, assume a 0 °C to 70 °C operating
range. Thus,
TTSD – TAMBIENT (max) = allowed thermal rise
165 °C – 70 °C = 95 °C
To estimate the open-air thermal impedance, use the
43 °C/W parameter from the 44-pin PLCC and ratio the
lead count.
44
Thermal impedance (32-pin PLCC) = 48 °C/W • ------32
= 59 °C/W
Again:
Allowed thermal rise = thermal impedance • SLIC
power dissipation
95 °C = 59 °C/W • SLIC power dissipation
SLIC PD = 1.6 W
In this example, again assume the dc loop + 2 • protection resistors = 300 Ω, then:
(ILIM)(VBAT max) + PQ – (ILIM)2 (Rdc + 2 RP) = 1.6 W
I • 52 + 0.167 – I2 300 = 1.6 W
300 I2 – 52 I + 1.433 = 0
This is a quadratic equation whose solution is in the
form:
2
–b ± b – 4ac
X = ---------------------------------------2a
2
± 52 – (4)(300)(1.433)
ILIM = 52
-------------------------------------------------------------------------------2(300)
52 ± 31.4
ILIM = -----------------------------600
26
Ignore the “+” term:
– 31.4
ILIM = 52
------------------------- = 34 mA
600
Thus, 34 mA is the maximum allowable current limit in
the 32-pin PLCC package under the conditions given in
this example.
This type of analysis should be performed under the
conditions of the user’s particular application to ensure
adequate thermal design.
Battery Switch
The L8560 SLIC provides an input for an auxiliary battery. Called VBAT2, this power supply should be lower in
magnitude than the primary battery VBAT1. Under an
acceptable loop condition, VBAT2 can be switched to
provide the loop power through the amplifiers of the
SLIC. The dc template, described in previous sections,
is determined by the battery that is active—either VBAT1
or VBAT2.
There are several important applications where use of
a lower-voltage battery in the off-hook state is desired
to provide dc current to the loop, yet a higher-voltage
battery is desired in on-hook or ringing modes. These
applications are typically short-loop applications, such
as an ISDN terminal adapter, fiber-in-the-loop applications, or a cable telephony interface.
Typically, in these applications, the maximum dc loop
resistance (which includes the off-hook telephone
handset plus twisted-cable pair) is relatively low. For
example, Bellcore TA-909, Generic Requirements and
Objectives for Fiber in the Loop Systems, specifies that
in the off-hook state, 20 mA must be provided into a
430 Ω dc loop. To meet these requirements, a lower
battery in the off-hook condition is important to minimize off-hook power consumption. Power conservation
is important from a cost of energy point of view and is
vital in remotely powered POTS interface applications.
While use of a low-voltage battery in off-hook short dc
loops is important, certain on-hook applications, such
as providing a balanced power ring signal or maintaining compatibility with certain CPE such as answering
machines, may require a higher magnitude battery.
With the logic-controlled battery switch, the L8560 is
able to provide a higher-voltage battery to meet onhook battery voltage requirements. At the same time,
the L8560 can accept a lower-voltage auxiliary battery
during short-loop, off-hook applications. If a dc/dc converter with two fixed voltage outputs is used, tie the
battery voltage that is higher in magnitude to VBAT1 and
the voltage that is lower in magnitude to VBAT2. If it is
Lucent Technologies Inc.
Data Sheet
April 2000
Applications (continued)
Battery Switch (continued)
desired to use a single battery supply or a dc/dc converter with a single programmable voltage output, tie
VBAT1 to VBAT2 and connect the battery to this node.
Note that VBAT1 is forced during the balanced ringing
state.
VCC/VEE Supplies
The L8560A/D/E/F SLICs are designed to operate
using battery and only a 5 V power supply. In this mode
of operation, power for the tip/ring drive amplifiers, dc
feedback loop, internal amplifiers, logic, ac, and reference circuits is drawn from the negative battery (and
5 V supply).
While the L8560A/D/E/F type devices offer very low
power dissipation in both the sleep and active states,
further reduction in power dissipation is possible by use
of battery and +5 V and –5 V power supplies. The
L8560C operates using battery, +5 V, and –5 V power
supplies. When the –5 V is used, the internal amplifiers, logic, ac, and reference circuits draw power from
the negative –5 V supply, not the negative battery.
Since the magnitude of the –5 V supply is less than the
battery, power consumption is reduced. With the
L8560C, the tip/ring drive amplifiers and dc feedback
loop still draw power from the battery.
Power Ringing
The L8560 ringing SLIC is designed with the capability
of generating balanced power ring signal to tip and
ring. Because the SLIC itself generates the power ringing signal, no ring relay is needed in this mode of operation. Alternatively, the L8560 SLIC can also be used in
the more standard 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 SLIC from, and apply the ring generator to,
the tip and ring pair.
This section discusses in detail the use of the L8560
ringing SLIC in either mode of application.
L8560 Low-Power SLIC with Ringing
with respect to PR or vice versa. If a square wave signal is added to B1, the SLIC will be operating consecutively at battery forward, and then battery reversal. The
differential output at PT and PR can be a balanced
power ringing signal. Its frequency is equal to that of
the square wave at B1. Its slew rate is determined by
the size of the capacitors CFB1 and CFB2.
If a sinusoidally modulated pulse-width-modulation
(PWM) signal is applied to B1, the differential output at
PT and PR will be sinusoidal. Theoretically, it provides
power ringing in a sinusoidal format. For more information, please refer to the L8560 Sinusoidal Ringing Generation Using a PWM Input to B1 Application Note.
POTS for ISDN Terminal Adapters
The L8560 ringing SLIC is designed to provide a balanced power ring signal to tip and ring. This mode of
operation is suited for short-loop, plain old telephone
service (POTS) applications, such as ISDN terminal
adapters (TA).
When ISDN was first visualized, it was thought that we
would all exchange our existing telephones for new,
full-feature ISDN phones. Digital technology would
drive these sets to very low costs. While this may happen in the future, the current demand is for the ISDN
TA to service a standard analog telephone. The challenges of this application are discussed here along with
a suggested solution.
Until recently, POTS has been the exclusive domain of
the service provider. Over its 100-year history, any
architectural change was always required to be compatible with the existing installed local loop plant and all
telephone sets.
If this is the expectation of the TA, it would be capable
of being connected into the residence phone wiring to
drive every phone in the house. It would also be
designed with enough backup battery to provide uninterrupted service during electrical power interruptions.
In this case, adherence to a standard, such as
Bellcore’s TA-909, is recommended.
For the case where a TA is only going to provide limited
service, the design can be made less costly by limiting
the scope of the device. An example of this limited
scope would be the provision of analog jacks for a FAX/
modem and a phone set near the TA in a home office
environment. A block diagram of a POTS design is outlined in Figure 28.
Ringing SLIC Balanced Ring Signal Generation
The internal dc current source drives current into or
pulls current out from CFB1 and CFB2 depending on
whether the SLIC is operating at battery forward or at
battery reversal. The voltage at PT then will be positive
Lucent Technologies Inc.
27
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Ringing (continued)
TO ISDN
SERVICE
TO
TELEPHONE SET
XMT
RJ-11
PROT.
CODEC
SLIC
RINGER
TDM
DX, DR
CLK, FS
ISDN
TA
RJ-45
RCV
µP
DTMF
DECODER
12-3286
Figure 28. POTS Controlled from an ISDN Terminal Adapter
Power Ringing Load
80
60
VOLTS (V)
Bellcore TA-909 specifies that a minimum 40 Vrms
must be delivered to a 5 REN ringing load of 1380 Ω +
40 µF. During the ringing state, VBAT1 is automatically
applied to the tip/ring power amplifiers. For 5 REN
load, it is recommended that VBAT1 be set to –65 Vdc.
Also during the power ring state, the dc current limit is
automatically boosted by a factor of 2.8 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 1380 Ω + 40 µF.
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)
Crest Factor
In a real application, the ringing trapezoidal waveform
crest factor can be estimated by:
1
Crest factor = -----------------------------------------------------------------------------------------4 × f × C FB × ( V BAT – V OH )
1 – ---------------------------------------------------------------------------3 × I CS
Where: f = ringing frequency; CFB = (CFB1 + CFB2)/2;
ICS = 29 µA @ ±8% accuracy over temperature;
VOH = SLIC overhead during ring.
Figure 29. Ringing Waveform Crest Factor = 1.6
80
60
VOLTS (V)
The balanced trapezoidal ring signal is generated by
simply toggling the SLIC between the powerup state
forward and powerup reverse battery states. The state
change is done by applying a square wave (whose frequency is the desired ring frequency) to logic input B1.
Capacitors FB1 and FB2 are used to control or ramp
the speed of the transition of the battery reverse, thus
shaping the balanced ring signal. Waveforms of crest
factors 1.6 and 1.2 are shown in Figure 29 and Figure
30.
12-3346a (F)
Note: Slew rate = 5.65 V/ms; trise = tfall = 23 ms; pwidth = 2 ms;
period = 50 ms.
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)
Note: Slew rate = 10.83 V/ms; trise = tfall = 12 ms; pwidth = 13 ms;
period = 50 ms.
Figure 30. Ringing Waveform Crest Factor = 1.2
28
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
hook 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 ground.
Power Ringing (continued)
Current-Limit Switch
Output NSTAT is automatically set to detect ring trip
during the balanced ring mode. During quiet intervals
of ringing, output NSTAT is automatically determined
by the loop closure detector.
During nonringing modes, the internal current source is
set at 75 µA. During the ring mode, the current limit is
automatically increased by a factor of 2.8. This is done
to provide sufficient ring to a true North American 5
REN load. This is done internally by increasing the
value of IPROG from 75 µA to 210 µA, thus:
The equivalent ring trip circuit for the balanced ringing
SLIC application is shown in Figure 31.
IPROG • RPROG = lLIM • BDCOUT
RPROG = lLIM • BDCOUT/IPROG
RPROG(K) = lLIM (mA) • 0.04167 (V/mA)/210e–3 (mA)
RPROG(K) = 0.198 • lLIM (mA)
In the current-limit region, the dc template has a high
resistance (12.5 kΩ).
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, on-
The equations governing ring trip are derived below.
Capacitors C2 and C4, in conjunction with resistors R2
and R4, form a double-pole, low-pass filter that
smooths the voltage seen at DCOUT. The poles of the
filters are determined by C2 and C4. Where these poles
are set 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. For the
derivation of the ring trip threshold equations, capacitors C2 and C4 can be ignored.
Redrawing the circuit, ignoring the capacitors, and taking the Thevenin equivalent circuit of the network at
RTSN gives the results shown below in Figure 32.
NLC
C4
RTSP
IP = IN
R4
+
–
IN
R1
NRDET
8.2 V
NSTAT
R2
DCOUT
R3
RTSN
C2
15 kΩ
12-3349.b (F)
Figure 31. Equivalent Ring Trip Circuit for Balanced Ringing SLIC
NLC
R4
RTSP
IP = IN
+
–
IN
NRDET
8.2 V
NSTAT
R2
(R3/[R1 + R3]) DCOUT
R1R3/(R1 + R3)
RTSN
15 kΩ
12-3348.b (F)
Figure 32. Thevenin Equivalent Ring Trip Circuit for Balanced Ringing SLIC
Lucent Technologies Inc.
29
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Ringing (continued)
I R T SN
R3
 -----------------
 R 3 + R 1 V DCOUT – ( –8.2 V )
= ---------------------------------------------------------------------R1R3
+ R 2 + 15 kΩ
-----------------R1 + R3
At the trip point, the internal current repeater will force IRTSP to be equal to IRTSN and VRTSP will be equal to VRTSN,
which is –8.2 V. Thus, at the trip point:
0 – ( –8.2 )
I RTSN = I RTSP = ------------------------R4
Thus:
R3 
 -------------------- V DCOUT + 8.2 V
 R 3 + R 1
8.2 V
----------------------------------------------------------------------- = -------------R1R3
R4
--------------------- + R 2 + 15 kΩ
R1 + R3
Solving for VDCOUT, the voltage at DCOUT at the ring trip point is given by:
R2
R1
15 kΩ 1
V DCOUT = 8.2 ( R 3 + R 1 ) ------------------------------------ + --------------- + ---------------- – ------R1R4 + R3R4 R 3R 4 R3R4 R3
(TRIP)
The loop current at ring trip is given by:
ILOOP(TRIP) = (VDCOUT)/(βDCOUT)
For the L8560, the gain (β) at pin DCOUT is 41.67 V/A.
Capacitors C2 and C4, along with resistors R2 and R4, respectively, form low-pass filters to filter the ac voltage seen
at DCOUT before it is applied to the ring trip comparator input. The lower the pole of the filter, the less the ripple,
but also the slower the state transition at NSTAT. Poles in the neighborhood of 2.5 Hz—3 Hz are suggested, as
given by:
1
fLP = ----------------------2πR 2 C 2
1
fLP = ----------------------2πR 4 C 4
In the reference designs discussed in the next section, the ring trip threshold is set for 50 mA with:
R1 = 210 kΩ
R2 = 124 kΩ
C2 = 0.1 µF
R3 = 562 kΩ
R4 = 351 kΩ
C4 = 0.1 µF
Except for L8560CAU, the internal voltage for L8560CAU is –5.7 V. 133 kΩ should be used for R1.
30
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Ringing (continued)
Reference Designs for ISDN TA Applications
A POTS circuit for reference design is shown in Figure 33. In Figure 33, the L8560 SLIC and T8503 codec are
used. The ac circuit is designed per Bellcore TA-909 with a 600 Ω resistive termination and hybrid circuit, with
the transmit gain set for –2 dB and the receive gain set for –4 dB. The T8503 codec is compatible with the T7237
U-interface transceiver and the T7256 SCNT1 interface.
R1 (RTS2)*
210 kΩ
IPROG
CC1
RT6
60.4 kΩ 0.1 µF
VITR
RPROG
14 kΩ
RT3
165 kΩ
BR
B2
B1
B0
CONTROL
INPUTS
RX
71.5 kΩ
RGDET
NTSTAT
ICM
RTSP
DCOUT
SUPERVISION
OUTPUT
R4
(RTSP)
351 kΩ
C4
(CRTSP)
0.1 µF
RTSN
R2
(RTSN)
124 kΩ
LCTH
RLCTH
8.25 kΩ
C2
(RTSN)
0.1 µF
R3
(RTS3)
562 kΩ
RGP
41.2 kΩ
L8560A, D, E, F, G
RGN
30.1 kΩ
1
TG
VTX
TX1
CBAT1
0.1 µF
CBAT2
0.1 µF
CBS
CCC
0.22 µF 0.1 µF
CST
0.1 µF
CFB1
4.7 nF
CFB2
4.7 nF
CF2
CF1
AGND
FB2
FB1
VCC
BGND
PR
VBAT1
RPR
30 Ω
RTG
4.32 kΩ
BS2
RING
6, 7
L7591
4
FGND
16
VFROP
PCM
HIGHWAY
FSX
FSR
MCLK
SYNC
AND
CLOCK
DGND
AGND
DGND
CVDD
0.1 µF
RCVN
VBAT2
BS1
2
RGP2
1.21 kΩ
CGP
220 pF
PT
DR
CC2
0.1 µF
RCVP
RPT
TIP 30 Ω
VBAT
RHB1
143 kΩ
RRCV
178 kΩ
GSX
VFXIN
DX
CTG
27 pF†
VDD
1/2 T8503
CODEC
CB2
0.1 µF
CF1
0.47 µF
CF2
0.1 µF
RST
100 Ω
12-3345.R (F)
* R1 = 133 kΩ for L8560C.
† Required only for L8560A/C versions.
Notes:
TX = –2 dB.
RX = –4 dB.
Termination = 600 Ω.
Hybrid balance = 600 Ω.
Figure 33. POTS Interface with Balanced Ringing Using L8560 SLIC and T8503 Codec
Lucent Technologies Inc.
31
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Power Ringing (continued)
Table 11. Parts List for Balanced Ringing Using T8503 Codec
Name
Value
Integrated Circuits
SLIC
L8560
Protector
L7591
Codec
T8503
Fault Protection
30 Ω fusible
RPT
30 Ω fusible
RPR
Power Supply
0.1 µF, 20%, 100 V
CBAT1
0.1 µF, 20%, 100 V
CBAT2
0.1 µF, 20%, 10 V
CCC
0.47 µF, 20%, 100 V
CF1
0.1 µF, 20%, 100 V
CF2
0.22 µF, 20%, 100 V
CBS
0.1 µF, 20%, 10 V
CST
100 Ω, 1%, 1/8 W
RST
dc Profile/Ringing
4.7 nF, 20%, 100 V
CFB1
CFB2
4.7 nF, 20%, 100 V
14 kΩ, 1%, 1/8 W
RPROG
ac Characteristics
4.32 kΩ, 1%, 1/8 W
RTG
0.1 µF, 20%, 10 V
CB2
0.1 µF, 20%, 10 V
CC1
0.1 µF, 20%, 10 V
CC2
165 kΩ, 1%, 1/8 W
RT3
178 kΩ, 1%, 1/8 W
RRCV
41.2 kΩ, 1%, 1/8 W
RGP
220 pF, 20%, 10 V
CGP
27 pF, 20%, 10 V
CTG*
1.21 kΩ, 1%, 1/8 W
RGP2
30.1 kΩ, 1%, 1/8 W
RGN
60.4 kΩ, 1%, 1/8 W
RT6
71.5 kΩ, 1%, 1/8 W
RX
143 kΩ, 1%, 1/8 W
RHB1
Supervision
8.25 kΩ, 1%, 1/8 W
RLCTH
†
210 kΩ, 1%, 1/8 W
R1 (RTS2)
124 kΩ, 1%, 1/8 W
R2 (RTSN)
0.1 µF, 20%, 50 V
C2 (CRTSN)
562 kΩ, 1%, 1/8 W
R3 (RTS3)
351 kΩ, 1%, 1/8 W
R4 (RTSP)
0.1 µF, 20%, 10 V
C4 (CRTSP)
Function
Subscriber line interface circuit (SLIC).
Secondary protection.
First-generation codec.
Overcurrent protection.
Overcurrent protection.
VBAT filter capacitor.
VBAT filter capacitor.
VCC filter capacitor.
With CF2, improves idle-channel noise.
With CF1, improves idle-channel noise.
Slows battery switch transition.
Loop stability.
Loop stability.
With CFB2, slows rate of forward/reverse battery transition. Sets crest factor of
balanced power ring signal.
With CFB1, slows rate of forward/reverse battery transition. Sets crest factor of
balanced power ring signal.
Sets dc loop current.
Sets internal transmit path gain to 19.2.
ac/dc separation capacitor.
dc blocking capacitor.
dc blocking capacitor.
With RGP and RRCV, sets ac termination impedance.
With RGP and RT3, sets receive gain.
With RT3 and RRCV, sets ac termination impedance and receive gain.
Loop stability.
Loop stability.
Loop stability.
Compensates for input bias offset at RCVN/RCVP.
With RX, sets transmit gain in codec.
With RT6, sets transmit gain in codec.
Sets hybrid balance.
Sets loop closure (off-hook) threshold.
With R2, R3, and R4, sets ring trip threshold.
With R1, R3, and R4, sets ring trip threshold.
With R2, sets pole of low-pass ring trip sense filter.
With R1, R2, and R4, sets ring trip threshold.
With R1, R2, and R3, sets ring trip threshold.
With R4, sets pole of low-pass ring trip sense filter.
* Required for L8560A/L8560C version only.
† Use 133 kΩ for L8560C.
32
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
input. When ringing is being injected, no dc current
flows through RTS1, so the RTSP input is at a lower
potential than RTSN. When enough dc loop current
flows, the RTSP input voltage increases to trip the comparator. In Figure 34, a low-pass filter with a double
pole at 2 Hz was implemented to prevent false ring trip.
Design Considerations
Unbalanced Bused Ring Signal Application
The L8560 SLIC can also be used in the standard 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 SLIC
from, and apply the ring generator to, the tip and ring
pair.
Ring Trip Detection
The ring trip circuit is a comparator that has a special
input section optimized for this application. The equivalent circuit is shown in Figure 34, along with its use
in an application using unbalanced, battery-backed
ringing.
PHONE
HOOK SWITCH
RLOOP
RTSP +
The current IN is repeated as IP in the positive comparator input. The voltage at comparator input RTSP is:
VRTSP = VBAT + ILOOP(dc) x RTS1 + IP x RTSP
Using this equation and the values in the example, the
voltage at input RTSP is –13.2 V during ringing injection
(ILOOP(dc) = 0). Input RTSP is therefore at a level of 5 V
below RTSN. When enough dc loop current flows
through RTS1 to raise its dc drop to 5 V, the comparator
will trip.
= 12.5 mA
2 MΩ
RTS2
= 17.4 µA
5V
ILOOP(dc) = ----------------402 Ω
RTSP
CRTS2
0.27 µF
–8.2 V – (–48)
I N = -------------------------------------2.289 MΩ
In this example:
RC PHONE
RTS1
402 Ω
The following example illustrates how the detection circuit in Figure 34 will trip at a 12.5 mA dc loop current
using a –48 V battery.
RTSN
274 kΩ 2 MΩ
NRDET
IP = IN
CRTS1
0.022 µF
IN
+
–
8.2 V
–
RTSN
15 kΩ
VRING
VBAT
12-3014.c (F)
Figure 34. Ring Trip Equivalent Circuit and
Equivalent Application
The comparator input voltage compliance is VCC to
VBAT, and the maximum current is 240 µA in either
direction. Its application is straightforward. A resistance
(RTSN + RTS2) in series with the RTSN input establishes a
current that is repeated in the RTSP input. A slightly
lower resistance (RTSP) is placed in series with the RTSP
Lucent Technologies Inc.
Except for L8560CAU, the internal voltage for
L8560CAU is –5.7 V.
Note that during ringing in this mode of operation, both
the NLC and NRDET circuits are active. During the
actual ringing, NRDET is connected and NLC is isolated from tip and ring by the ring relay; thus, NSTAT
reflects the status at NRDET. During quiet intervals of
ringing, NLC is connected and NRDET is isolated from
tip and ring by the ring relay; thus, NSTAT reflects the
status at NLC. Thus, during ring cadence, the logic
input that drives the ring relay can be used as an indication as to whether NRDET or NLC appears at output
NSTAT.
A basic loop start reference circuit, using bused
ringing with the L8560 SLIC and T7504 first-generation
codec, is shown in Figure 35. This circuit is designed
for a 600 Ω resistive termination impedance and hybrid
balance. Transmit and receive gains are both set at
0 dB.
33
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Considerations (continued)
CST
0.1 µF
RST
100 Ω
VBAT1
VBAT2
CBAT1
0.1 µF
VCC
CBAT2
0.1 µF
CCC
0.1 µF
CBS
0.22 µF
RPROG
RGX
4.32 kΩ
14 kΩ
IPROG VBAT1
DCOUT
VBAT2
BS1
BS2 VCC
RLCTH
8.25 kΩ
VTX
LCTH
CTG
27 pF*
TG
CB2
0.1 µF
TXI
CROWBAR
PROTECTOR
RT6
49.9 kΩ
TIP RPT
L7581
RELAY
RT3
174 kΩ
L8560
SLIC
RING RPR
RCVP
RING
50 Ω
CROWBAR
PROTECTOR
RRCV
100 kΩ
RGP
41.2 kΩ
RTSP
GSX
CC1
0.1 µF
VITR
TIP
50 Ω
RX
75.0 kΩ
VFXIN
–
DX
+
RHB1
75.0 kΩ
PCM
HIGHWAY
+2.4 V
VFRO
RGP2
1.21 kΩ
CGP
220 pF
CC2
0.1 µF
DR
FSE
FSEP
MCLK
SYNC
AND
CLOCK
ASEL
CONTROL
INPUTS
2.0 MΩ
RTSP
RTS1
402 Ω
CRTS2
0.27 µF
RTS2
274 kΩ
RCVN
CRTS1
0.022 µF
RTSN
2.0 MΩ
VRING
B1
B0
RTSN
CF2
CF1
AGND
BGND
NSTAT
CONTROL
INPUTS
RGN
29.4 kΩ
1/4 T7504
CODEC
SUPERVISION
OUTPUTS
CF1
0.47 µF
VBAT
CF2
0.1 µF
12-3550 (F)
* Required for L8560A/L8560C version only.
Notes:
TX = 0 dB.
RX = 0 dB.
Termination = 600 Ω.
Hybrid balance = 600 Ω.
Figure 35. Basic Loop Start Application Circuit Using T7504 Codec and Bused Ringing
34
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Considerations (continued)
Figure 36 shows the ground start application.
VCC
GROUND START
APPLICATION CIRCUIT
RGDET
100 kΩ
RGDET
RICM2
71.5 kΩ
RGDET
ICM
CICM
0.47 µF
12-3547.a.c (F)
Figure 36. Ground Start Application Circuit
Table 12. Parts List for Loop Start with Bused Ringing and Ground Start Applications
Name
Integrated Circuits
SLIC
Protector
Ringing Relay
Codec
Fault Protection
RPT
RPR
Power Supply
CBAT1
CBAT2
CCC
CF1
CF2
CBS
CST
RST
CTG†
dc Profile
RPROG
Value
Function
—
Crowbar protector*
L7581
T7504
Subscriber line interface circuit (SLIC).
Secondary protection.
Switches ringing signals.
First-generation codec.
50 Ω PTC or fusible
50 Ω PTC or fusible
Protection resistor.
Protection resistor.
0.1 µF, 20%, 100 V
0.1 µF, 20%, 100 V
0.1 µF, 20%, 10 V
0.47 µF, 20%, 100 V
0.1 µF, 20%, 100 V
0.22 µF, 20%, 100 V
0.1 µF, 20%, 10 V
100 Ω, 1%, 1/8 W
27 pF, 20%, 10 V
VBAT filter capacitor.
VBAT filter capacitor.
VCC filter.
With CF2, improves idle-channel noise.
With CF1, improves idle-channel noise.
Slows battery switch transition.
Loop stability.
Loop stability.
Loop stability.
14 kΩ, 1%, 1/8 W
Sets dc loop current.
* Contact your Lucent Technologies account representative for protector recommendations. Choice of this (and all) component(s) should be
evaluated and confirmed by the customer prior to use in any field or laboratory system. Lucent does not recommend use of this part in the
field without performance verification by the customer. This device is suggested by Lucent for customer evaluation. The decision to use a
component should be based solely on customer evaluation.
† Required for L8560A/L8560C version only.
Lucent Technologies Inc.
35
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Considerations (continued)
Table 12. Parts List for Loop Start with Bused Ringing and Ground Start Applications (continued)
Name
Value
ac Characteristics
RGX
4.32 kΩ, 1%, 1/8 W
CB2
0.1 µF, 20%, 10 V
RT3
174 kΩ, 1%, 1/8 W
RRCV
100 kΩ, 1%, 1/8 W
RGP
41.2 kΩ, 1%, 1/8 W
CGP
220 pF, 20%, 10 V
RGP2
1.21 kΩ, 1%, 1/8 W
RGN
29.4 kΩ, 1%, 1/8 W
CC1
0.1 µF, 20%, 10 V
CC2
0.1 µF, 20%, 10 V
RT6
49.9 kΩ, 1%, 1/8 W
RX
75.0 kΩ, 1%, 1/8 W
RHB1
75.0 kΩ, 1%, 1/8 W
Supervision
RLCTH
8.25 kΩ, 1%, 1/8 W
RTS1
402 Ω, 5%, 2 W
RTS2
274 kΩ, 1%, 1/8 W
CRTS1
0.022 µF, 20%, 5 V
CRTS2
0.27 µF, 20%, 100 V
RTSN
2 MΩ, 1%, 1/8 W
RTSP
2 MΩ, 1%, 1/8 W
Ground Start
CICM
0.47 µF, 20%, 10 V
RGDET
100 kΩ, 20%, 1/8 W
RICM2
71.5 kΩ, 1%, 1/8 W
36
Function
Sets internal transmit path gain of 9.6.
ac/dc separation capacitor.
With RGP and RRCV, sets ac termination impedance.
With RGP and RT3, sets receive gain.
With RT3 and RRCV, sets ac termination impedance and receive gain.
Loop stability.
Loop stability.
Compensates for input bias offset at RCVN/RCVP.
dc blocking capacitor.
dc blocking capacitor.
With RX, sets transmit gain in codec.
With RT6, sets transmit gain in codec.
Sets hybrid balance.
Sets loop closure (off-hook) threshold.
Ringing source series resistor.
With CRTS2, forms first pole of a double pole, 2 Hz ring trip sense filter.
With RTSN and RTSP, forms second 2 Hz filter pole.
With RTS2, forms first 2 Hz filter pole.
With CRTS1 and RTSP, forms second 2 Hz filter pole.
With CRTS1 and RTSN, forms second 2 Hz filter pole.
Provides 60 Hz filtering for ring ground detection.
Digital output pull-up resistor.
Sets ring ground detection threshold.
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Considerations (continued)
Table 13 shows the design parameters of the application circuit shown in Figure 35. Components that are adjusted
to program these values are also shown.
Table 13. 600 Ω Design Parameters
Design Parameter
Loop Closure Threshold
dc Loop Current Limit
dc Feed Resistance
2-wire Signal Overload Level
ac Termination Impedance
Hybrid Balance Line Impedance
Transmit Gain
Receive Gain
Parameter Value
10 mA
25 mA
55 Ω
3.14 dBm
600 Ω
600 Ω
0 dB
0 dB
Components Adjusted
RLCTH
RPROG
—
—
RT3, RGP, RRCV
RHB1
RT6, RX
RRCV, RGP, RT3
ac Design
Second-Generation Codecs
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 echo return to
the telephone set. Transmit gain is measured from the
2-wire port to the PCM highway, while receive gain is
done from the PCM highway to the transmit port.
Finally, the hybrid balance network cancels the
unwanted amount of the receive signal that appears at
the transmit port.
This class of devices includes a microprocessor interface for software control of the gains and hybrid balance. The hybrid balance is included in the device. ac
programmability adds application flexibility and saves
several passive components. It also adds several I/O
latches that are needed in the application. It does not
have the transmit op amp, since the transmit gain and
hybrid balance are set internally.
At this point in the design, the codec needs to be
selected. The discrete network between the SLIC and
the codec can then be designed. Below is a brief codec
feature and selection summary.
This class of devices includes the gains, termination impedance, and hybrid balance—all under microprocessor control. Depending on the device, it may or may not
include latches.
First-Generation Codecs
In the codec selection, increasing software control and
flexibility are traded for device cost. To help decide, it
may be useful to consider the following: Will the application require only one value for each gain and impedance? Will the board be used in different countries with
different requirements? Will several versions of the
board be built? If so, will one version of the board be
most of the production volume? Does the application
need only real termination impedance? Does the hybrid
balance need to be adjusted in the field?
These perform the basic filtering, A/D (transmit), D/A
(receive), and µ-law/A-law companding. They all have
an op amp in front of the A/D converter for transmit gain
setting and hybrid balance (cancellation at the summing
node). Depending on the type, some have differential
analog input stages, differential analog output stages,
and µ-law/A-law selectability. This generation of codec
has the lowest cost. It is most suitable for applications
with fixed gains, termination impedance, and hybrid balance.
Lucent Technologies Inc.
Third-Generation Codecs
37
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
ac Design (continued)
ac equivalent circuits using a T7504 codec (VCC only) are shown in Figures 37 and 38. Use the following two equations for Figure 37 below:
RSTP = 1 kΩ x {[RGP (kΩ) || RRCV (kΩ)]/24 (kΩ)}
CSTP = 270 pF/{[RGP (kΩ) || RRCV (kΩ)]/24 (kΩ)}
RX
VGSX
–0.400 V/mA
RT6
VFXIN
VITR
ZT/R
VS
ZT
RP TIP
IT/R
+
VT/R
–
RP
–
–
AV = 1
+
AV = 4
+
+
+2.4 V
RRCV
RCVP
CURRENT
SENSE
VFXIP
RT3
RHB1
RCVN
–
VFR
RGP
RSTP
+
AV = –1
–
RING
CSTP
L8560 SLIC
1/2 T7504 CODEC
12-2554.p (F)
Figure 37. ac Equivalent Circuit Not Including Spare Op Amp
Use the following two equations for Figure 38 below:
RSTN = 1 kΩ x {[RGN (kΩ) || RRCV (kΩ)]/24 (kΩ)}
CSTN = 270 pF/{[RGN (kΩ) || RRCV (kΩ)]/24 (kΩ)}
ZT5
RX
VGSX
XMT
RT4
RT5X
–
VITR
RT6
SN
AGND
VFXIN
VFXIP
ZT/R
VS
ZT
RP
TIP
IT/R
+
VT/R
–
RP
–
–
AV = 1
+
AV = 4
+
CURRENT
SENSE
RT3
RCVN
RHB1
+
+2.4 V
RRCV
RCVP
RGN
+
–
+
VFRO
RSTN
CSTN
AV = –1
RING
–
L8560 SLIC
1/4 T7504 CODEC
12-3013.j (F)
Figure 38. ac Equivalent Circuit Including Spare Op Amp
38
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Hybrid balance:
Design Examples
RX
hbal = 20log  --------------- – g tx × g rcv
R HB1
In the preceding examples, use of a first-generation
codec is shown. The equations for second- and thirdgeneration codecs are simply subsets of these. There
are two examples below. The first shows the simplest
circuit, which uses a minimum number of discrete components to synthesize a real termination impedance.
The second example shows the use of the uncommitted op amp to synthesize a complex termination. The
design has been automated in a DOS-based program,
available on request.
V GSX
hbal = 20log  ---------------
V FR
To optimize the hybrid balance, the sum of the currents
at the VFX input of the codec op amp should be set to
0. The expression for ZHB becomes:
R H B 1 ( kΩ ) =
RX
------------------
g tx × g rcv
Example 1, Real Termination
Example 2, Complex Termination
The following design equations refer to the circuit in
Figure 37. Use these to synthesize real termination
impedance.
For complex termination, the spare op amp may be
used (see Figure 38).
Termination impedance:
V T/R
zT = -----------– I T/R
3200
z T = 2R P + ----------------------------------RT3
RT3
1 + --------- + -----------RGP RRCV
Receive gain:
8
-----------------------------------------------------------------R CV
R R C V 
zT 
1 + R
+
1+
 ----------- ------------  ---------
R T3
Transmit gain:
g tx =
V GSX
----------V T/R
gtx =
–-------R X 400
- × --------R T6
8
g rcv = ----------------------------------------------------------------------------R RCV R RCV 
zT
 1 + ------------- + -------------- 1 + ----------

R T3
RGN  
Z T/R
gtx =
R X 400 Z T5
R T5X
R T5X
--------- × ---------- × ---------  1 + -------------- + ----------------------------------------------------
R T6 Z T/R R T4 
Z T5 R T3 + R G N || R RCV
V T/R
g rcv = -----------V FR
g rcv =
Z T5
3200
z T = 2R P + ----------------------------------- ( --------- )
R
T4
RT3
RT3
1 + --------- + -----------RGN RRCV
= 2RP + k(ZT5)
RGP
Z T/R
The hybrid balance equation is the same as in Example 1.
Example 3, Complex Termination Without Spare Op
Amp
The gain shaping necessary for a complex termination
impedance may be done without using the spare op
amp by shaping across the Ax amplifier at nodes TG
and VTX. This is a recommended approach.
Z T/R
Lucent Technologies Inc.
39
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
RX/RT6: With other components set, the transmit gain
(for complex and resistive terminations) RX and RT6 are
varied to give specified transmit gain.
Design Examples (continued)
R2
RT3/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.
C
CN/RN1/RN2: For complex terminations, these components provide high-frequency compensation to the
return loss characteristic.
Complex Termination Impedance Design Example
Using L8560 Without Spare Op Amp
Complex termination is specified in the form:
R1
5-6396(F)
To work with this application, convert termination to the
form:
For resistive terminations, these components are not
used and RCVN is connected to ground via a resistor.
RHB: Sets hybrid balance for all terminations.
R1´
Set ZTG—gain shaping:
R 2´
C´
5-6398(F)
where:
R1´ = R1 + R2
R1
R2´ = ------- (R1 + R2)
R2
2
R2
C´ =  --------------------- C
R1 + R2
ac Interface Using First-Generation Codec
ZTG = RTGP || RTGS + CGS which is a scaled version of
ZT/R (the specified termination resistance) in the
R1´ || R2´ + C´ form.
RTGP must be 4.32 kΩ to set SLIC transconductance to
400 V/A
RTGP = 4.32 kΩ
At dc, CTGS and C´ are open.
RTGP = M x R1´
where M is the scale factor.
4320
M = -------------R1′
RTGP/RTGS/CGS (ZTG): These components give gain
shaping to get good gain flatness. These components
are a scaled version of the specified complex termination impedance.
It can be shown:
Note for pure (600 Ω) resistive terminations, components RTGS and CGS are not used. Resistor RTGP is
used and is still 4.32 kΩ.
CTGS =
40
RTGS = M x R2´
and
C′
-----M
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Examples (continued)
RTGS
CG
Rx
–IT/R
207.36
RTGP = 4.32 kΩ
0.1 µF
RT6
–
+
19.2
VTX
TXI
VITR
CODEC
OP AMP
CN
RT3
RN1
RHB
RCVN
CODEC
OUTPUT
DRIVE
AMP
RRCV
RCVP
RN2
RGP
5-6400.b (F)
Figure 39. Interface Circuit Using First-Generation Codec (Blocking Capacitors Not Shown)
TX (specified[dB]) is the specified transmit gain. 600 Ω is the
impedance at the PCM and R EQ is the impedance at
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:
Tip and ring. 20 log
600
----------- represents the power
R EQ
loss/gain due to the impedance transformation.
Note in the case of a 600 Ω pure resistive termination
at T/R 20 log
600
----------- = 20 log
R EQ
600
---------- = 0.
600
Thus, there is no power loss/gain due to impedance
transformation and TX (dB) = TX (specified[dB]).
R2
Finally, convert TX (dB) to a ratio, gTX:
R1
TX (dB) = 20 log gTX
C
5-6396(F)
First, calculate the equivalent resistance of this network at the midband frequency of 1000 Hz.
REQ =
2 πf ) 2 C 1 2 R 1 R 2 2 + R 1 + R 2- 2  -------------------------------------------------2 πf R 2 2 C 1 - 2
 (---------------------------------------------------------------------------+
2


2
2
1 + ( 2 πf ) R 2 C 1
1 + ( 2 πf ) 2 R 2 2 C 1 2
The ratio of RX/RT6 is used to set the transmit gain:
RX
R T6
207.36
19.2
---------- = gTX • ------------------
1
• ----
M
with a quad Lucent codec such as T7504:
RX < 200 kΩ
Using REQ, calculate the desired transmit gain, taking
into account the impedance transformation:
TX (dB) = TX (specified[dB]) + 20 log
Lucent Technologies Inc.
600
----------R EQ
41
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Next, solve for the high-frequency return loss compensation circuit, CN, RN1, and RN2:
Design Examples (continued)
2R P
CNRN2 = ------------- CG RTGP
3200
Receive Gain
Ratios of RRCV, RT3, 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 via a
resistor.
Determine the receive gain, gRCV, taking into account
the impedance transformation in a manner similar to
transmit gain.
R EQ
RX (dB) = RX (specified[dB]) + 20 log ----------600
RX (dB) = 20 log gRCV
Then:
3200 R TGS
RN1 = RN2 -------------  -------------- – 1
2R P  R TGP
There is an input offset voltage associated with nodes
RCVN and RCVP. To minimize the effect of 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 40 on page 43 (with dc blocking capacitors). To meet this requirement, RN2 = RGP ||
RT3.
Hybrid Balance
Set the hybrid cancellation via RHB.
RX
RHB = ------------------------------g RCV × g TX
4
gRCV = -----------------------------------------------R
RCV R RCV
1 + --------------- + --------------R T3
R GP
and low-frequency termination
3200
ZTER(low) = -------------------------------------------- + 2RP
R
T3
R T3
1 + ------------ + --------------R GP R RCV
ZTER(low) is the specified termination impedance assuming low frequency (C or C´ is open).
RP is the series protection resistor.
These two equations are best solved using a computer
spreadsheet.
42
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Applications (continued)
Design Examples (continued)
Blocking Capacitors
RTGS
CGS
Rx
–IT/R
207.36
RTGP = 4.32 kΩ
0.1 µF
RT6
CB1
19.2
VTX
TXI
VITR
–
+
CODEC
OP AMP
CN
RN1
RT3
RCVN
RHB
CB2
RCVP
RN2
RRCV
RGP
CODEC
OUTPUT
DRIVE
AMP
2.5 V
5-6401b(F)
Figure 40. ac Interface Using First-Generation Codec (Including Blocking Capacitors) for Complex
Termination Impedance
If a 5 V only codec such as the Lucent T7504 is used, dc blocking capacitors must be added as shown in Figure
40. 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.
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 L8560 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.
* PSPICE is a registered trademark of MicroSim Corporation.
Lucent Technologies Inc.
43
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Outline Diagrams
32-Pin PLCC
Dimensions are in millimeters.
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics to assist your design efforts, please contact your Lucent Technologies Sales Representative.
12.446 ± 0.127
11.430 ± 0.076
4
PIN #1 IDENTIFIER
ZONE
1
30
5
29
13.970
± 0.076
14.986
± 0.127
13
21
14
20
3.175/3.556
1.27 TYP
0.38 MIN
TYP
SEATING PLANE
0.10
0.330/0.533
5-3813r2 (F)
44
Lucent Technologies Inc.
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Outline Diagrams (continued)
44-Pin PLCC
Dimensions are in millimeters.
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics to assist your design efforts, please contact your Lucent Technologies Sales Representative.
17.65 MAX
16.66 MAX
PIN #1 IDENTIFIER
ZONE
6
1
40
39
7
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
5-2506r.8(F)
Lucent Technologies Inc.
45
Data Sheet
April 2000
L8560 Low-Power SLIC with Ringing
Ordering Information
Device Code
LUCL8560AAU-D
LUCL8560AAU-DT
LUCL8560AP-D
LUCL8560AP-DT
LUCL8560CAU-D
LUCL8560CAU-DT
LUCL8560DAU-D
LUCL8560DAU-DT
LUCL8560EP-D
LUCL8560EP-DT
LUCL8560FAU-D
LUCL8560FAU-DT
LUCL8560GP-D
LUCL8560GP-DT
Description
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Low-power SLIC (Dry-bagged)
Low-power SLIC (Tape and Reel, Dry-bagged)
Package
32-Pin PLCC
32-Pin PLCC
44-Pin PLCC
44-Pin PLCC
32-Pin PLCC
32-Pin PLCC
32-Pin PLCC
32-Pin PLCC
44-Pin PLCC
44-Pin PLCC
32-Pin PLCC
32-Pin PLCC
44-Pin PLCC
44-Pin PLCC
Comcode
107957375
107957383
107891111
107891129
107953390
107953408
108130576
108130584
108133000
108133018
108190885
108190893
108190935
108190943
For additional information, contact your Microelectronics Group Account Manager or the following:
INTERNET:
http://www.lucent.com/micro
E-MAIL:
[email protected]
N. AMERICA: Microelectronics Group, Lucent Technologies Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18103
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA PACIFIC: Microelectronics Group, Lucent Technologies Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256
Tel. (65) 778 8833, FAX (65) 777 7495
CHINA:
Microelectronics Group, Lucent Technologies (China) Co., Ltd., A-F2, 23/F, Zao Fong Universe Building, 1800 Zhong Shan Xi Road, Shanghai
200233 P. R. China Tel. (86) 21 6440 0468, ext. 316, FAX (86) 21 6440 0652
JAPAN:
Microelectronics Group, Lucent Technologies Japan Ltd., 7-18, Higashi-Gotanda 2-chome, Shinagawa-ku, Tokyo 141, Japan
Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700
EUROPE:
Data Requests: MICROELECTRONICS GROUP DATALINE: Tel. (44) 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 4354 2800 (Helsinki),
ITALY: (39) 02 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. N o liability is assumed as a result of their use or application. No
rights under any patent accompany the sale of any such product(s) or information.
Copyright © 2000 Lucent Technologies Inc.
All Rights Reserved
April 2000
DS00-172ALC (Replaces DS99-124ALC)