Agere LUCL9218AAR-DT Low-cost line interface Datasheet

Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Features
■
Basic forward battery only SLIC functionality at a
low cost
■
Pin compatible with Agere Systems Inc. L9219 and
L9217 SLIC
■
Low active power (typical 138 mW during on-hook
transmission)
■
Low-power scan mode for low-power, on-hook
power dissipation (59 mW typical)
■
Minimal external components
■
Distortion-free, on-hook transmission
■
Convenient operating states:
— Forward battery low current limit
— Forward battery high current limit
— Low-power scan
— Disconnect (high impedance)
■
Adjustable supervision functions:
— Off-hook detector with hysteresis
— Ring trip detector
■
Logic controlled high and low current limit
■
Two gain options to optimize the codec interface
■
Thermal protection with thermal shutdown indication
Description
This general-purpose electronic subscriber loop
interface circuit (SLIC) is optimized for low cost, while
still providing a satisfactory set of features.
The L9218 is pin-for-pin compatible with the Agere
L9219 and L9217 SLICs.
The L9218 requires a 5 V power supply and single
battery to operate. This is a forward battery only
device. Additionally, a low-power scan mode,
wherein all circuitry except the off-hook supervision is
shut down to conserve power, is available.
Via the logic inputs, a low or high current limit may be
selected. The low value is set via a single external
resistor, and the high value is 1.4 times the low value.
Device overhead is fixed and is adequate for
3.14 dBm into 900 Ω of on-hook transmission.
Both the loop supervision and ring trip supervision
functions are offered with user-controlled thresholds
via external resistors.
The L9218 is offered with a receive gain that is optimized for interface to a first-generation type codec
(L9218A). It is also offered with a gain option that is
optimized for interface to a third- or fourth-generation
type codec (L9218G). In both cases, minimizing
external components required at this interface. In the
receive direction, the device may be dc-coupled to a
third-generation codec. No dc blocking capacitors
are needed.
Data control is via a parallel data control scheme.
The device is available in a 28-pin PLCC package. It
is built by using a 90 V complementary bipolar
(CBIC) process.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Table of Contents
Contents
Page
Features ......................................................................1
Description...................................................................1
Pin Information ............................................................4
Functional Description .................................................6
Absolute Maximum Ratings (at TA = 25 °C) ................7
Recommended Operating Conditions .........................7
Electrical Characteristics .............................................8
Ring Trip Requirements ..........................................12
Test Configurations ...................................................13
Applications ...............................................................15
dc Applications....................................................... 19
Battery Feed.........................................................19
Current Limit.........................................................19
Overhead Voltage ............................................... 19
Loop Range..........................................................20
Off-Hook Detection...............................................20
Ring Trip Detection...............................................21
Longitudinal Balance.............................................. 21
ac Design ............................................................... 22
Codec Types ........................................................22
ac Interface Network ............................................22
Receive Interface .................................................22
Example 1: Real Termination (FirstGeneration Codec) .............................................. 23
Example 2: Complex Termination (FirstGeneration Codec) ...............................................25
Power Derating ...................................................... 27
Pin-for-Pin Compatibility with L9217/L9219 ........... 27
PCB Layout Information ............................................27
Outline Diagram.........................................................28
28-Pin PLCC .......................................................... 28
Ordering Information..................................................29
Figures
Figures
Page
Figure 15. Ring Trip Equivalent Circuit and
Equivalent Application ........................... 21
Figure 16. ac Equivalent Circuit .............................. 23
Figure 17. Interface Circuit Using FirstGeneration Codec (±5 V Battery) .......... 26
Figure 18. Interface Circuit Using FirstGeneration Codec (5 V Only Codec) ..... 26
Tables
Page
Table 1.
Table 2.
Table 3.
Table 4.
Table 5.
Table 6.
Table 7.
Table 9.
Pin Descriptions ...................................... 4
Input State Coding .................................. 6
Supervision Coding ................................. 6
Power Supply .......................................... 8
2-Wire Port .............................................. 9
Analog Pin Characteristics .................... 10
ac Feed Characteristics ...................... 11
Parts List for Loop Start Application
Circuit Using T7504-Type Codec .......... 16
200 Ω + 680 Ω || 0.1 µF FirstGeneration Codec Design Parameters . 17
Parts List for Loop Start Application
Circuit Using T8536-Type Codec .......... 18
Table 10.
Table 11.
Page
Figure 1.
Figure 2.
Figure 3.
Figure 4.
Figure 5.
Figure 6.
Figure 7.
Figure 8.
Figure 9.
Figure 10.
Figure 11.
Functional Diagram...................................3
28-Pin PLCC.............................................4
Ring Trip Circuits ....................................12
L9218 Basic Test Circuit.........................13
Metallic PSRR.........................................13
Longitudinal PSRR .................................13
Longitudinal Balance ..............................14
RFI Rejection ..........................................14
Longitudinal Impedance..........................14
ac Gains..................................................14
Basic Loop Start Application
Circuit Using T7504-Type Codec............15
Figure 12. Basic Loop Start Application
Circuit Using T8536-Type Codec............17
Figure 13. Loop Current vs. Loop Voltage ...............19
Figure 14. Off-Hook Detection Circuit ......................20
2
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
CF2
CF1
AGND
VCC
IPROG
BGND
Description (continued)
POWER CONDITIONING AND REFERENCE
FORWARD AND REVERSE BATTERY
DCOUT
3
RECTIFIER
+
AX
–
VTX
β = 41 V/A
TG
TXI
AAC
–
A=1
PT
β = 9.66
+
TIP/RING
CURRENT
SENSE
A VERSION GAIN = 3.93
G VERSION GAIN = 1
+
A = –1
–
PR
VITR
–
RCVN
+
RCVP
B0
BATTERY FEED
STATE CONTROL
B1
B2/NC
LCTH
LOOP CLOSURE DETECTOR
+
–
THERMAL
SHUTDOWN
+
RTSP
RTSN
TSD
RING TRIP DETECTOR
NSTAT
–
12-3557 (F).d
Figure 1. Functional Diagram
Agere Systems Inc.
3
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
VCC
NC
NC
IPROG
NC
TSD
TG
Pin Information
4
3
2
1
28
27
26
RCVP
5
25
VTX
RCVN
6
24
TXI
LCTH
7
23
VITR
DCOUT
8
22
NSTAT
VBAT
9
21
NC
PR
10
20
RTSP
CF2
11
19
RTSN
12
13
14
15
16
17
18
CF1
B2/NC
B1
B0
AGND
BGND
PT
28-PIN PLCC
12-3552 (F)
Figure 2. 28-Pin PLCC
Table 1. Pin Descriptions
PLCC
1
2
3
4
5
6
4
Symbol Type
Description
IPROG
I
Current-Limit Program Input. A resistor to DCOUT sets the dc current limit of
the device.
NC
— No Connect.
NC
— No Connect.
CC
V
— 5 V Power Supply.
RCVP
I
Receive ac Signal Input (Noninverting). This high-impedance input controls
the ac differential voltage on tip and ring.
RCVN
I
Receive ac Signal Input (Inverting). This high-impedance input controls the
ac differential voltage on tip and ring.
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Pin Information (continued)
Table 1. Pin Descriptions (continued)
PLCC
7
Symbol Type
Description
LCTH
I
Loop Closure Threshold Input. Connect a resistor to VTX to set off-hook
threshold.
8
DCOUT
O
dc Output Voltage. This output is a voltage that is directly proportional to the
absolute value of the differential tip/ring current.
9
VBAT
—
Battery Supply. Negative high-voltage power supply.
10
PR
I/O
Protected Ring. The output of the ring driver amplifier and input to loop sensing circuitry. Connect to the loop through overvoltage protection.
11
CF2
—
Filter Capacitor 2. Connect a 0.1 µF capacitor from this pin to AGND.
12
CF1
—
Filter Capacitor 1. Connect a 0.47 µF capacitor from this pin to pin CF2.
13
B2/NC
—
Dummy Pin. Used for exact pin-for-pin compatibility with L9219. There is no
physical connection to this pin, however, it may be connected to the B2 control
latch to get an exact PWB footprint match with L9219.
14
B1
I
State Control Input. B0 and B1 determine the state of the SLIC. See Table 2.
Pin B1 has an internal pull-down.
15
B0
I
State Control Input. B0 and B1 determine the state of the SLIC. See Table 2.
Pin B0 has an internal pull-down.
16
AGND
—
Analog Signal Ground.
17
BGND
—
Battery Ground. Ground return for the battery supply.
18
PT
I/O
Protected Tip. The output of the tip driver amplifier and input to loop-sensing
circuitry. Connect to loop through overvoltage protection.
19
RTSN
I
Ring Trip Sense Negative. Connect this pin to the ringing generator signal
through a high-value resistor.
20
RTSP
I
Ring Trip Sense Positive. Connect this pin to the ring relay and the ringer
series resistor through a high-value resistor.
21
NC
—
No Connect.
22
NSTAT
O
Loop Detector Output/Ring Trip Detector Output. When low, this logic output indicates that an off-hook condition exists or that ringing is tripped.
23
VITR
O
24
TXI
—
Transmit ac Output Voltage. This output is a voltage that is directly proportional to the differential tip/ring current.
ac/dc Separation. Connect a 0.1 µF capacitor from this point to VTX.
25
VTX
O
Transmit ac/dc Output Voltage. This output is a voltage that is directly proportional to the differential tip/ring current.
26
TG
—
27
TSD
O
Transmit Gain. Connect an 8.06 kΩ from TG to VTX to set the transmit gain of
the SLIC.
Thermal Shutdown. When high, this logic output indicates the device is in
thermal shutdown.
28
NC
—
Agere Systems Inc.
No Connect.
5
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Functional Description
Table 2. Input State Coding
B0
1
1
0
0
B1
State/Definition
1 Powerup, Forward Battery. Normal talk and battery feed state. Pin PT is positive with respect to PR.
On-hook transmission is enabled. Low current limit is selected.
0 Powerup, Forward Battery. Normal talk and battery feed state. Pin PT is positive with respect to PR.
On-hook transmission is enabled. High current limit is selected.
0 Disconnect. The tip and ring amplifiers are turned off, and the SLIC goes to a high-impedance state
(>100 kΩ). Supervision outputs read on hook. Device will power up in this state.
1 Low-Power Scan. Except for off-hook detection, all circuits are shut down to conserve power. Pin PT
is positive with respect to pin PR. On-hook transmission is disabled.
Table 3. Supervision Coding
NSTAT
0 = off-hook or ring trip.
1 = on-hook and no ring trip.
6
TSD
0 = Normal device operation.
1 = Device is in thermal shutdown.
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Absolute Maximum Ratings (at TA = 25 °C)
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress ratings only. Functional operation of the device is not implied at these or any other conditions in excess
of those given in the operational sections of the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect device reliability.
Parameter
5 V Power Supply
Battery (talking) Supply
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
VBAT
—
—
TJ
Tstg
RH
—
PT
V , VPR
VPT, VPR
RTSP
I
, IRTSN
Min
—
—
–0.5
–7.0
150
–40
5
—
BAT
V
–5
VBAT – 15
—
Typ
—
—
—
—
—
—
—
±3
—
—
±240
Max
7.0
–75
7.0
7.0
—
125
95
—
3
15
—
Unit
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 the following:
1. An inductor connected to tip and ring can force an overvoltage on VBAT through the protection devices if the VBAT connection chatters.
2. Inductance in the VBAT lead could resonate with the VBAT filter capacitor to cause a destructive overvoltage.
Recommended Operating Conditions
Parameter
Ambient Temperature
VCC Supply Voltage
VBAT Supply Voltage
Agere Systems Inc.
Min
–40
4.75
–24
Typ
—
5.0
–48
Max
85
5.25
–70
Unit
°C
V
V
7
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
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 4 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, VBAT = –48 V, unless otherwise noted.
Table 4. Power Supply
Parameter
Power Supply—Powerup, No Loop Current:
ICC
IBAT (VBAT = –48 V)
Power Dissipation (VBAT = –48 V)
Power Supply—Scan, No Loop Current:
ICC
IBAT (VBAT = –48 V)
Power Dissipation (VBAT = –48 V)
Power Supply—Disconnect, No Loop Current:
ICC
IBAT (VBAT = –48 V)
Power Dissipation (VBAT = –48 V)
Power Supply Rejection 500 Hz to 3 kHz
(See Figure 5 and Figure 6)1:
VCC
VBAT
Min
Typ
Max
Unit
—
—
—
4.6
–2.4
138
5.6
–2.7
158
mA
mA
mW
—
—
—
2.8
–0.8
52
3.8
–1.0
67
mA
mA
mW
—
—
—
1.6
–0.12
14
—
—
—
mA
mA
mW
30
40
—
—
—
—
dB
dB
Thermal Protection Shutdown (Tjc)3
150
165
—
°C
—
—
—
—
30
43
27
36
—
—
—
—
°C/W
°C/W
°C/W
°C/W
Thermal Resistance, Junction to Ambient (θJA)2, 3:
Natural Convection 2S2P Board
Natural Convection 2S0P Board
Wind Tunnel 100 Linear Feet per Minute (LFPM) 2S2P Board
Wind Tunnel 100 Linear Feet per Minute (LFPM) 2S0P Board
1. This parameter is not tested in production. It is guaranteed by design and device characterization.
2. Careful thermal design as a function of maximum battery, loop length, maximum ambient temperature package thermal resistance, airflow,
PCB board layers, and other related parameters must ensure that thermal shutdown temperature is not exceeded under normal use conditions.
3. Airflow, PCB board layers, and other factors can greatly affect this parameter.
8
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Electrical Characteristics (continued)
Table 5. 2-Wire Port
Parameter
Min
Typ
Max
Unit
Tip or Ring Drive Current = dc + Longitudinal + Signal
Currents
80
—
—
mA
Signal Current
15
—
—
mArms
8.5
15
—
mArms
15
—
—
±5
45
—
mA
%
—
|VBAT + 7.5|
|VBAT + 8.0|
VBAT/2
|VBAT + 6.5|
|VBAT + 6.5|
—
|VBAT + 5.9|
|VBAT + 5.9|
V
V
V
—
10
150
µA
—
80
100
Ω
1800
—
—
Ω
Longitudinal to Metallic Balance—IEEE Std. 455
(See Figure 7)5:
200 Hz to 3400 Hz
58
61
—
dB
Metallic to Longitudinal Balance (open loop):
200 Hz to 4 kHz
40
—
—
dB
RFI Rejection (See Figure 8)3, 0.5 Vrms, 50 Ω Source,
30% AM Mod 1 kHz:
500 kHz to 100 MHz
—
—
—
–55
—
–45
—
dBV
Longitudinal Current Capability per Wire
1
dc Loop Current Limit2:
Allowed Range Including Tolerance3
Accuracy (RLOOP = 100 Ω, VBAT = –48 V)
Powerup Open Loop Voltage Levels:
Common-mode Voltage
Differential Voltage VBAT = –48 V4 (Gain = 2)
Differential Voltage VBAT = –48 V4 (Gain = 7.86)
Disconnect State:
Leakage
dc Feed Resistance (for ILOOP below regulation level) (does
not include protection resistor)
Loop Resistance Range (–3.17 dBm overload into
900 Ω; not including protection):
ILOOP = 20 mA at VBAT = –48 V
®
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 13).
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. Longitudinal balance of circuit card will depend on loop series protection resistor matching and magnitude. More information is available in
the Applications section of this document.
Agere Systems Inc.
9
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Electrical Characteristics (continued)
Table 6. Analog Pin Characteristics
Parameter
Differential PT/PR Current Sense (DCOUT):
Gain (PT/PR to DCOUT)
Offset Voltage at ILOOP = 0
Loop Closure Detector Threshold (RLCTH = 22.1 kΩ)1:
On- to Off-hook Threshold (scan mode)
Off- to On-hook Threshold (active mode)
Ring Trip Comparator:
Input Offset Voltage2
Internal Voltage Source
Current at Input RTSP3
RCVN, RCVP:
Input Bias Current
Input Resistance
Min
Typ
Max
Unit
121
–100
125
—
129
100
V/A
mV
8.8
6.0
—
—
13.6
10.2
mA
mA
—
–9.1
IN – 0.5
±10
–8.6
IN
—
–8.1
IN + 0.6
mV
V
µA
—
—
–0.2
1
–1
—
µA
MΩ
1. Loop closure threshold is programmed by resistor RLCTH from pin LCTH to pin DCOUT. The programming equation or relationship between
off-hook threshold and resistor value is different for active mode versus scan mode (see Applications section for more details).
2. This parameter is not tested in production. It is guaranteed by design and device characterization.
3. IN is the sourcing current at RTSN. Guaranteed if IN is within 5 µA to 30 µA.
10
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Electrical Characteristics (continued)
Table 7. ac Feed Characteristics
Parameter
Min
Typ
Max
Unit
150
—
1300
Ω
Longitudinal Impedance at PT/PR2
—
0
—
Ω
Total Harmonic Distortion—200 Hz to 4 kHz2:
Off-hook
On-hook
—
—
—
—
0.3
1.0
%
%
–391
–403
–415
V/A
7.62
–7.62
7.86
–7.86
8.09
–8.09
—
—
1.94
–1.94
2.00
–2.00
2.06
–2.06
—
—
Gain vs. Frequency (transmit and receive)
(600 Ω termination; reference 1 kHz2):
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 dBV2):
–55 dB to +3 dB
–0.05
0
0.05
dB
2-Wire Idle-channel Noise (600 Ω termination):
Psophometric2
C-message
3 kHz Flat2
—
—
—
–87
2
10
–77
12
20
dBmp
dBrnC
dBrn
Transmit Idle-channel Noise:
Psophometric2
C-message
3 kHz Flat2
—
—
—
–82
7
15
–77
12
20
dBmp
dBrnC
dBrn
ac Termination Impedance
1
Transmit Gain, f = 1 kHz (PT/PR to VITR) (current limit)
L9218A, Open Loop:
Receive + Gain, f = 1 kHz (RCVP to PT/PR)3
Receive – Gain, f = 1 kHz (RCVN to PT/PR)3
L9218G, Open Loop:
Receive + Gain, f = 1 kHz (RCVP to PT/PR)4
Receive – Gain, f = 1 kHz (RCVN to PT/PR)4
1. With a first-generation codec, this parameter is set by external components. Any complex impedance R1 + R2 || C between 150 Ω and
1300 Ω can be synthesized. With a third-generation codec, this parameter is set by a codec or by a combination of a codec and an external
network.
2. This parameter is not tested in production. It is guaranteed by design and device characterization.
3. Use this gain option with a first-generation or third-generation codec.
4. Use this gain option with an Agere third-generation codec.
Agere Systems Inc.
11
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Electrical Characteristics (continued)
Table 8. Logic Inputs and Outputs
All outputs are open collectors with internal, 30 kΩ pull-down resistor. Input pins have internal pull-down or some
way to power up in disconnect state.
Parameter
Symbol
Min
Typ
Max
Unit
Input Voltages:
Low Level (permissible range)
High Level (permissible range)
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
0
+10
+4
+24
+10
+50
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 = 200 µA)
High Level (VCC = 4.75 V, IOH = –20 µA)
Ring Trip Requirements
■
■
■
Ringing signal:
— Voltage, minimum 35 Vrms, maximum 100 Vrms.
— Frequency, 17 Hz to 33 Hz.
— Crest factor, 1.2 to 1.6.
Ring trip:
— ≤100 ms (typical).
8 µF
TIP
RING
10 kΩ
2 µF
100 Ω
RING
TIP
Pretrip:
— The circuits in Figure 3 will not cause ring trip.
12-2572 (F).f
Figure 3. Ring Trip Circuits
12
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Test Configurations
VBAT
VCC
0.1 µF
VBAT
0.1 µF
BGND VCC
AGND
50 Ω
TIP
VITR
PT
XMT
75 kΩ
RLOOP
100 Ω/600 Ω
L9218
SLIC
RCVN
RCV
50 Ω
RING
46 kΩ
19.4 kΩ
RCVP
PR
DCOUT
8.06 kΩ
TG
43.2 kΩ
IPROG
VTX
0.1 µF
TXI
22.1 kΩ
LCTH
B0
B1
2 MΩ
RTSP
402 Ω
B2
NSTAT
TSD
274 kΩ
RTSN
CF1
2 MΩ
0.47 µF
CF2
VBAT
0.1 µF
2796 (F)
Figure 4. L9218 Basic Test Circuit
V BAT OR VCC
100 Ω
V BAT OR VCC
DISCONNECT
BYPASS CAPACITOR
4.7 µF
100 Ω
4.7 µF
VS
VS
VBAT OR
VCC
V BAT OR
V CC
67.5 Ω
TIP
+
900 Ω
VT/R
–
TIP
10 µF
BASIC
TEST CIRCUIT
+
VM
–
RING
PSRR = 20 log
DISCONNECT
BYPASS CAPACITOR
VS
VT/R
67.5 Ω
56.3 Ω
BASIC
TEST CIRCUIT
RING
10 µF
PSRR = 20 log
VS
VM
12-2583 (F).b
12-2582 (F).b
Figure 5. Metallic PSRR
Agere Systems Inc.
Figure 6. Longitudinal PSRR
13
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Test Configurations (continued)
ILONG
100 µF
TIP
+
VPT
–
TIP
VS
368 Ω
+
BASIC
TEST CIRCUIT
VM
368 Ω
–
ILONG
RING
100 µF
BASIC
TEST CIRCUIT
–
VPR
+
RING
LONGITUDINAL BALANCE = 20 log
VS
VM
ZLONG =
∆ VPT
∆VPR
OR
∆ ILONG
∆ ILONG
12-2584 (F).c
12-2585 (F).a
Figure 7. Longitudinal Balance
0.01 µF
Figure 9. Longitudinal Impedance
82.5 Ω
TIP
600 Ω
50 Ω
VS
1
6, 7
0.01 µF
L7591
2.15 µF
4
2
+
600 Ω
VT/R
RING
82.5 Ω
HP ® 4935A
TIMS
VS = 0.5 Vrms 30% AM 1 kHz modulation,
f = 500 kHz—1 MHz
device in powerup mode, 600 Ω termination.
Figure 8. RFI Rejection
XMT
TIP
BASIC TEST
CIRCUIT
V BAT
–
BASIC
TEST CIRCUIT
RCV
RING
VS
GXMT =
VXMT
VT/R
GRCV =
VT/R
VRCV
12-2587 (F).e
Figure 10. ac Gains
14
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications
A basic loop start reference circuit, using bused ringing with the L9218 SLIC and the T7504 first-generation codec,
is shown in Figure 11. This circuit is designed for a 200 Ω + 680 Ω || 0.1 µF complex termination impedance and
transhybrid. Transmit gain is set at 0 dBm and receive gain is set at –7 dBm.
VBAT CBAT
0.1 µF
RPROG
1
35.7 kΩ
RLCTH
7
9
VBAT
IPROG
VCC CCC
0.1 µF
4
VCC
TG
LCTH
22.1 kΩ
VTX
8
VITR
RPT
18
50 Ω
L9218
SLIC
RCVP
RTS1
402 Ω
CRTS1
0.015 µF
RTSN
3.32 MΩ
RCVN
20
TSD
RTSP
NSTAT
19 RTSN
CF2
11
CF1
12
B2/NC
B1
B0
AGND BGND
17
16
6
27
22
13
14
15
GSX
CB1
0.47 µF
RHB1
357 kΩ
RRCV
137.0 kΩ
+
DX
PCM
HIGHWAY
+2.4 V
DR
RGP
30.1 kΩ
PR
50 Ω
RTSP
2.94 MΩ
RX
158.0 kΩ
–
5
10
RPR
RING
23
RT1
71.5 kΩ
L7591
LCAS
EMR
CB
0.1 µF
RT2
80.6 kΩ
24
PT
CGS
6.8 nF
RGP1
8.06 kΩ
25
DCOUT
TXI
TIP
RGS
2.37 kΩ
26
CB2
RN1
143.0 kΩ 0.47 µF
CGN
0.1 nF
RN2
18.2 kΩ
VFRO
FSX
FSR
MCLK
CONTROL
AND
CLOCK
SUPERVISION
OUTPUTS
1/4 T7504
CODEC
CONTROL
INPUTS
CF1
0.47 µF
VRING
CF2
0.1 µF
VBAT
2797 (F).a
Figure 11. Basic Loop Start Application Circuit Using T7504-Type Codec
Table 9 shows the design parameters of the application circuit shown in Figure 11. Components that are adjusted
to program these values are also shown.
Table 9. 200 Ω + 680 Ω || 0.1 µF First-Generation Codec Design Parameters
Design Parameter
Loop Closure Threshold
dc Loop Current Limit
2-wire Signal Overload Level
ac Termination Impedance
Hybrid Balance Line Impedance
Transmit Gain
Receive Gain
Agere Systems Inc.
Parameter Value
10 mA
20 mA
3.14 dBm
200 Ω + 680 Ω || 0.1 µF
200 Ω + 680 Ω || 0.1 µF
0 dBm
–7 dBm
Components Adjusted
RLCTH
RPROG
—
RT1, RGP, RRCV, RGP1, RGS, CGS
RHB1
RT2, RX, RN1, RN2, CN
RRCV, RGP, RT1
15
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
Table 10. Parts List for Loop Start Application Circuit Using T7504-Type Codec
Name
Integrated Circuits
SLIC
Protector
Ringing Relay
Codec
Overvoltage Protection
RPT
RPR
Power Supply
CBAT1
CCC
CF1
CF2
dc Profile
RPROG
ac Characteristics
CB1
CB2
RT1
RRCV
RGP
Value
Function
L9218
Agere L7591
Agere L7581/2/3 or EMR
T7504
Subscriber loop interface circuit (SLIC).
Secondary protection.
Switches ringing signals.
First-generation codec.
50 Ω, Fusible
50 Ω, Fusible
Protection resistor.
Protection resistor.
0.1 µF, 20%, 100 V
0.1 µF, 20%, 10 V
0.47 µF, 20%, 100 V
0.1 µF, 20%, 100 V
VBAT filter capacitor.
VCC filter capacitor.
With CF2, improves idle-channel noise.
With CF1, improves idle-channel noise.
35.7 kΩ, 1%, 1/16 W
Sets dc loop current limit.
0.47 µF, 20%, 10 V
0.47 µF, 20%, 10 V
71.5 kΩ, 1%, 1/16 W
137 kΩ, 1%, 1/16 W
30.1 kΩ, 1%, 1/16 W
RT2
RX
RHB1
CGS
80.6 kΩ, 1%, 1/16 W
158 kΩ, 1%, 1/16 W
357 kΩ, 1%, 1/16 W
6.8 nF, 10%, 10 V
RGS
2.37 kΩ, 1%, 1/16 W
RGP1
CN
RN1
RN2
Supervision
RLCTH
RTS1
CRTS1
RTSN
RTSP
8.06 kΩ, 1%, 1/16 W
0.1 nF, 20%, 10 V
143 kΩ, 1%, 1/16 W
18.2 kΩ, 1%, 1/16 W
ac/dc separation capacitor.
ac/dc separation capacitor.
With RGP and RRCV, sets ac termination impedance.
With RGP and RT1, sets receive gain.
With RT1 and RRCV, sets ac termination impedance
and receive gain.
With RX, sets transmit gain in codec.
With RT2, sets transmit gain in codec.
Sets hybrid balance.
With RGS, provides gain shaping for termination
impedance matching.
With CGS, provides gain shaping for termination
impedance matching.
Sets transmit gain of SLIC.
With RN1 and RN2 high frequency compensation.
With CN and RN2 high frequency compensation.
With RN1 and CN high frequency compensation.
22.1 kΩ, 1%, 1/16 W
402 Ω, 5%, 2 W
0.015 µF, 20%, 10 V
3.32 MΩ, 1%, 1/16 W
2.94 MΩ, 1%, 1/16 W
Sets loop closure (off-hook) threshold.
Ringing source series resistor.
With RTSN, RTSP, forms filter pole.
With RTSP, sets threshold.
With CRTS1, RTSN, sets threshold.
16
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
A basic loop start reference circuit, using bused ringing with the L9218 SLIC and the T8536 third-generation codec,
is shown in Figure 12.
VBAT CBAT
0.1 µF
VCC
CCC
0.1 µF
RPROG
1
35.7 kΩ
RLCTH
7
22.1 kΩ
8
9
IPROG
4
VBAT
VCC
TG
LCTH
VTX
DCOUT
TXI
RPT
TIP
18
50 Ω
L9218
SLIC
10
RPR
50 Ω
RTSP
2.94 MΩ
RTS1
510 Ω
VITR
L7591
LCAS
EMR
RING
PT
CRTS1
0.015 µF
RTSN
3.4 MΩ
RCVP
RCVN
NSTAT
PR
B0
20
B1
RTSP
B2/NC
19
26
25
RGP1
8.06 kΩ
24
CB
0.1 µF
23
CB1
0.1 µF
DX1
1/4 T8536
CODEC DX2
RCIN
20 MΩ
5
6
22
15
14
13 (OPTIONAL*)
VFXI
DR1
VFROP
DR2
VFRON
SLIC0a
SLIC3a
FS
BCLK
CONTROL
AND
CLOCK
VDD
CVDD
0.1 µF
SLIC2a
SLIC4a
PCM
HIGHWAY
DGND
RTSN
CF2
11
CF1
12
AGND BGND
17
16
CF1
0.47 µF
VRING
CF2
0.1 µF
VBAT
2798 (F).a
* Optional nonfunctional connection for exact footprint match with L9219.
Figure 12. Basic Loop Start Application Circuit Using T8536-Type Codec
Agere Systems Inc.
17
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
Table 11. Parts List for Loop Start Application Circuit Using T8536-Type Codec
Name
Integrated Circuits
SLIC
Protector
Ringing Relay
Codec
Overvoltage Protection
RPT
RPR
Power Supply
CBAT1
CCC
CF1
CF2
dc Profile
RPROG
ac Characteristics
CB3
RGP1
RCIN
Supervision
RLCTH
RTS1
CRTS1
RTSN
RTSP
18
Value
Function
L9218
Agere L7591
Agere L7581/2/3 or EMR
T8536
Subscriber loop interface circuit (SLIC).
Secondary protection.
Switches ringing signals.
Third-generation codec.
50 Ω, Fusible
50 Ω, Fusible
Protection resistor.
Protection resistor.
0.1 µF, 20%, 100 V
0.1 µF, 20%, 10 V
0.47 µF, 20%, 100 V
0.1 µF, 20%, 100 V
VBAT filter capacitor.
VCC filter capacitor.
With CF2, improves idle-channel noise.
With CF1, improves idle-channel noise.
35.7 kΩ, 1%, 1/16 W
Sets dc loop current limit.
0.1 µF, 20%, 10 V
8.06 kΩ, 1%, 1/16 W
20 MΩ, 5%, 1/16 W
ac/dc separation capacitor.
Sets transmit gain of SLIC.
dc bias.
22.1 kΩ, 1%, 1/16 W
510 Ω, 5%, 2 W
0.015 µF, 20%, 10 V
3.4 MΩ, 1%, 1/16 W
2.94 MΩ, 1%, 1/16 W
Sets loop closure (off-hook) threshold.
Ringing source series resistor.
With RTSN and RTSP, forms second 2 Hz filter pole.
With RTSP, sets threshold.
With RTSN, sets threshold.
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
Starting from the on-hook condition and going through
to a short circuit, the curve passes through the following two regions:
dc Applications
Region 1: On-hook and low-loop currents. The slope
corresponds to the dc resistance of the
SLIC, Rdc1 (70 Ω typical). The open circuit
voltage is the battery voltage minus the overhead voltage of the device, VOH (6.5 V typical). These values are suitable for most
applications but can be adjusted if needed.
Battery Feed
The dc feed characteristic can be described by:
V T/R =
IL =
( VBAT – VOH) × RL
--------------------------------------------R L + 2R P + R dc
V B AT – V O H
---------------------------------
R L + 2R P + R dc
where:
IL = dc loop current.
VT/R = dc loop voltage.
|VBAT| = battery voltage magnitude.
VOH = overhead voltage. This is the difference between
the battery voltage and the open loop tip/ring
voltage.
RL = loop resistance, not including protection resistors.
RP = protection resistor value.
Rdc = SLIC internal dc feed resistance.
The design begins by drawing the desired dc template.
An example is shown in Figure 13.
LOOP CURRENT (mA)
50
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
With the B0/B1 logic inputs set to 11 (low current limit),
current limit with a 100 Ω load is given by the following
equation:
0.637 RPROG (kΩ) + 2 mA= ILIM x (mA)
The relationship between low current limit (B0 = 1,
B1 = 1) and high current limit (B0 = 1, B1 = 0) is
I LIMIT ( Low )
---------------------------------- = 0.7
I LIMIT ( High )
Overhead Voltage
40
ILIM TESTED
1
12.5 kΩ
30
ILIM ONSET
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, expressed as the following equation:
20
–1
R dc1
10
VOH = |VBAT| – (VPT – VPR)
0
0
10
20
30
LOOP VOLTAGE (V)
40
50
12-3050 (F).i
Notes:
VBAT = –48 V.
Without this buffer voltage, amplifier saturation will
occur and the signal will be clipped. The L9218 is automatically set at the factory to allow undistorted on-hook
transmission of a 3.14 dBm signal into a 900 Ω loop
impedance.
ILIM = 22 mA.
Rdc1 = 115 Ω.
Figure 13. Loop Current vs. Loop Voltage
Agere Systems Inc.
19
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
dc Applications (continued)
Loop Range
The equation below can be rearranged to provide the loop range for a required loop current:
RL =
VBAT – VOH
--------------------------- – 2R P – R D C
IL
Off-Hook Detection
The loop closure comparator has built-in longitudinal rejection, eliminating the need for an external 60 Hz filter. The
loop closure detection threshold is set by resistor RLCTH. The supervision output bit NSTAT is high in an on-hook
condition. The off-hook comparator goes low during an off-hook condition:
ITR (mA) = 0.4167 RLCTH (kΩ) – 1.9 mA ACTIVE off-hook to on-hook
ITR (mA) = 0.4167 RLCTH (kΩ) + 2.7 mA SCAN on-hook to off-hook
RP
TIP
ITR
+
RL
0.125 V/mA
DCOUT
–
RLCTH
RING
LCTH
RP
0.05 mA
+
–
NSTAT
12-2553 (F).f
Figure 14. Off-Hook Detection Circuit
20
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
dc Applications (continued)
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 15, along with its use in an application using unbalanced, battery-backed ringing.
PHONE
HOOK SWITCH
RLOOP
RTSP
RC PHONE
VBAT
VRING
RTSP +
2.94 MΩ
RS
402 Ω/510 Ω
CRTS1
0.015 µF
RTSN
3.32 MΩ/3.40 MΩ
NSTAT
IP = IN
IN
+
–
8.6 V
–
RTSN
15 kΩ
2799 (F)
Figure 15. Ring Trip Equivalent Circuit and Equivalent Application
Ring trip detection threshold is given by the following equation:
[ RTSN ( MΩ ) + 0.015 – RTSP ( MΩ ) ] × [ V BAT – 8.6 ] × 1000
ITH (mA) = ------------------------------------------------------------------------------------------------------------------------------------------------------------------------[ RTSN ( MΩ ) + 0.015 ] × R S
Longitudinal Balance
The SLIC is graded to certain longitudinal balance specifications. The numbers are guaranteed by testing (Figure
5 and Figure 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 the following equation:
( 368 + RP ) × ( 368 + ZT – RP )
LB = 20 x log ------------------------------------------------------------------------------------------368 × ( 2 × [ ZT – 2 × RP ] × ∆ + ε )
where:
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.
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.
Agere Systems Inc.
21
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
ac Interface Network
ac Design
The ac interface network between the L9218 and the
codec will vary depending on the codec selected. With
a first-generation codec, the interface between the
L9218 and codec actually sets the ac parameters. With
a third-generation codec, all ac parameters are set digitally, internal to the codec; thus, the interface between
the L9218 and this type of codec is designed to avoid
overload at the codec input in the transmit direction,
and to optimize signal-to-noise ratio (S/N) in the
receive direction.
Codec Types
At this point in the design, the codec needs to be
selected. The interface network between the SLIC and
codec can then be designed. 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.
Below is a brief codec feature summary.
First-Generation Codecs. 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, 5 V only or ±5 V operation, and µ-law/A-law selectability. These are available in single and quad designs. This type of codec
requires continuous time analog filtering via external
resistor/capacitor networks to set the ac design parameters. An example of this type of codec is the Agere
T7504 quad 5 V only codec.
This type of codec tends to be the most economical in
terms of piece part price, but tends to require more
external components than a third-generation codec.
Furthermore, ac parameters are fixed by the external
R/C network, so software control of ac parameters is
difficult.
Third-Generation Codecs. This class of devices
includes all ac parameters set digitally under microprocessor control. Depending on the device, it may or may
not have data control latches. Additional functionality
sometimes offered includes tone plant generation and
reception, TTX generation, test algorithms, and echo
cancellation. Again, this type of codec may be 5 V
only or ±5 V operation, single quad or 16-channel, and
µ-law/A-law or 16-bit linear coding selectable. Examples of this type of codec are the Agere T8535/6 (5 V
only, quad, standard features), T8533/4 (5 V only, quad
with echo-cancellation), and the T8531/36 (5 V only
16-channel with self-test).
22
Receive Interface
Because the design requirements are very different
with a first- or third-generation codec, the L9218 is
offered with two different receive gains. Each receive
gain was chosen to optimize, in terms of external components required, the ac interface between the L9218
and the codec.
With a first-generation codec, the termination impedance is set by providing gain shaping through a feedback network from the SLIC VITR output to the SLIC
RCVN/RCVP inputs. The L9218 provides a transconductance from T/R to VITR in the transmit direction and
a single-ended to differential gain in the receive direction from either RCVN or RCVP to T/R. Assuming a
short from VITR to RCVN or RCVP, the maximum
impedance that is seen looking into the SLIC is the
product of the SLIC transconductance times the SLIC
receive gain, plus the protection resistors. The various
specified termination impedance can range over the
voice band as low as 300 Ω up to over 1000 Ω. Thus, if
the SLIC gains are too low, it will be impossible to synthesize the higher termination impedances. Furthermore, the termination that is achieved will be far less
than what is calculated by assuming a short for SLIC
output to SLIC input. In the receive direction, in order to
control echo, the gain is typically a loss, which requires
a loss network at the SLIC RCVN/RCVP inputs, which
will reduce the amount of gain that is available for termination impedance. For this reason, a high-gain SLIC
is required with a first-generation codec.
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
better the S/N. The problem is, if the codec is feeding a
high-gain SLIC, either an external resistor divider is
needed to knock the gain down to meet the TLP
requirements, or the codec is not operating near maximum signal levels, thus compromising the S/N.
ac Design (continued)
Receive Interface (continued)
It appears the solution is to have a SLIC with a low
gain, especially in the receive direction. This will allow
the codec to operate near its maximum output signal
(to optimize S/N), without an external resistor divider
(to minimize cost).
With a third-generation codec, the line card designer
has different concerns. To design the ac interface, the
designer must first decide upon all termination impedance, hybrid balances, and transmission-level points
(TLP) requirements that the line card must meet. In the
transmit direction, the only concern is that the SLIC
does not provide a signal that is too hot and overloads
the codec input. Thus, for the highest TLP that is being
designed to, given the SLIC gain, the designer, as a
function of voice band frequency, must ensure that the
codec is not overloaded. With a given TLP and a given
SLIC gain (if the signal will cause a codec overload),
the designer must insert some sort of loss, typically a
resistor divider, between the SLIC output and codec
input.
Note also that some third-generation codecs require
the designer to provide an inherent resistive termination via external networks. The codec will then provide
gain shaping, as a function of frequency to meet the
return loss requirements. Further stability issues may
add external components or excessive ground plane
requirements to the design.
To meet the unique requirements of both types of
codecs, the L9218 offers two receive gain choices.
These receive gains are mask-programmable at the
factory and are offered as two different code variations.
For interface with a first-generation codec, the L9218A
is offered with a receive gain of 7.86. For interface with
a third-generation codec, the L9218G is offered with a
receive gain of 2. In either case, the transconductance
in the transmit direction, or the transmit gain is 403 Ω.
In the receive direction, the issue is to optimize S/N.
Again, the designer must consider all the considered
TLPs. The idea is, for all desired TLPs, to run the
codec at or as close as possible to its maximum output
signal, to optimize the S/N. Remember noise floor is
constant, so the hotter the signal from the codec, the
Example 1: Real Termination (First-Generation Codec)
ac equivalent circuits for real termination using a T7504 codec is shown in Figure 15.
RX
VGSX
–0.403 V/mA
RT2
VFXIN
VITR
VFXIP
ZT/R
VS
ZT
–
AV = 1
+
RP TIP
IT/R
+
VT/R
–
RP
RING
–
AV =
3.93
+
CURRENT
SENSE
RT1
RCVN
RHB1
RRCV
RCVP
–
+
2.4 V
VFR
RG
+
AV = –1
–
L9218 SLIC
1/4 T7504 CODEC
12-3581 (F).d
Figure 16. ac Equivalent Circuit
Agere Systems Inc.
23
L9218A/G Low-Cost Line Interface
Data Sheet
November 2001
Applications (continued)
ac Design (continued)
Example 1: Real Termination (First-Generation Codec) (continued)
The following design equations refer to the circuit in Figure 16. Use these to synthesize real termination impedance.
Termination Impedance:
VT ⁄ R
ZT = -------------–I T ⁄ R
3168
Z T = 2R P + ----------------------------------RT3
RT3
1 + --------- + -----------RGP RRCV
Receive Gain:
VT ⁄ R
grcv = -------------V fr
7.86
grcv = ------------------------------------------------------------------------------------RCV
RCV
R
ZT
 1 + --------------- + R
---------------  1 + -------------

R T3
R GP  
Z T/R
Transmit Gain:
V GSX
gtx = --------------VT ⁄ R
RX
403
gtx = ---------- x ----------ZT
R T6
Hybrid Balance:
V GSX
hbal = 20log --------------VT ⁄ R
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 following expressions assume the test network is the same as the termination impedance:
RX
RHB = ------------------------g tx × g rcv
RX
hbal = 20log  ------------ – g tx × g rcv
R HB
24
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
ac Design (continued)
Example 2: Complex Termination (First-Generation Codec)
Below are design equations for complex termination (see Figure 17 and Figure 18).
ZT = RT1 + RT2 || CT
R T1
7.86
= 2R P + -----------201.2


1
1

•  ----------------------------------- – ------------------ RTGP || RTGS
R T3
RN1
RT3
 1 + --------- + ------------ 1 + --------
RGP
R T2 =
RRCV
RN2


7.86  R T G P ⁄ R TGS
1
 RTGP || RTGS
----------- • ----------------------------------- + ----------------201.2 
RN1 
RT3
R T3
1 + --------- + ------------ 1 + -------- 
RGP
RRCV
RN2



2

7.86  1
R N2
1
R TGP
1
1 
= ----------------  ----------- ------------------------------------2- R TGP || R TGS + ----------- •  ------------------------------------- •  ---------------------------------------------- – --------------------- 
C TG R TGP + R TGS
CT
T3
T3
201.2  C N1 ( R N1 + R N2 )
R
R N1
R
 1 + ----------- + --------------- 1 + ----------- 


R GP R RCV
R N2
1
-------
RX
1
Z TG
gtx = ---------- ---------------- ----------R T6 201.2 Z T
7.86
1
grcv = ------------------------------------------------ × -----------------------RCV R RCV
R
ZT
1 + --------------- + --------------- 1 + ------------R T3
R GP
ZT ⁄ R
RX
hbal = 20log  ------------ – g tx × g rcv
R HB
where:
ZT/R = R1 + R2 || C
ZTG = RTGP || (RTGS + CG)
RTGP = 8.06 kΩ
R1
RTGS = ------- RTGP
R2
R 22
CG = ------------------------------------------ x C
R TGP ( R 1 + R 2 )
and
2R P
CNRN2 = ------------- CG RTGP
3168
( 3168 ) R TGS
RN1 = RN2 ------------------  -------------- – 1
2R P  R TGP
The equations above do not include the blocking capacitors.
Agere Systems Inc.
25
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
ac Design (continued)
Example 2: Complex Termination (First-Generation Codec) (continued)
RTGS
CGS
RX
RTGP = 8.06 kΩ
–IT/R
201.2
CB
RT6
AX
AAC
–
+
CODEC
OP AMP
CN
RT3
RN1
RCVN
RCVN
RCVP
RCVP
CODEC
OUTPUT
DRIVE
AMP
RRCV
RGP
RN2
5-6401 (F).j
Figure 17. Interface Circuit Using First-Generation Codec (±5 V Battery)
RTGS
CG
RX
–IT/R
201.2
RTGP = 8.06 kΩ
RT6
AX
AAC
CB
CB1
CN
RN1
CODEC
OP AMP
–2.4 V
RT3
RCVN
RRCV
RCVP
CB2
RGP
RN2
–
+
CODEC
OUTPUT
DRIVE
AMP
5-6400 (F).n
Figure 18. Interface Circuit Using First-Generation Codec (5 V Only Codec)
26
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Applications (continued)
Loop power = (25 mA • 1.05)2 •
(200 Ω + 100 Ω)
Power Derating
Loop power = 0.207 W
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.
SLIC power = 1.523 W – 0.207 W = 1.28
Consider the L9218 SLIC in a 28-pin PLCC package.
The still-air thermal resistance on a 2-layer board is
typically 43 °C/W.
The SLIC will enter the thermal shutdown state at a
minimum of 150 °C. The thermal shutdown design
should ensure that the SLIC temperature does not
reach 150 °C under normal operating conditions.
Assume a maximum ambient operating temperature of
85 °C, a maximum current limit of 25 mA (including tolerance), and a maximum battery of –52 V. Furthermore, assume a (worst-case) minimum dc loop of
200 Ω, and that 50 Ω protection resistors are used at
both tip and ring.
1. TTSD – TAMBIENT(max) = allowed thermal rise.
150 °C – 85 °C = 65 °C
2. Allowed thermal rise = package thermal
impedance • SLIC power dissipation.
65 °C = 43 °C/W • SLIC power dissipation
SLIC power dissipation (PDISS) = 1.51 W
Thus, if the total power dissipated in the SLIC is less
than 1.51 W, it will not enter the thermal shutdown
state. Total SLIC power is calculated as:
Total PDISS = maximum battery • maximum
current limit (including effects of accuracy)
+ SLIC quiescent power
For the L9218, SLIC quiescent power (P Q) is maximum
at 0.158 W. Thus,
Total PDISS = (–52 V • [25 mA • 1.05]) + 0.158 W
Total PDISS = 1.365 W + 0.158 W
Total PDISS = 1.523 W
The power dissipated in the SLIC is the total power dissipation minus the power that is dissipated in the loop.
SLIC power = 1.28 W < 1.51 W
Thus, in this example, the thermal design ensures that
the SLIC will not enter the thermal shutdown state.
Pin-for-Pin Compatibility with L9217/L9219
The L9218 is an exact pin-for-pin replacement for the
L9217/19. The one minor exception is L9217/19 has
three logic control inputs: B0, B1, and B2. The L9218
has only two logic control inputs, B0 and B1. B2 in the
L9217/19 is pin 13. Pin 13 in L9218 is NC, so a connection between the controller and pin 13 will not affect
L9218 operation. This allows an exact footprint match
with L9217/19.
PCB Layout Information
Make the leads to BGND and VBAT as wide as possible
for thermal and electrical reasons. Also, maximize the
amount of PCB copper in the area of (and specifically
on) the leads connected to this device for the lowest
operating temperature.
When powering the device, make certain that no external potential creates a voltage on any pin of the device
that exceeds the device ratings. In this application,
some of the conditions that cause such potentials during powerup are the following:
1. An inductor connected to PT and PR (this can force
an overvoltage on VBAT through the protection
devices if the VBAT connection chatters).
2. Inductance in the VBAT lead (this could resonate with
the VBAT filter capacitor to cause a destructive overvoltage).
This device is normally used on a circuit card that is
subjected to hot plug-in, meaning the card is plugged
into a biased backplane connector. In order to prevent
damage to the IC, all ground connections must be
applied before, and removed after, all other connections.
SLIC PDISS = total power – loop power
Loop power = (ILIM)2 • (RdcLOOP min + 2RP)
Agere Systems Inc.
27
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Outline Diagram
28-Pin PLCC
Dimensions are in millimeters.
12.446 ± 0.127
11.506 ± 0.076
PIN #1 IDENTIFIER
ZONE
4
1
26
25
5
11.506
± 0.076
12.446
± 0.127
11
19
12
18
4.572
MAX
SEATING PLANE
1.27 TYP
0.51 MIN
TYP
0.10
0.330/0.533
5-2608(F)
28
Agere Systems Inc.
Data Sheet
November 2001
L9218A/G Low-Cost Line Interface
Ordering Information
Device
Package
Comcode
LUCL9218AAR-D
28-Pin PLCC
(Dry Bag)
Gain of 12
108558271
LUCL9218AAR-DT
28-Pin PLCC
(Tape and Reel, Dry Bag)
Gain of 12
108558289
LUCL9218GAR-D
28-Pin PLCC
(Dry Bag)
Gain of 2
108558156
LUCL9218GAR-DT
28-Pin PLCC
(Tape and Reel, Dry Bag)
Gain of 2
108558164
Agere Systems Inc.
29
IEEE is a registered trademark of The Institute of Electrical and Electronics Engineers, Inc.
HP is a registered trademark of Hewlett-Packard Company.
For additional information, contact your Agere Systems Account Manager or the following:
INTERNET:
http://www.agere.com
E-MAIL:
[email protected]
N. AMERICA: Agere Systems Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18109-3286
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA:
Agere Systems Hong Kong Ltd., Suites 3201 & 3210-12, 32/F, Tower 2, The Gateway, Harbour City, Kowloon
Tel. (852) 3129-2000, FAX (852) 3129-2020
CHINA: (86) 21-5047-1212 (Shanghai), (86) 10-6522-5566 (Beijing), (86) 755-695-7224 (Shenzhen)
JAPAN: (81) 3-5421-1600 (Tokyo), KOREA: (82) 2-767-1850 (Seoul), SINGAPORE: (65) 778-8833, TAIWAN: (886) 2-2725-5858 (Taipei)
EUROPE:
Tel. (44) 7000 624624, FAX (44) 1344 488 045
Agere Systems Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application.
Copyright © 2001 Agere Systems Inc.
All Rights Reserved
November 2001
DS02-039ALC (Replaces DS01-318ALC)
Similar pages