™
Le79489
Subscriber Line Interface Circuit
Ve580 Series
DISTINCTIVE CHARACTERISTICS
Low standby power (normal and reverse)
On-chip ring and test relay drivers and relay snubber
circuits
Automatic on-chip battery switching
Polarity reversal (full transmission)
On-chip thermal management
Loop and ground-key detector
On-chip thermal shutdown
Comparator for ring-trip detection
–20 V to –60 V battery operation
Ground-start capability
Programmable current limit
On-hook transmission
Ideal for low power sensitive applications
Programmable resistive feed
Programmable loop-detect threshold
Selectable overhead for metering applications
Two-wire impedance set by single external impedance
BLOCK DIAGRAM
TMG
DA
DB
Test Relay
Driver
A(TIP)
Ring Relay
Driver
TESTOUT
RINGOUT
C1
Ring-Trip
Comparator
HPA
Two-Wire
Interface
Ground-Key
Detector
HPB
Loop Detector
B(RING)
Signal
Transmission
VBAT2
Power-Feed
Controller
VBAT1
Input
Decoder
and
Control
RSN
RDC
CAS
OVH
RFA
BGND
VCC
E1
DET
RD
VTX
Switch Control
BSWOUT BSWEN BSWTH
C2
C3
C4
AGND/DGND
Document ID# 080201 Date: Sep 19, 2007
Rev:
G
Version: 3
Distribution:
Public Document
Le79489
Data Sheet
ORDERING INFORMATION
Standard Products
Zarlink standard products are available in several packages and operating ranges. The order number (Valid Combination) is formed by a combination of the elements below.
D
Le79489*
J
C
TEMPERATURE RANGE
C = Commercial (0°C to 70°C)*
PACKAGE TYPE
J = 32-pin Plastic Leaded Chip Carrier (PL 032)
PACKAGING
D = Green package
DEVICE NUMBER/DESCRIPTION
Le79489
Subscriber Line Interface Circuit
PERFORMANCE GRADE OPTION
Blank = No performance grade option
–2 = 60 dB Longitudinal Balance, Polarity Reversal
–3 = 52 dB Longitudinal Balance, No Polarity Reversal
Valid Combinations
Valid Combinations
Le79489*
(Blank)
–2
–3
DJC1, 2
1. For delivery using a tape and reel packing system, add a "T"
suffix to the OPN (Ordering Part Number) when placing an
order.
Valid Combinations list configurations planned to be
supported in volume for this device. Contact Zarlink
sales to confirm availability of specific valid
combinations and to obtain additional data on
Zarlink’s standard military–grade products.
2. The green package meets RoHS Directive 2002/95/EC of
the European Council to minimize the environmental impact
of electrical equipment.
*Zarlink reserves the right to fulfill all orders for this device with parts marked with the "Am" part number prefix, until such time as
all inventory bearing this mark has been depleted. It should be noted that parts marked with either the "Am" or the "Le" part number
prefix are equivalent devices in terms of form, fit, and function. The only difference between the two is in the part number prefix appearing
on the topside mark.
2
Zarlink Semiconductor Inc.
Le79489
Data Sheet
VBAT2
VCC
BGND
B(RING)
A(TIP)
4
3
2
1
32
31 30
DB
RINGOUT
CONNECTION DIAGRAMS
Top View
TESTOUT
5
29
DA
BSWOUT
6
28
RD
TMG
7
27
HPB
VBAT1
8
26
HPA
C4
9
25
NC
BSWEN
10
24
VTX
C1
11
23
RSVD
E1
12
22
RSN
DET
13
21
AGND/DGND
BSWTH
18
19
20
RDC
C2
17
RFA
16
OVH
15
CAS
14
C3
32-Pin PLCC
Notes:
1. Pin 1 is marked for orientation.
2. NC = No Connect
3. RSVD = Reserved. Do not connect to this pin.
3
Zarlink Semiconductor Inc.
Le79489
Data Sheet
PIN DESCRIPTIONS
Pin Names
Type
Description
AGND/DGND
Gnd
A(TIP)
Output
BGND
Gnd
B(RING)
Output
BSWEN
—
Battery Switch Control. Internally connected to automatic battery switch circuitry. BSWEN can be
overridden by external logic. BSWEN Low connects VBAT1 to VBAT2. BSWEN High disconnects
VBAT1 from VBAT2.
BSWOUT
Output
Buffered Output. Internally connected to battery switch circuitry. The output is open-collector with a
built-in pull-up resistor. BSWOUT Low indicates VBAT1 is connected to VBAT2. BSWOUT High
indicates VBAT1 is disconnected from VBAT2. This output is valid only in the Active states.
BSWTH
Input
Input for setting automatic battery switch threshold. Normally tied to Battery 2. Tie to ground for
manual switching.
C3–C1
Input
Decoder. TTL compatible. C3 is MSB and C1 is LSB.
C4
Input
Test Relay Input – Active Low. 1 = Off. 0 = On.
CAS
Capacitor
DA
Input
Ring-trip negative. Negative input to ring-trip comparator.
DB
Input
Ring-trip positive. Positive input to ring-trip comparator.
DET
Output
E1
Input
HPA
Capacitor
High-Pass Filter Capacitor. A(TIP) side of high-pass filter capacitor.
HPB
Capacitor
High-Pass Filter Capacitor. B(RING) side of high-pass filter capacitor.
NC
—
OVH
Input
Analog and Digital ground.
Output of A(TIP) power amplifier.
Battery (power) ground.
Output of B(RING) power amplifier.
Anti-sat pin for capacitor to filter reference voltage when operating in anti-sat region.
Switchhook detector. When enabled, a logic Low indicates the selected detector is tripped. The detector
is selected by the logic inputs (C3–C1). The output is open-collector with a built-in 15 kΩ pull-up
resistor.
Ground-Key Detect Select. E1 = 1 selects the hook switch detector. E1 = 0 selects the ground-key
detector. In the Tip Open state, ground key is selected independent of E1.
No connect. This pin not internally connected.
Overhead Control. Logic High enables minimized nonmetering overhead. Logic Low enables 2.2 V
metering DC overhead. TTL-compatible.
RD
Resistor
Detector resistor. Detector threshold set and filter pin.
RDC
Resistor
DC feed resistor. Connection point for the DC feed current programming network. The other end of the
network connects to the receiver summing node (RSN). Connection point for the DC feed current
programming network. The other end of the network connects to RSN. VRDC is negative for normal
polarity and positive for reverse polarity.
RFA
—
RINGOUT
Output
RSN
Input
Resistive feed adjust. Adjust the DC feed resistance gain coefficient, GDC, with external resistor
connected to ground.
Ring Relay Driver. Open-collector driver with emitter internally connected to BGND.
Receive Summing Node. The metallic current (AC and DC) between A(TIP) and B(RING) is equal to
500 times the current into this pin. The networks that program receive gain, two-wire impedance, and
feed current all connect to this node.
RSVD
—
Reserved. These pins are reserved for Zarlink use. Make no connection to these pins.
TESTOUT
Output
Test Relay Driver. Open collector driver with emitter internally connected to AGND.
TMG
—
VBAT1
Battery
VBAT2
Battery
Battery supply for output power amplifiers. Switched to VBAT1 by BSWEN.
VCC
Power
+5 V power supply.
VTX
Output
Transmit Audio. This output is a 0.5066 unity gain version of the A(TIP) and B(RING) metallic voltage.
VTX also sources the two-wire input impedance programming network.
Exposed Pad
Battery
Thermal Management. External resistor connects this pin to VBAT2 to offload power dissipation from
SLIC. Functions during normal polarity, Active state.
Most negative battery supply and substrate connection.
This must be electrically tied to VBAT1.
4
Zarlink Semiconductor Inc.
Le79489
ABSOLUTE MAXIMUM RATINGS
Data Sheet
OPERATING RANGES
Commercial (C) Devices
Storage temperature. . . . . . . . . . . . . . . . . –55°C to +150°C
With respect to AGND/DGND:
VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –0.4 V to +7.0 V
Ambient temperature . . . . . . . . . . . . . . . . –40°C to +85°C*
VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.75 V to 5.25 V
VBAT1
Continuous. . . . . . . . . . . . . . . . . . . . . . +0.4 V to –70 V
10 ms . . . . . . . . . . . . . . . . . . . . . . . . . . +0.4 V to –75 V
BAT1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . –40.5 V to –60 V
BAT2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . –20 V to BAT1
VBAT2 and BSWTH. . . . . . . . . . . . . . . . . . +0.4 V to VBAT1
AGND/DGND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 V
BGND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +3 V to –3 V
BGND with respect to GND . . . . . . .–100 mV to +100 mV
A(TIP) or B(RING) with respect to BGND:
Continuous. . . . . . . . . . . . . . . . . . . . . . . .VBAT1 to +1 V
10 ms (f = 0.1 Hz) . . . . . . . . . . . . . . . . . . –70 V to +5 V
1 µs (f = 0.1 Hz) . . . . . . . . . . . . . . . . . . . –80 V to +8 V
250 ns (f = 0.1 Hz). . . . . . . . . . . . . . . . . –90 V to +12 V
Load resistance on VTX to GND . . . . . . . . . . . .20 kΩ min
Operating ranges define those limits over which the functionality of
the device is guaranteed by production testing.
*Zarlink guarantees the performance of this device over
commercial (0 to 70°C) and industrial (-40 to 85 °C) temperature
ranges by conducting electrical characterization over each range
and by conducting a production test with single insertion coupled
to periodic sampling. These characterization and test procedures
comply with section 4.6.2 of Bellcore TR-TSY-000357 Component
Reliability Assurance Requirements for Telecommunications
Equipment.
Current from A(TIP) or B(RING) . . . . . . . . . . . . . ±150 mA
TESTOUT/RINGOUT/current . . . . . . . . . . . . . . . . . 80 mA
TESTOUT/RINGOUT/voltage . . . . . . . . . . BGND to +7 V
TESTOUT/RINGOUT/transient . . . . . . . . BGND to +10 V
DA and DB inputs
Voltage on ring-trip inputs. . . . . . . . . . . . . VBAT1 to 0 V
Current on ring-trip inputs. . . . . . . . . . . . . . . . . ±10 mA
C4–C1, BSWEN, OVH, E1
Input voltage . . . . . . . . . . . . . . . –0.4 V to VCC + 0.4 V
Maximum power dissipation, continuous*
TA = 70°C, No heat sink (see note):
In 32-pin PLCC package . . . . . . . . . . . . . . . . . . . .1.7 W
Thermal data (θJA)
In 32-pin PLCC package ..............................43°C/W typ
ESD immunity (HBM) . . . . . . JESD22 Class 1C compliant
* Thermal limiting circuitry on chip will shut down the circuit at a
junction temperature of about 165°C. Continuous operation above
145°C junction temperature may degrade device reliability.
Stresses above those listed under Absolute Maximum Ratings may
cause permanent device failure. Functionality at or above these limits is not implied. Exposure to Absolute Maximum Ratings for extended periods may affect device reliability.
Package Assembly
Green package devices are assembled with enhanced,
environmental compatible lead-free, halogen-free, and
antimony-free materials. The leads possess a matte-tin
plating which is compatible with conventional board assembly
processes or newer lead-free board assembly processes.
The peak soldering temperature should not exceed 245°C
during printed circuit board
5
Zarlink Semiconductor Inc.
Le79489
Data Sheet
ELECTRICAL CHARACTERISTICS
Description
Test Conditions (See Note 1)
Min
Typ
Max
Unit
Note
dB
4, 6
20
Ω
4
+50
mV
Transmission Performance
2-wire return loss
(See Test Circuit D)
200 Hz to 3.4 kHz
26
Analog output (VTX) impedance
3
Analog output (VTX) offset voltage
Overload level, 2-wire
THD, Total Harmonic Distortion
THD, open loop
–50
Active state
2.5
Vpk
0 dBm
–64
–50
+7 dBm
–55
–40
0 dBm, RLAC = 600 Ω
dB
–36
2a, 3
3
4
Longitudinal Capability (See Test Circuit C)
0°C to +70°C
–40°C to +85°C
–40°C to +85°C
–3*
–2
–2
–2
52
60
58
54
0°C to +70°C
–40°C to +85°C
–40°C to +85°C
–3
–2
–2
–2
52
54
54
54
Longitudinal to metallic L-T
200 Hz to 1 kHz
Normal polarity
Normal polarity
Normal polarity
Reverse polarity
Longitudinal to metallic L-T
1 kHz to 3.4 kHz
Normal polarity
Normal polarity
Normal polarity
Reverse polarity
Longitudinal signal generation 4-L
200 Hz to 3.4 kHz
40
Longitudinal current per pin
(A or B)
Active state
15
Longitudinal impedance at A or B
0 to 100 Hz
dB
8
dB
27
mArms
Ω/pin
4
23
dBrnc
4
25
Longitudinal Induction
7
Idle Channel Noise
C-message weighted noise
RL = 600 Ω
+7
+12
dBrnC
4, 8
Psophometric weighted noise
RL = 600 Ω
–83
–78
dBmp
8
Insertion Loss (See Test Circuits A and B)
Gain, 4- to 2-wire
Gain, 2- to 4-wire, 4-to-4-wire
0 dBm, 1 kHz
0 dBm, 1 kHz
0°C to 70°C
–40°C to 85°C
–0.15
0
+0.15
–0.20
0
+0.20
0°C to 70°C
–40°C to 85°C
–6.05
–5.90
–5.75
–6.10
–5.90
–5.70
Gain, 4- to 2-wire
Open loop
–0.35
+0.35
Gain, 2- to 4-wire, 4- to 4-wire
Open loop
–6.25
Gain over frequency
300 to 3.4 kHz, relative to 1 kHz
–0.10
+0.10
Gain tracking
+3 dBm to –55 dBm relative to 0 dBm
–0.10
+0.10
Gain tracking open loop
0 dB to –15 dB
–0.35
+0.35
Group delay
0 dBm, 1 kHz
–5.90
4
Note:
* P.G. = Performance Grade
6
Zarlink Semiconductor Inc.
4
4
dB
–5.55
4
4
4
µs
4, 6
Le79489
Data Sheet
ELECTRICAL CHARACTERISTICS (CONTINUED)
Description
Test Conditions (See Note 1)
Min
Typ
Max
Unit
Note
Line Characteristics
IL, Active
Short loop
Medium loop
Long loop
RLDC = 250 Ω
RLDC = 700 Ω
RLDC = 2 kΩ
44.2
33.4
17.2
48.6
37.1
19.2
54.0
40.8
21.2
IL, Active
Short loop
Long loop
RLDC = 250 Ω
RLDC = 2 kΩ
44.2
16.0
48.6
18.0
54.0
20.0
0.7 IL
IL
1.3 IL
18
30
IL, Accuracy, Standby state
V BAT1 – 3 V
I L = ---------------------------------R L + 400
TA = 25°C
Current limited region
IL, Loop current, Disconnect state
RL = 0
ILLIM
Active, A and B to GND
95
100
µA
135
mA
52
Vapparent
VAB, Open loop voltage
mA
40.3
39.8
37
Active, Normal
Reverse Polarity
OVH = 0
4
41.7
41.7
39
V
BAT SW hysteresis
1150
mV
BAT SW threshold
(from VBAT1 to VBAT2)
BAT2
+ 8.5
V
IA, Leakage, Tip Open state
RL = 0
IB, Current, Tip Open state
B to GND
VA, Active
RA to BAT1 = 7 kΩ, RB to
GND = 100 Ω
18
30
–7.5
–5
100
µA
56
mA
V
4
Power Supply Rejection Ratio (Vripple = 100 mVrms), Active Normal State
VCC
50 Hz to 3.4 kHz
30
45
VBAT1
50 Hz to 3.4 kHz
28
50
VBAT2
50 Hz to 3.4 kHz
35
50
VBAT1, Open loop, RLAC = 600 Ω
(Anti-sat region)
50 Hz
100 Hz
200 Hz
500 Hz to 3.4 kHz
8
15
20
28
14
22
29
40
Effective internal resistance
CAS pin to GND
85
170
255
Open loop, Disconnect state
35
70
Open loop, Standby state
50
85
3
4
dB
4
kΩ
4
mW
9
Device Power Dissipation
Open loop, Active state
OVH = 1
150
250
Open loop, Active state
OVH = 0
550
620
Off hook, Standby state
RL = 600 Ω
1000
1300
Off hook, Active state
RL = 250 Ω
RL = 700 Ω
880
800
1200
1000
ICC,
Open Loop VCC supply current
Disconnect state
Standby state
Active state
2.5
3.0
6.3
4.5
4.5
9.5
IBAT1,
Open Loop VBAT1 supply current
Disconnect state
Standby state
Active state
0.5
0.7
2.8
1.0
1.5
4.8
Supply Currents, Battery
7
Zarlink Semiconductor Inc.
mA
Le79489
Data Sheet
ELECTRICAL CHARACTERISTICS (CONTINUED)
Description
Test Conditions (See Note 1)
Min
Typ
Max
Unit
Note
0.7
mVrms
4
RFI Rejection
RFI rejection
100 kHz to 30 MHz
(See Figure E)
Logic Inputs (C4–C1, E1, BSWEN, OVH [–5, –6 only])
VIH, Input High voltage
C3
C1, C2, C4, BSWEN, OVH, E1
2.5
2.0
V
VIL, Input Low voltage
0.8
IIH, Input High current C4–C1,
OVH, E1
–75
40
IIH, Input High current, BSWEN
–75
1200
IIL, Input Low current, except C1
–400
IIL, Input Low current, C1
–600
µA
–300
Logic Output (DET, BSWOUT)
VOL, Output Low voltage
IOUT = 0.3 mA
VOH, Output High voltage
IOUT = –0.05 mA
0.40
2.4
V
Ring-Trip Comparator Input (DA, DB)
Bias current
Offset voltage
Source resistance = 2 MΩ
–500
–50
–50
0
nA
+50
mV
5
Loop Detector
IT, Loop-detect threshold tolerance
Active state, Off-hook to On-hook
RD = 35.4 kΩ, IT = 368/RD
–15
+15
–20
+20
–15
+15
–20
+20
On-hook to Off-hook
RD = 35.4 kΩ, IT = 414/RD
Standby state, Off-hook to On-hook
RD = 35.4 kΩ, IT = 425/RD
%
On-hook to Off-hook
RD = 35.4 kΩ, IT = 471/RD
Loop-detect threshold hysteresis
Active state
1.3
Standby state
IGK, GND key-detector threshold
RL from BX to GND
Active, Standby, and Tip Open states
5
4
mA
9
13
+0.3
+0.7
V
100
µA
Relay Driver Output (RINGOUT/TESTOUT)
On voltage
IOL = 40 mA
Off leakage
VOH = +5 V
Zener breakover
IZ = 100 µA
Zener On voltage
IZ = 40 mA
6
7.5
7.9
8
Zarlink Semiconductor Inc.
10
V
Le79489
Data Sheet
RELAY DRIVER SCHEMATICS
RINGOUT
TESTOUT
BGND
BGND
Notes:
1. Unless otherwise specified, test conditions are VCC = +5 V, BAT1 = –50 V, BAT2 = –34 V, RL = 600 Ω, RDC1 = RDC2 = 5.833 kΩ, RTMG = 570
Ω, RD = 35.4 kΩ, RFA = 0 Ω, no fuse resistors, CHP = 0.22 µF, CDC = 0.5 µF, CCAS = 0.33 µF, CVBAT12 = 220 nF, D1 = D2 = 1N400x, OVH
= 1, two-wire AC input impedance is a 600 Ω resistance synthesized by the programming network shown below.
VTX
RT1 = 76 kΩ
CT1 = 120 pF
RT2 = 76 kΩ
RSN
RRX = 150 kΩ
VRX
2. a. Overload level exists when THD = 1%.
b. Overload level exists when THD = 1.5%.
3. This parameter is tested at 1 kHz in production. Performance at other frequencies is guaranteed by characterization.
4. Not tested in production. This parameter is guaranteed by characterization or correlation to other tests.
5. Tested with 0 Ω source impedance. 2 MΩ is specified for system design only.
6. Group delay can be greatly reduced by using a ZT network such as that shown in Note 1 above. The network reduces the group delay to
less than 2 µs and increases 2WRL. The effect of group delay on linecard performance also may be compensated for by synthesizing
complex impedance with the DSLAC™ or QSLAC™ device.
7. Minimum current level is guaranteed not to cause a false Loop Detect. The SLIC must be functional in this condition.
8. Four-wire performance is 5–9 dB better than the specified two-wire values.
9. Open loop, Active state, Metering mode power dissipation may be reduced from a typical of 550 mW to a typical of 150 mW by connecting
the DET pin to the OVH pin. This connection will force the SLIC into the nonmetering mode while on hook. With this connection, a metering signal sent after the SLIC goes on hook may be distorted on the 2W line because the SLIC is forced into the nonmetering mode. To
eliminate this distortion, a delay can be added between the time the SLIC goes on hook and the time the SLIC switches to nonmetering
mode by using an RC circuit for the DET pin to OVH pin connection.
9
Zarlink Semiconductor Inc.
Le79489
Data Sheet
Table 1. SLIC Decoding
DET Output
State
C3 C2 C1
2-Wire Status
E1 = 1
E1 = 0
0
0
0 0
Standby, Reverse Polarity
Loop detector
GK
1
0
0 1
Reserved
X
X
2
0
1 0
Active, Reverse Polarity
Loop detector
GK
3
0
1 1
Tip Open
GK or loop detector
GK
4
1
0 0
Disconnect
Ring trip
Ring trip
5
1
0 1
Ringing
Ring trip
Ring trip
6
1
1 0
Active, Normal
Loop detector
GK
7
1
1 1
Standby, Normal
Loop detector
GK
Table 2. User-Programmable Components
Z T = 253 ( Z 2WIN – 2R F )
ZT is connected between the VTX and RSN pins. The fuse resistors
are RF, and Z2WIN is the desired two-wire AC input impedance.
When computing ZT, the internal current amplifier pole and any
external stray capacitance between VTX and RSN must be taken
into account. The internal amplifier pole is:
22 kHz • R LAC
------------------------------------600 Ω ± 10%
ZRX is connected from VRX to RSN. ZT is defined above, and G42L
is the desired receive gain. ZL is the 2-wire load impedance.
ZL
500 ( Z T )
Z RX = ------------ • --------------------------------------------------G 42L Z T + 253 ( Z L + 2R F )
RDC1, RDC2, and CDC form the network connected to the RDC pin.
RDC1 and RDC2 are approximately equal. ILIMIT is the desired loop
current in the constant-current region.
625 ( GFA )
I LIMIT = --------------------------------R DC1 + R DC2
R DC1 + R DC2
R DC1 • R DC2
C DC = 1.5 ms • --------------------------------
( RFA + 30.1 kΩ )
GFA = 0.99 • ------------------------------------------( RFA + 32 kΩ )
( RFA + 60 kΩ )
RCL = 1.4 • ( R DC1 + R DC2 ) • -----------------------------------------( RFA + 100 kΩ )
365
R D = --------- ,
IT
RD and CD form the network connected from RD to AGND/DGND
and IT is the threshold current between on hook and off hook in the
Active state.
msC D = 0.5
---------------
RD
CCAS is the regulator filter capacitor and fc is the desired filter
cutoff frequency.
1
C CAS = ----------------------------5
3.4 • 10 πf c
V BAT1 – 3 V
I S tan dby = ---------------------------------400 Ω + R L
Standby loop current (resistive region).
C BSWEN = 5 µmhos • T D ( ms )
CBSWEN is connected from BSWEN to GND for automatic
switching. TD is the delay in switching from BAT1 to BAT2. The
delay from BAT2 to BAT1 is about 0.1 TD.
10
Zarlink Semiconductor Inc.
Le79489
Data Sheet
Table 2. User-Programmable Components (continued)
The DC feed resistance can be adjusted with a resistance (RFA)
from the RFA pin to ground.
R DC1 + R DC2
R FEED = 2 • R FUSE + ---------------------------------
GDC
40 kΩ + RFA
GDC = 47.9 -------------------------------------
120 kΩ + RFA
Thermal Management Equations (Active, Normal, and Reverse Polarity States)
V BAT2 – 6 V
R TMG ≥ ----------------------------------I LOOPmax
(OVH = 1)
V BAT2 – 7.5 V
R TMG ≥ --------------------------------------I LOOPmax
(OVH = 0)
RTMG is connected from TMG to VBAT2 and is used to limit
power dissipation within the SLIC in Active states only.
Power dissipated in the thermal management resistor, RTMG,
during the Active states.
2
P RTMG
( V BAT2 – 6 V – ( I L • R L ) ) ( R TMG )
= ------------------------------------------------------------------------------------------2
( R TMG + 40 )
(OVH = 1)
2
( V BAT2 – 7.5 V – ( I L • R L ) ) ( R TMG )
P RTMG = ----------------------------------------------------------------------------------------------2
( R TMG + 40 )
(OVH = 0)
Power dissipated in the SLIC while in the Active states.
2
P SLIC = ( V BAT2 • I L ) – P RTMG – R L • ( I L ) + 0.22 W
11
Zarlink Semiconductor Inc.
Le79489
Data Sheet
DC FEED CHARACTERISTICS
RFA = 0 Ω
RDC = RDC1 + RDC2 = 11.67 kΩ,
No fuse resistors
OVH = 1
BAT1 = –50 V
60
18.8 mA, 38.8 V
3
41.5 V
48.0 mA, 18.5 V
VAB
(Volts)
2
1
0
50.0 mA
IL (mA)
0
Notes:
Graph is for illustration only.
1.
V AB = I LIMIT • RCL – I L • RCL
RDC
2. V AB = 52 V – I L -------------
GDC
3a.
RDC
V AB = 0.8 V BAT1 + 2.2 – I L ------------------------ , OVH = 1
5 • GDC
RDC
3b. V AB = 0.8 V BAT1 – 1.0 – I L ------------------------ , OVH = 0
5 • GDC
a. Load Line (Typical)
A
a
RL
IL
SLIC
RSN
RDC1
b
RDC2
B
RDC
Feed current programmed by RDC1 and RDC2
b. Feed Programming
Figure 1.
DC Feed Characteristics
12
Zarlink Semiconductor Inc.
CDC
60
Le79489
Data Sheet
TEST CIRCUITS
A(TIP)
A(TIP)
VTX
RL
VTX
SLIC
2
SLIC
AGND
VL
RT
VAB
RL
VAB
AGND
RT
RL
RRX
2
RRX
RSN
RSN
B(RING)
VRX
B(RING)
IL2-4 = –20 log (VTX / VAB)
IL4-2 = –20 log (VAB / VRX)
B. Four- to Two-Wire Insertion Loss
A. Two- to Four-Wire Insertion Loss
1
ωC