ETC HC5514

HC55120, HC55121, HC55130, HC55131, HC55140,
HC55141, HC55142, HC55143, HC55150, HC55151
®
Data Sheet
June 2002
Low Power UniSLIC14 Family
Features
The UniSLIC14 is a family of Ultra Low Power SLICs. The
feature set and common pinouts of the UniSLIC14 family
positions it as a universal solution for: Plain Old Telephone
Service (POTS), PBX, Central Office, Loop Carrier, Fiber in
the Loop, ISDN-TA and NT1+, Pairgain and Wireless Local
Loop.
• Ultra Low Active Power (OHT) < 60mW
• Single/Dual Battery Operation
The UniSLIC14 family achieves its ultra low power operation
through: Its automatic single and dual battery selection (based
on line length) and battery tracking anti clipping to ensure the
maximum loop coverage on the lowest battery voltage. This
architecture is ideal for power critical applications such as
ISDN NT1+, Pairgain and Wireless local loop products.
• Zero Crossing Ring Control
- Zero Voltage On/Zero Current Off
The UniSLIC14 family has many user programmable features.
This family of SLICs delivers a low noise, low component
count solution for Central Office and Loop Carrier universal
voice grade designs. The product family integrates advanced
pulse metering, test and signaling capabilities, and zero
crossing ring control.
The UniSLIC14 family is designed in the Intersil “Latch” free
Bonded Wafer process. This process dielectrically isolates the
active circuitry to eliminate any leakage paths as found in our
competition’s JI process. This makes the UniSLIC14 family
compliant with “hot plug” requirements and operation in harsh
outdoor environments.
Block Diagram
RRLY
TRLY1
DR
STATE
DECODER
AND
DETECTOR
LOGIC
RING AND TEST
RELAY DRIVERS
ZERO CURRENT
CROSSING
RING TRIP
DETECTOR
LOOP CURRENT
DETECTOR
GKD/LOOP LENGTH
DETECTOR
LINE FEED
CONTROL
2-WIRE
RING
BGND
AGND
INTERFACE
4-WIRE INTERFACE
VF SIGNAL PATH
VBH
VBL
VCC
C1
C2
C3
C4
C5
SHD
GKD_LVM
CRT_REV_LVM
POLARITY
REVERSAL
TIP
Automatic Silent Battery Selection
Power Management/Shutdown
Battery Tracking Anti Clipping
Single 5V Supply with 3V Compatible Logic
•
•
•
•
•
Tip/Ring Disconnect
Pulse Metering Capability
4 Wire Loopback
Programmable Current Feed
Programmable Resistive Feed
•
•
•
•
Programmable Loop Detect Threshold
Programmable On-Hook and Off-Hook Overheads
Programmable Overhead for Pulse Metering
Programmable Polarity Reversal Time
•
•
•
•
•
Selectable Transmit Gain 0dB/-6dB
2 Wire Impedance Set by Single Network
Loop and Ground Key Detectors
On-Hook Transmission
Common Pinout
• HC55121
- Polarity Reversal
• HC55130
- -63dB Longitudinal Balance
TRLY2
DT
•
•
•
•
FN4659.10
BATTERY
SELECTION
AND
BIAS
NETWORK
PULSE METERING
SIGNAL PATH
ILIM
RSYNC_REV
ROH
CDC
RDC_RAC
RD
VTX
VRX
PTG
ZT
CH
• HC55140
- Polarity Reversal
- Ground Start
- Line Voltage Measurement
- 2 Wire Loopback
- -63dB Longitudinal Balance
• HC55142
- Polarity Reversal
- Ground Start
- Line Voltage Measurement
- 2.2VRMS Pulse Metering
- 2 Wire Loopback
• HC55150
- Polarity Reversal
- Line Voltage Measurement
- 2.2VRMS Pulse Metering
- 2 Wire Loopback
Related Literature
• AN9871, User’s Guide for UniSLIC14 Eval Board
• AN9903, UniSLIC14 and TI TCM38C17
SPM
1
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Ordering Information
MAX
LOOP
CURRENT
(mA)
PART
NUMBER
POLARITY
REVERSAL
GND
START
GND
KEY
LINE
VOLTAGE
MEASUREMENT
†
2 TEST
RELAY
PULSE
METERING DRIVERS
2 WIRE
LOOPBACK
†
TEMP
LONGITUDINAL RANGE
(oC)
BALANCE
PKG.
NO.
HC55120CB
30
•
53dB
0 to 70 M28.3
SOIC
HC55120CM
30
•
53dB
0 to 70 N28.45
PLCC
HC55121IB
30
•
•
•
•
53dB
-40 to M28.3
85
SOIC
HC55121IM
30
•
•
•
•
53dB
-40 to N28.45
85
PLCC
HC55130IB
45
63dB
-40 to M28.3
85
SOIC
HC55130IM
45
63dB
-40 to N28.45
85
PLCC
HC55131IM
45
63dB
-40 to N32.45x55
85
PLCC
HC55140IB
45
•
•
•
•
•
63dB
-40 to M28.3
85
SOIC
HC55140IM
45
•
•
•
•
•
63dB
-40 to N28.45
85
PLCC
HC55141IM
45
•
•
•
•
•
63dB
-40 to N32.45x55
85
PLCC
HC55142IB
45
•
•
•
•
•
•
63dB
-40 to M28.3
85
SOIC
HC55142IM
45
•
•
•
•
•
•
63dB
-40 to N28.45
85
PLCC
HC55143IM
45
•
•
•
•
•
•
63dB
-40 to N32.45x55
85
PLCC
HC55150CB
45
•
•
•
•
55dB
0 to 70 M28.3
SOIC
HC55150CM
45
•
•
•
•
55dB
0 to 70 N28.45
PLCC
HC55151CM
45
•
•
•
•
55dB
0 to 70 N32.45x55
PLCC
•
•
•
•
HC5514XEVAL1 Evaluation board
† Available by placing SLIC in Test mode.
Device Operating Modes
C3
C2
C1
0
0
0
0
0
0
0
DESCRIPTION
HC55120
HC55121
HC55130/1
HC55140/1
HC55142/3
HC55150/1
Open Circuit
4-Wire Loopback
•
•
•
•
•
•
1
Ringing
•
•
•
•
•
•
1
0
Forward Active
•
•
•
•
•
•
1
1
Test Forward Active
2 Wire Loopback and
Line Voltage Measurement
•
•
•
1
0
0
Tip Open Ground Start
•
•
1
0
1
Reserved
•
•
•
1
1
0
Reverse Active
•
•
•
1
1
1
Test Reverse Active
Line Voltage Measurement
•
•
•
•
•
2
•
•
•
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Absolute Maximum Ratings TA = 25oC
Thermal Information
Temperature, Humidity
Storage Temperature Range . . . . . . . . . . . . . . . . -65oC to 150oC
Operating Temperature Range . . . . . . . . . . . . . . -40oC to 110oC
Operating Junction Temperature Range . . . . . . . -40oC to 150oC
Power Supply (-40oC ≤ TA ≤ 85oC)
Supply Voltage V CC to GND . . . . . . . . . . . . . . . . . . . . -0.4V to 7V
Supply Voltage VBL to GND. . . . . . . . . . . . . . . . . . . .-VBH to 0.4V
Supply Voltage VBH to GND, Continuous . . . . . . . . . -75V to 0.4V
Supply Voltage VBH to GND, 10ms . . . . . . . . . . . . . . -80V to 0.4V
Relay Driver
Ring Relay Supply Voltage . . . . . . . . . . . . . . . . . . . . . . 0V to 14V
Ring Relay Current. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50mA
Digital Inputs, Outputs (C1, C2, C3, C4, C5, SHD, GKD_LVM)
Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.4V to VCC
Output Voltage (SHD, GKD_LVM Not Active) . . . . . -0.4V to VCC
Output Current (SHD, GKD_LVM) . . . . . . . . . . . . . . . . . . . . . 5mA
ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .500V
Gate Count. . . . . . . . . . . . . . . . . . . . . . . 543 Transistors, 51 Diodes
Tipx and Ringx Terminals (-40oC ≤ TA ≤ 85oC)
Tipx or Ringx Current . . . . . . . . . . . . . . . . . . . . -100mA to 100mA
Thermal Resistance (Typical, Note 1)
θJA
28 Lead PLCC Package. . . . . . . . . . . . . . . . . . . . . .
52oC/W
28 Lead SOIC Package . . . . . . . . . . . . . . . . . . . . . .
45oC/W
32 Lead PLCC Package. . . . . . . . . . . . . . . . . . . . . .
66.2oC/W
Continuous Power Dissipation at 85oC
28 Lead PLCC Package. . . . . . . . . . . . . . . . . . . . . . . . . . . . .1.5W
28 Lead SOIC Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2.0W
32 Lead PLCC Package. . . . . . . . . . . . . . . . . . . . . . . . . . . . .1.4W
Lead Temperature (Soldering 10s). . . . . . . . . . . . . . . . . . . . . . . . 300oC
(PLCC, SOIC - Lead Tips Only)
Derate above 70oC
Tip and Ring Terminals
Tipx or Ringx, Current, Pulse < 10ms, TREP > 10s . . . . . . . . . .2A
Tipx or Ringx, Current, Pulse < 1ms, TREP > 10s . . . . . . . . . . .5A
Tipx or Ringx, Current, Pulse < 10µs, TREP > 10s . . . . . . . . . 15A
Tipx or Ringx, Current, Pulse < 1µs, TREP > 10s . . . . . . . . . . 20A
Tipx or Ringx, Pulse < 250ns, TREP > 10s
20A
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the
device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
NOTE:
1. θJA is measured with the component mounted on an evaluation PC board in free air.
Typical Operating Conditions
These represent the conditions under which the device was developed and are suggested as guidelines.
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
0
-
70
oC
-40
-
85
oC
VBH with Respect to GND
-58
-
-8
V
VBL with Respect to GND
VBH
-
0
V
VCC with Respect to GND
4.75
-
5.25
V
Ambient Temperature
HC55120, HC55150/1
HC55121, HC55130/1, HC55140/1,
HC55142/3
3
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
2-WIRE PORT
1% THD, IDCMET ≥ 18mA
(Note 2, Figure 1)
3.2
-
-
VPEAK
Forward
Only
•
Forward
Only
•
•
•
Overload Level, On Hook
Forward and Reverse
1% THD, IDCMET ≤ 5mA
(Note 3, Figure 1)
1.3
-
-
VPEAK
Forward
Only
•
Forward
Only
•
•
•
Input Impedance (Into Tip and Ring)
-
ZT /200
-
Ω
•
•
•
•
•
•
Longitudinal Impedance (Tip, Ring) 0 < f < 100Hz (Note 4, Figure 2)
Forward and Reverse
-
0
-
Ω/Wire
Forward
Only
•
Forward
Only
•
•
•
28
-
-
mARMS/Wire
Forward
Only
•
Forward
Only
•
•
•
4
Overload Level, Off Hook
Forward and Reverse
LONGITUDINAL CURRENT LIMIT (TIP, RING)
No False Detections, (Loop
Current), LB > 45dB (Notes 5, 6,
Figures 3A, 3B)
On-Hook, Off-Hook (Active),
RL = 736Ω
Forward and Reverse
TIP
AT
1VRMS
VTX
0 < f < 100Hz
EL
C
VTR
TIP
VTX
RING
VRX
VT
300Ω
RL
300Ω
IDCMET
ERX
RING
VR
AR
VRX
LZT = VT/AT
FIGURE 1. OVERLOAD LEVEL (OFF HOOK, ON HOOK)
FIGURE 2. LONGITUDINAL IMPEDANCE
368Ω
368Ω
A
10µF
LZR = VR/AR
VTX
TIP
A
C
TIP
VTX
VTX
C
EL
EL
10µF
C
A
RING
VRX
368Ω
SHD
FIGURE 3A. LONGITUDINAL CURRENT LIMIT ON-HOOK (ACTIVE)
A
RING
368Ω
VRX
SHD
FIGURE 3B. LONGITUDINAL CURRENT LIMIT OFF-HOOK (ACTIVE)
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part.
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
MIN
MIN
HC55130/1 HC55140/1 HC55142/3 HC55150/1
OFF-HOOK LONGITUDINAL BALANCE
Longitudinal to Metallic (Note 7)
Forward and Reverse
5
Longitudinal to Metallic (Note 7)
Forward and Reverse
Longitudinal to 4-Wire (Note 9)
(Forward and Reverse)
IEEE 455 - 1985, RLR, RLT = 368Ω
Normal Polarity:
Forward
Only
MIN
MIN
MIN
MIN
55
Forward
Only
0.2kHz < f < 1.0kHz, 0oC to 70oC
-
-
-
dB
53
NA
NA
NA
NA
1.0kHz < f < 3.4kHz, 0oC to 70oC
-
-
-
dB
53
NA
NA
NA
NA
55
0.2kHz < f < 1.0kHz, -40oC to 85oC
-
-
-
dB
NA
53
63
63
63
NA
1.0kHz < f < 3.4kHz, -40oC to 85oC
-
-
-
dB
NA
53
58
58
58
NA
Reverse Polarity 0.2kHz < f < 3.4kHz,
(Figure 4)
-
-
-
dB
NA
53
NA
58
58
55
MIN
MIN
MIN
MIN
MIN
MIN
55
RLR, RLT = 300Ω,
Normal Polarity:
Forward
Only
Forward
Only
0.2kHz < f < 1.0kHz, 0oC to 70oC
-
-
-
dB
53
NA
NA
NA
NA
1.0kHz < f < 3.4kHz, 0oC to 70oC
-
-
-
dB
53
NA
NA
NA
NA
55
0.2kHz < f < 1.0kHz, -40oC to 85oC
-
-
-
dB
NA
53
63
63
63
NA
1.0kHz < f < 3.4kHz, -40oC to 85oC
-
-
-
dB
NA
53
58
58
58
NA
Reverse Polarity 0.2kHz < f < 3.4kHz,
(Figure 4)
-
-
-
dB
NA
53
NA
58
58
55
MIN
MIN
MIN
MIN
MIN
MIN
61
Normal Polarity:
Forward
Only
0.2kHz < f < 1.0kHz, 0oC to 70oC
-
1.0kHz < f < 3.4kHz, 0oC to 70oC
0.2kHz < f < 1.0kHz, -40oC to 85oC
1.0kHz < f < 3.4kHz, -40oC to 85oC
-
-
-
-
-
-
-
-
-
-
-
Reverse Polarity 0.2kHz < f < 3.4kHz,
(Figure 4)
-
-
dB
Forward
Only
53
NA
NA
NA
NA
dB
53
NA
NA
NA
NA
61
dB
NA
53
63
63
63
NA
dB
NA
53
58
58
58
NA
dB
NA
53
NA
58
58
61
Metallic to Longitudinal (Note 10)
Forward and Reverse
FCC Part 68, Para 68.310 (Note 8)
0.2kHz < f < 3.4kHz, (Figure 5)
40
50
-
dB
Forward
Only
•
Forward
Only
•
•
•
4-Wire to Longitudinal (Note 11)
Forward and Reverse
0.2kHz < f < 3.4kHz, (Figure 5)
40
-
-
dB
Forward
Only
•
Forward
Only
•
•
•
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
RLT
TIP
EL
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
RLT
300Ω
VTX
C
VTX
TIP
VTX
2.16µF
ETR
VTR
ERX
C
2.16µF
VL
6
RING
RLR
VRX
RLR
300Ω
FIGURE 4. LONGITUDINAL TO METALLIC AND LONGITUDINAL TO 4-WIRE BALANCE
2-Wire Return Loss
Forward and Reverse
VRX
RING
FIGURE 5. METALLIC TO LONGITUDINAL AND 4-WIRE TO LONGITUDINAL
BALANCE
0.2kHz to 1.0kHz (Note 12, Figure 6)
30
35
-
dB
1.0kHz to 3kHz (Note 12, Figure 6)
23
25
-
dB
Forward
Only
3kHz to 3.4kHz (Note 12, Figure 6)
21
23
-
dB
-2.6
-2.2
-1.8
V
Forward
Only
•
Active, IL < 5mA
-46.4
-45.3
-44.2
V
Tip open, IL < 5mA
-46.4
-45.3
-44.2
V
Forward
Only
•
Forward
Only
•
•
•
Forward
Only
•
•
•
•
Forward
Only
•
•
•
TIP IDLE VOLTAGE (User Programmable)
Active, IL < 5mA
TIPX Idle Voltage
Forward and Reverse
RING IDLE VOLTAGE (User Programmable)
RINGX Idle Voltage
Forward and Reverse
VTR
Forward and Reverse
Active, IL < 5mA
41
43.1
45
V
Forward
Only
•
Forward
Only
•
•
•
VTR(ROH) Pulse Metering
Forward and Reverse
Active, IL≥ 8.5mA, ROH = 50kΩ
36
38.1
-
V
NA
•
NA
NA
•
•
ZD
TIP
R
TIP
VTX
VTX
VTR
VM
600Ω
VS
R
VTX
EG
ZL
RL
ZIN
RING
VRX
RING
VRX
RLR
FIGURE 6. TWO-WIRE RETURN LOSS
FIGURE 7. OVERLOAD LEVEL (4-WIRE TRANSMIT PORT), OUTPUT OFFSET
VOLTAGE AND HARMONIC DISTORTION
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
Overload Level, Off Hook (IL≥ 18mA) (ZL > 20kΩ, IL 1% THD) (Note 13,
Forward and Reverse
Figure 7) TA = 0oC to 85oC
TA = -40oC to 0oC
3.2
-
-
VPEAK
Forward
Only
•
Forward
Only
•
•
•
3.0
-
-
VPEAK
Overload Level, On Hook (IL ≤ 5mA) (ZL > 20kΩ, 1% THD)
Forward and Reverse
(Note 14, Figure 7)
1.3
-
-
VPEAK
Forward
Only
•
Forward
Only
•
•
•
-200
-
200
mV
Forward
Only
•
Forward
Only
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
4-WIRE TRANSMIT PORT (V TX)
7
VTX Output Offset Voltage
Forward and Reverse
EG = 0, ZL = ∞, (Note 15, Figure 7)
Output Impedance
(Guaranteed by Design)
0.2kHz < f < 03.4kHz
-
0.1
1
Ω
0.2kHz < f < 3.4kHz
-
500
600
kΩ
4-WIRE RECEIVE PORT (VRX)
VRX Input Impedance
(Guaranteed by Design)
FREQUENCY RESPONSE (OFF-HOOK)
Relative to 0dBm at 1.0kHz, ERX = 0V
2-Wire to 4-Wire
Forward and Reverse
0.3kHz < f < 3.4kHz
4-Wire to 2-Wire
Forward and Reverse
-0.15
-
0.15
dB
f = 8.0kHz (Note 16, Figure 8)
-
0.24
0.5
dB
f = 12kHz (Note 16, Figure 8)
-
0.58
1.0
dB
f = 16kHz (Note 16, Figure 8)
-
1.0
1.5
dB
Relative to 0dBm at 1.0kHz, E G = 0V
0.3kHz < f < 3.4kHz
-0.15
-
0.15
dB
f = 8kHz (Note 17, Figure 8)
-0.5
0.24
-
dB
f = 12kHz (Note 17, Figure 8)
-1.0
0.58
-
dB
f = 16kHz (Note 17, Figure 8)
-1.5
1.0
-
dB
0.3kHz < f < 3.4kHz (Note 18, Figure 8) -0.15
-
0.15
dB
8kHz, 12kHz, 16kHz (Note 18, Figure 8)
0
0.5
dB
Relative to 0dBm at 1.0kHz, E G = 0V
4-Wire to 4-Wire
Forward and Reverse
TIP
-0.5
Forward
Only
Forward
Only
•
Forward
Only
Forward
Only
•
Forward
Only
Forward
Only
•
VTX
TIP
VTX
VTX
VTX
EG
RL
600Ω
OPEN
VTR
PTG
RL
600Ω
VTR
ERX
RING
VRX
FIGURE 8. FREQUENCY RESPONSE, INSERTION LOSS, GAIN TRACKING
AND HARMONIC DISTORTION
RING
VRX
FIGURE 9. IDLE CHANNEL NOISE
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
Forward
Only
•
Forward
Only
•
•
•
INSERTION LOSS
2-Wire to 4-Wire
Forward and Reverse
0dBm, 1kHz
4-Wire to 2-Wire
Forward and Reverse
8
PTG = Open (Note 19, Figure 8)
-0.2
-
0.2
dB
PTG = GND (Note 20, Figure 8)
-6.22
-6.02
-5.82
dB
0dBm, 1kHz (Note 21, Figure 8)
-0.2
-
0.2
dB
Forward
Only
•
Forward
Only
•
•
•
Forward
Only
•
Forward
Only
•
•
•
Forward
Only
•
Forward
Only
•
•
•
Forward
Only
•
Forward
Only
•
•
•
Forward
Only
•
Forward
Only
•
•
•
GAIN TRACKING (Ref = -10dBm, at 1.0kHz)
2-Wire to 4-Wire
Forward and Reverse
4-Wire to 2-Wire
Forward and Reverse
-40dBm to +3dBm (Note 22, Figure 8)
-0.1
-
0.1
dB
-55dBm to -40dBm (Note 22, Figure 8)
-0.2
-
0.2
dB
-40dBm to +3dBm (Note 23, Figure 8)
-0.1
-
0.1
dB
-55dBm to -40dBm (Note 23, Figure 8)
-0.2
-
0.2
dB
NOISE
Idle Channel Noise at 2-Wire
C-Message Weighting
-
10.5
13
dBrnC
Forward and Reverse
Psophometric Weighting (Note 24,
Note 30, Figure 9)
-
-79.5
-77
dBmp
Idle Channel Noise at 4-Wire
C-Message Weighting
-
10.5
13
dBrnC
Forward and Reverse
Psophometrical Weighting
(Note 25, Note 30, Figure 9)
-
-79.5
-77
dBmp
2-Wire to 4-Wire
Forward and Reverse
0dBm, 0.3kHz to 3.4kHz
(Note 26, Figure 7)
-
-67
-50
dB
Forward
Only
•
Forward
Only
•
•
•
4-Wire to 2-Wire
Forward and Reverse
0dBm, 0.3kHz to 3.4kHz
(Note 27, Figure 8)
-
-67
-50
dB
Forward
Only
•
Forward
Only
•
•
•
HARMONIC DISTORTION
TIP
VBH
VTX
7kΩ
TIP
VTX
RING
VRX
S
RL
600Ω
R LIM
RLIM
38.3kΩ
VTR
IR1
R1
RING
VRX
FIGURE 10. CONSTANT LOOP CURRENT TOLERANCE
FIGURE 11. TIPX VOLTAGE
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
0.92IL
IL
1.08IL
mA
Forward
Only
•
Forward
Only
•
•
•
-
-
-200
µA
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
BATTERY FEED CHARACTERISTICS
9
Constant Loop Current Tolerance
18mA ≤ IL ≤ 45mA,
IL = 26.5mA, RLIM = 38.3kΩ
Forward and Reverse
(Note 27, Figure 10)
Tip Open State TIPX Leakage
Current
S = Closed (Figure 11)
Tip Open State RINGX Current
R1 = 0Ω, VBH = -48V, RLIM = 38.3kΩ
22.6
26.8
31
mA
R1 = 2.5kΩ, VBH = -48V (Figure 11)
15.5
17.1
18.2
mA
-
42.8
-
V
•
•
•
-5.3
-4.8
-4.3
V
NA
NA
NA
•
•
NA
-48V Through 7kΩ, Ring Lead to
Ground Through 150Ω (Figure 11)
-5.3
-4.8
-4.3
V
NA
NA
NA
•
•
NA
(Active) RL = 0Ω
-20
0
20
µA
•
•
•
•
•
•
0.9ILTh
ILTh
1.1ILTh
mA
Forward
Only
•
•
•
•
•
Tip Open State RINGX Voltage
5mA < IR1 < 26mA (Figure 11)
Tip Voltage (Ground Start)
Active State, (S Open) R1 = 150Ω
(Figure 11)
Tip Voltage (Ground Start)
Active State, (S Closed) Tip Lead to
Open Circuit State Loop Current
LOOP CURRENT DETECTOR
Programmable Threshold
ILTh = (500/ RD) ≥ 5mA,
Forward and Reverse
ILTh = 8.5mA
•
Forward
Only
RD = 58.8kΩ
GROUND KEY DETECTOR
Ground Key Detector Threshold
Tip/Ring Current Difference
5
8
11
mA
Active (Note 29, R1 = 2.5kΩ, Figure 12)
Tip Open
12.5
20
27.5
mA
Pulse Width = (20)(CREV.../ILIM)
0.32
0.36
0.4
NA
NA
•
•
ms/V
NA
NA
NA
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
LINE VOLTAGE MEASUREMENT
Pulse Width (GKD_LVM)
RING TRIP DETECTOR (DT, DR)
Ring Trip Comparator Current
Source Res = 2MΩ
-
2
-
µA
Input Common-Mode Range
Source Res = 2MΩ
-
-
±200
V
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
HC55130/1 HC55140/1 HC55142/3 HC55150/1
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
RING RELAY DRIVER
VSAT at 30mA
IOL = 30mA
-
0.2
0.5
V
VSAT at 40mA
IOL = 40mA
-
0.52
0.8
V
Off State Leakage Current
VOH = 13.2V
-
0.1
10
µA
•
•
•
10
TEST RELAY DRIVER (TRLY1, TRLY2)
VSAT at 30mA
IOL = 30mA
-
0.3
0.5
V
NA
NA
NA/•
NA/•
NA/•
NA/•
VSAT at 40mA
IOL = 40mA
-
0.65
1.3
V
NA
NA
NA/•
NA/•
NA/•
NA/•
Off State Leakage Current
VOH = 13.2V
-
-
10
µA
NA
NA
NA/•
NA/•
NA/•
NA/•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
TIP
VTX
VRX
RING
2.5kΩ
SHD
FIGURE 12. GROUND KEY DETECT
DIGITAL INPUTS (C1, C2, C3, C4, C5)
Input Low Voltage, V IL
0
-
0.8
V
Input High Voltage, VIH
2.0
-
VCC
V
Input Low Current, IIL
VIL = 0.4V
-
-
-10
µA
Input High Current, IIH
VIH = 2.5V
-
25
50
µA
-
-
0.5
V
Forward
Only
•
Forward
Only
•
•
•
2.7
-
-
V
Forward
Only
•
Forward
Only
•
•
•
-
-
0.5
V
GKD
GKD
NA
GKD_
LVM
GKD_
LVM
LVM
2.7
-
-
V
GKD
GKD
NA
GKD_
LVM
GKD_
LVM
LVM
-
15
-
kΩ
•
•
•
•
•
•
DETECTOR OUTPUTS (SHD, GKD_LVM)
SHD Output Low Voltage, VOL
Forward, Reverse
IOL = 1mA
SHD Output High Voltage, VOH
Forward, Reverse
IOH = 100µA
GKD_LVM Output Low Voltage,
VOL Forward and Tip Open
IOL = 1mA
R1 = 2.5kΩ (Figure 11)
GKD_LVM Output High Voltage,
VOH Forward and Tip Open
IOH = 100µA
Internal Pull-Up Resistor
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
TA = -40oC to 85oC, VCC = +5V ±5%, VBH = -48V, VBL = -24V, PTG = Open, R P1 = RP2 = 0Ω, ZT = 120kΩ, R LIM = 38.3kΩ, RD = 50kΩ, RDC_RAC =
20kΩ, ROH = 40kΩ, C H = 0.1µF, C DC = 4.7µF, CRT/REV = 0.47µF, GND = 0V, RL = 600Ω. Unless Otherwise Specified. (•) Symbol used to indicate the
test applies to the part. (NA) symbol used to indicate the test does not apply to the part. (Continued)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
HC55120
HC55121
-
25
-
mW
Forward
Only
•
HC55130/1 HC55140/1 HC55142/3 HC55150/1
POWER DISSIPATION (VBH = -48V, VBL = -24V)
Open Circuit State
C1, C2, C3 = 0, 0, 0
On-Hook, Active
C1, C2, C3 = 0, 1, 0
C1, C2, C3 = 1, 1, 0
Forward and Reverse
IL = 0mA, Longitudinal
Current = 0mA
Forward
Only
•
•
•
•
•
•
•
52
-
mW
Forward
Only
•
Forward
Only
•
•
•
-
2.25
3.0
mA
Forward
Only
•
Forward
Only
•
•
•
VBH Current, IBH
-
0.3
0.45
mA
Forward
Only
•
Forward
Only
•
•
•
VBL Current, IBL
-
0.022
0.035
mA
Forward
Only
•
Forward
Only
•
•
•
-
2.7
3.6
mA
Forward
Only
•
Forward
Only
•
•
•
-
0.8
1.06
mA
Forward
Only
•
Forward
Only
•
•
•
-
-
0.01
mA
Forward
Only
•
Forward
Only
•
•
•
-
40
-
dB
Forward
Only
•
Forward
Only
•
•
•
VBH to 2 or 4 Wire Port
Forward and Reverse
-
40
-
dB
Forward
Only
•
Forward
Only
•
•
•
VBL to 2 or 4 Wire Port
Forward and Reverse
-
40
-
dB
Forward
Only
•
Forward
Only
•
•
•
-
175
-
oC
•
•
•
•
•
•
11
-
POWER SUPPLY CURRENTS (V BH = -48V, VBL = -24V)
VCC Current, ICC
VCC Current, ICC
Forward and Reverse
VBH Current, IBH
Forward and Reverse
Open Circuit State
Active State
IL = 0mA, Longitudinal
Current = 0mA
VBL Current, IBL
Forward and Reverse
POWER SUPPLY REJECTION RATIOS
VCC to 2 or 4 Wire Port
Forward and Reverse
Active State RL = 600Ω
50Hz < f < 3400Hz, VIN =100mV
TEMPERATURE GUARD
Junction Threshold Temperature
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Electrical Specifications
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Notes
2. Overload Level (Two-Wire Port, Off Hook) - The overload
level is specified at the 2-wire port (VTR) with the signal source at
the 4-wire receive port (ERX). RL = 600Ω, IDCMET ≥ 18mA.
Increase the amplitude of ERX until 1% THD is measured at VTR.
Reference Figure 1.
3. Overload Level (Two-Wire Port, On Hook) - The overload
level is specified at the 2-wire port (VTR) with the signal source at
the 4-wire receive port (ERX). RL = ∞, IDCMET = 0mA. Increase
the amplitude of ERX until 1% THD is measured at VTR.
Reference Figure 1.
4. Longitudinal Impedance - The longitudinal impedance is
computed using the following equations, where TIP and RING
voltages are referenced to ground. LZT, LZR, VT, VR, AR and
A T are defined in Figure 2.
(TIP) LZT = VT /AT
(RING) LZR = VR /AR
where: EL = 1VRMS (0Hz to 100Hz)
5. Longitudinal Current Limit (On-Hook Active) - On-Hook
longitudinal current limit is determined by increasing the (60Hz)
amplitude of EL (Figure 3A) until the 2-wire longitudinal current
is greater than 28mARMS /Wire. Under this condition, SHD pin
remains low (no false detection) and the 2-wire to 4-wire
longitudinal balance is verified to be greater than 45dB
(LB 2-4 = 20log VTX/EL).
6. Longitudinal Current Limit (Off-Hook Active) - Off-Hook
longitudinal current limit is determined by increasing the (60Hz)
amplitude of EL (Figure 3B) until the 2-wire longitudinal current
is greater than 28mARMS /Wire. Under this condition, SHD pin
remains high (no false detection) and the 2-wire to 4-wire
longitudinal balance is verified to be greater than 45dB
(LB 2-4 = 20log VTX/EL).
7. Longitudinal to Metallic Balance - The longitudinal to
metallic balance is computed using the following equation:
BLME = 20 log (EL /VTR), where: EL and VTR are defined in
Figure 4.
8. Metallic to Longitudinal FCC Part 68, Para 68.310 - The
metallic to longitudinal balance is defined in this spec.
9. Longitudinal to Four-Wire Balance - The longitudinal to 4-wire
balance is computed using the following equation:
BLFE = 20 log (EL /VTX), EL and VTX are defined in Figure 4.
10. Metallic to Longitudinal Balance - The metallic to longitudinal
balance is computed using the following equation:
BMLE = 20 log (ETR /VL), ERX = 0
where: ETR, VL and ERX are defined in Figure 5.
11. Four-Wire to Longitudinal Balance - The 4-wire to longitudinal
balance is computed using the following equation:
BFLE = 20 log (E RX / VL), ETR = source is removed.
where: ERX, VL and ETR are defined in Figure 5.
12. Two-Wire Return Loss - The 2-wire return loss is computed
using the following equation:
r = -20 log (2VM /VS) where: ZD = The desired impedance; e.g.,
the characteristic impedance of the line, nominally 600Ω.
(Reference Figure 6).
13. Overload Level (4-Wire Port Off-Hook) - The overload level
is specified at the 4-wire transmit port (VTX) with the signal
source (E G) at the 2-wire port, ZL = 20kΩ, RL = 600Ω
(Reference Figure 7). Increase the amplitude of EG until 1%
THD is measured at VTX. Note the PTG pin is open, and the
gain from the 2-wire port to the 4-wire port is equal to 1.
14. Overload Level (4-Wire Port On-Hook) - The overload level
is specified at the 4-wire transmit port (VTX) with the signal
source (E G) at the 2-wire port, ZL = 20kΩ, RL = ∞ (Reference
Figure 7). Increase the amplitude of EG until 1% THD is
measured at V TX. Note the PTG pin is open, and the gain from
the 2-wire port to the 4-wire port is equal to 1.
15. Output Offset Voltage - The output offset voltage is specified
with the following conditions: EG = 0, RL = 600Ω, ZL = ∞ and is
measured at V TX. EG, RL, VTX and ZL are defined in Figure 7.
16. Two-Wire to Four-Wire Frequency Response - The 2-wire to
4-wire frequency response is measured with respect to
EG = 0dBm at 1.0kHz, ERX = 0V (VRX input floating), RL = 600Ω.
The frequency response is computed using the following equation:
F2-4 = 20 log (VTX/VTR), vary frequency from 300Hz to 3.4kHz
and compare to 1kHz reading.
VTX, VTR, RL and EG are defined in Figure 8.
17. Four-Wire to Two-Wire Frequency Response - The 4-wire to 2wire frequency response is measured with respect to ERX = 0dBm
at 1.0kHz, EG source removed from circuit, RL = 600Ω. The
frequency response is computed using the following equation:
F4-2 = 20 log (VTR /ERX), vary frequency from 300Hz to 3.4kHz
and compare to 1kHz reading.
VTR, RL and ERX are defined in Figure 8.
18. Four-Wire to Four-Wire Frequency Response - The 4-wire
to 4-wire frequency response is measured with respect to
ERX = 0dBm at 1.0kHz, EG source removed from circuit,
RL = 600Ω. The frequency response is computed using the
following equation:
F4-4 = 20 log (VTX /ERX), vary frequency from 300Hz to 3.4kHz
and compare to 1kHz reading.
VTX , RL and E RX are defined in Figure 8.
19. Two-Wire to Four-Wire Insertion Loss (PTG = Open) - The
2-wire to 4-wire insertion loss is measured with respect to
EG = 0dBm at 1.0kHz input signal, ERX = 0 (VRX input floating),
RL = 600Ω and is computed using the following equation:
L2-4 = 20 log (VTX /VTR)
where: VTX, VTR, RL and EG are defined in Figure 8. (Note:
The fuse resistors, RF , impact the insertion loss. The specified
insertion loss is for RF1 = RF2 = 0).
20. Two-Wire to Four-Wire Insertion Loss (PTG = AGND) - The
2-wire to 4-wire insertion loss is measured with respect to EG =
0dBm at 1.0kHz input signal, E RX = 0 (VRX input floating), RL =
600Ω and is computed using the following equation:
L2-4 = 20 log (VTX /VTR)
where: VTX, VTR, RL and EG are defined in Figure 8. (Note:
The fuse resistors, RF , impact the insertion loss. The specified
insertion loss is for RF1 = RF2 = 0).
21. Four-Wire to Two-Wire Insertion Loss - The 4-wire to 2-wire
insertion loss is measured based upon ERX = 0dBm, 1.0kHz
input signal, EG source removed from circuit, RL = 600Ω and is
computed using the following equation:
L4-2 = 20 log (VTR /ERX )
where: VTR, RL and ERX are defined in Figure 8.
22. Two-Wire to Four-Wire Gain Tracking - The 2-wire to 4-wire
gain tracking is referenced to measurements taken for
EG = -10dBm, 1.0kHz signal, ERX = 0 (VRX output floating),
RL = 600Ω and is computed using the following equation.
G2-4 = 20 • log (V TX/VTR) vary amplitude -40dBm to +3dBm, or
-55dBm to -40dBm and compare to -10dBm reading.
VTX, RL and VTR are defined in Figure 8.
12
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
23. Four-Wire to Two-Wire Gain Tracking - The 4-wire to 2-wire
gain tracking is referenced to measurements taken for
ERX = -10dBm, 1.0kHz signal, EG source removed from circuit,
RL = 600Ω and is computed using the following equation:
G4-2 = 20 • log (VTR /ERX) vary amplitude -40dBm to +3dBm, or
-55dBm to -40dBm and compare to -10dBm reading.
VTR, RL and ERX are defined in Figure 8. The level is specified at
the 4-wire receive port and referenced to a 600Ω impedance level.
24. Two-Wire Idle Channel Noise - The 2-wire idle channel noise
at VTR is specified with the 2-wire port terminated in 600Ω (RL)
and with the 4-wire receive port (VTX) floating (Reference
Figure 9).
25. Four-Wire Idle Channel Noise - The 4-wire idle channel noise
at VTX is specified with the 2-wire port terminated in 600Ω (RL).
The noise specification is with respect to a 600Ω impedance
level at VTX. The 4-wire receive port (VTX) floating (Reference
Figure 9).
26. Harmonic Distortion (2-Wire to 4-Wire) - The harmonic
distortion is measured within the voice band with the following
conditions. E G = 0dBm at 1kHz, RL = 600Ω. Measurement
taken at VTX. (Reference Figure 7).
27. Harmonic Distortion (4-Wire to 2-Wire) - The harmonic
distortion is measured within the voice band with the following
conditions. E RX = 0dBm0. Vary frequency between 300Hz and
3.4kHz, RL = 600Ω. Measurement taken at V TR. (Reference
Figure 8).
28. Constant Loop Current - The constant loop current is
calculated using the following equation:
IL = 1000/RLIM = VTR/600 (Reference Figure 10).
29. Ground Key Detector - (TRIGGER) Ground the Ring pin
through a 2.5kΩ resistor and verify that GKD goes low.
(RESET) Disconnect the Ring pin and verify that GKD goes
high.
(Hysteresis) Compare difference between trigger and reset.
30. Electrical Test - Not tested in production at -40oC.
Circuit Operation and Design Information
The tip and ring voltages for various loop resistances are
shown in Figure 13. The tip voltage remains relatively
constant as the ring voltage moves to limit the loop current
for short loops.
.
35
30
LOOP CURRENT (mA)
The UniSLIC14 family of SLICs are voltage feed current
sense Subscriber Line Interface Circuits (SLIC). For short
loop applications, the voltage between the tip and ring
terminals varies to maintain a constant loop current. For long
loop applications, the voltage between the tip and ring
terminals are relatively constant and the loop current varies
in proportion to the load.
CONSTANT TIP TO RING
VOLTAGE REGION
25
20
CONSTANT
LOOP CURRENT
REGION
15
VBH = -48V
RD = 41.2kΩ
ROH = 38.3kΩ
RDC_RAC = 19.6kΩ
RILim = 33.2kΩ
10
5
The loop current for various loop resistances are shown in
Figure 14. For short loops, the loop current is limited to the
programmed current limit, set by RILIM. For long loop
applications, the loop current varies in accordance with
Ohms law for the given tip to ring voltage and the loop
resistance.
TIP AND RING VOLTAGES (V)
0
-2.5V
TIP
-5
-10
CONSTANT TIP TO RING
VOLTAGE REGION
-15
VBH = -48V
RD = 41.2kΩ
ROH = 38.3kΩ
RDC_RAC = 19.6kΩ
RILim = 33.2kΩ
-25
-30
-35
-40
-45
CONSTANT
LOOP CURRENT
REGION
-44.5V
-50
200
600
1000 1400 1800 2000
4K
6K
8K
10K
LOOP RESISTANCE (Ω)
FIGURE 13. TIP AND RING VOLTAGES vs LOOP RESISTANCE
13
200
600
1K
1.4K 1.8K
2.2K 2.6K 3.0K 3.4K 3.8K
LOOP RESISTANCE (Ω)
FIGURE 14. LOOP CURRENT vs LOOP RESISTANCE
The following discussion separates the SLIC’s operation into
its DC and AC paths, then follows up with additional circuit
and design information.
DC Feed Curve
RING
-20
0
The DC feed curve for the UniSLIC14 family is user
programmable. The user defines the on hook and off hook
overhead voltages (including the overhead voltage for off
hook pulse metering if applicable), the maximum and
minimum loop current limits, the switch hook detect
threshold and the battery voltage. From these requirements,
the DC feed curve is customized for optimum operation in
any given application. An Excel spread sheet to calculate the
external components can be downloaded off our web site
www.intersil.com/telecom/unislic14.xls.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
VBH
TIP TO RING ABSOLUTE VOLTAGE (V)
2.5V †
SLIC SELF PROGRAMMING
VOH(on) AT LOAD
CONSTANT
CURRENT
REGION
VOH(off) AT LOAD
RSAT
60kΩ SLOPE
R
a
(m
OP
LO
x)
IOH
ISH-
ISHD
ILOOP(min)
ILOOP(max)
LOOP CURRENT (mA)
† Internal overhead voltage automatically generated by the SLIC.
FIGURE 15. UniSLIC14 DC FEED CURVE
RP = Protection Resistors (Typically 30Ω)
The on hook overhead
voltage at the load (VOH(on)
at Load) is independent of the
2.5V
VBH battery voltage. Once
VOH(on)
ON HOOK
OVERHEAD
set, the on hook voltage
remains constant as the VBH
battery voltage changes. The
ISH- I SHD
on hook voltage also remains
LOOP CURRENT
constant over temperature
ISH- = I SHD(0.6)
and line leakages up to 0.6
times the Switch Hook Detect threshold (ISHD ). The
maximum loop current for a constant on hook overhead
voltage is defined as ISH-.
RS = Internal Sense Resistors (40Ω)
TIP TO RING VOLTAGE
On Hook Overhead Voltage
DC FEED CURVE
VBH
The on hook overhead voltage, required for a given signal
level at the load, must take into account the AC voltage drop
across the 2 external protection resistors (RP) and the 2
internal sense resistors (R S) as shown in Figure 16. The AC
on hook overload voltage is calculated using Equation 1.
ZL = AC load impedance for (600Ω)
1.5V = Additional on hook overhead voltage requirement
To account for any process and temperature variations in the
performance of the SLIC, 1.5V is added to the overhead
voltage requirement for the on hook case in Equation 1 and
2.0V for the off hook case in Equation 3. Note the 2.5V
overhead is automatically generated in the SLIC and is not
part of the external overhead programming.
2RP

L

TIP AND RING
AMPLIFIERS
INTERNAL SENSE
RESISTORS
ZL
(EQ. 1
UniSLIC14
2R S
VZL
(LOAD)
2R P + 2R S

- + 1.5V
OH (on ) at Load = V sp ( on ) ×  1 + ----------------------------Z
REQUIRED
OVERHEAD VOLTAGE
VOH (ON, OFF)
EXTERNAL PROTECTION
RESISTOR
 2R P + 2R S
V OH ( ON, OFF ) =  ------------------------------  VZL
ZL


Where:
VZL is the required on hook or offhook
transmission delivered to the load.
FIGURE 16. OVERHEAD VOLTAGE OF THE TIP AND RING
AMPLIFIERS
where
VOH(on) at Load = On hook overhead voltage at load
Vsp(on) = Required on hook transmission for speech
14
The off hook overhead
voltage VOH(off) at Load is
VBH
also
independent of the VBH
2.5V
VSAT
battery voltage and remains
OFF HOOK
OVER HEAD constant over temperature.
VOH(off)
The required off hook
overhead voltage is the sum
ILOOP(min)
of the AC and DC voltage
LOOP CURRENT
drops across the internal
sense resistors (RS), the
protection resistors (RP), the required (peak) off hook
voltage for speech (Vsp(off)) and the required (peak) off hook
voltage for the pulse metering (Vpm(off)), if applicable.
TIP TO RING VOLTAGE
DC FEED CURVE
The off hook overhead voltage is defined in Equation 2 and
calculated using Equation 3.
V OH ( off ) at Load = VOH ( Rsense ) + V sp ( of f ) + Vpm ( of f )
(EQ. 2)
where:
VOH(off) at Load = Off hook overhead voltage at load
VOH(Rsense) = Required overhead for the DC voltage drop
across sense resistors (2RS x Iloop(max))
Vsp(off) = Required (peak) off hook AC voltage for speech
Vpm(off) = Required (peak) off hook AC voltage for pulse
metering
2R P + 2R S

V OH(off) at Load = 80 × ILOOP ( max ) + V sp ( of f ) ×  1 + ------------------------------ 
ZL


2R P + 2R S

+ V pm ( off ) ×  1 + ------------------------------ + 2.0V
Z pm


(EQ. 3)
where:
80 = 2Rs + 2R INT (reference Figure 17)
Zpm = Pulse metering load impedance (typically 200Ω).
2.0V = Additional off hook overhead voltage requirement
RSAT Resistance Calculation
The RSAT resistance of the DC feed curve is used to
determine the value of the RDC_RAC resistor (Equation 6).
The value of this resistor has an effect on both the on hook
and off hook overheads. In most applications the off hook
condition will dominate the overhead requirements.
Therefore, we’ll start by calculating the RSAT value for the
off hook conditions and then verify that the on hook
conditions are also satisfied.
DC FEED CURVE
VBH
2.5V
VSAT
RSAT
VOH(off)
When considering the Off
hook condition, RSAT is equal
to VOH(off) at Load divided by
Iloop(min) (Equation 4).
For the given system
requirements (recommended
application circuit in back of
ILOOP(min)
data sheet): Iloop (min) =
LOOP CURRENT
20mA, Iloop (max) = 30mA,
RSAT
VOH(off) AT LOAD
Vsp(off) = 3.2VPEAK,
Vspm(off) = 0VPEAK,
ILOOP(min)
VOH(off) at Load = 8.34V the
value of RSAT(off) is equal to 417Ω as calculated in Equation 4.
V OH(off) at Load
8.34V
R SAT(off) = ---------------------------------------- = ---------------- = 417Ω
20m A
ILOOP(min)
(EQ. 4)
Before using this RSAT value, to calculate the RDC_RAC
resistor, we need to verify that the on hook requirements will
also be met.
TIP TO RING VOLTAGE
Off Hook Overhead Voltage
TIP TO RING VOLTAGE
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
DC FEED CURVE
VBH
VSAT
2.5V
VOH(on)
RSAT
ISH-(min)
LOOP CURRENT
VOH(on) AT LOAD
RSAT
ISH-(min)
2.85V
R SAT ( on ) = ------------------ = 395 Ω
7.2mA
The on hook overhead voltage
calculated with the off hook
RSAT (RSAT(off)), is given in
Equation 5 and equals 3.0V.
The on hook overhead
calculated with Equation 1
equals 2.85V for the given
system requirements
(recommended application
circuit in back of data sheet):
Switch Hook Detect threshold
= 12mA, ISH- = (0.6)12mA =
7.2mA, Vsp(on) = 0.775VRMS
Thus, the on hook overhead
requirements of 2.85V will be
met if we use the R SAT(off) value.
V OH ( on) = ( ISH- ) ( R SAT ( off) )
(EQ. 5)
V OH ( on) = 7.2mA × 417 Ω
V OH ( on) = 3.0V
If the on hook overhead requirement is not met, then we
need to use the RSAT(on) value to determine the RDC_RAC
resistor value. The external saturation guard resistor
RDC_RAC is equal to 50 times RSAT.
In the example above RSAT would equal 417Ω and
RDC_RAC would then equal to 20.85kΩ (closest standard
value is 21kΩ).
RDC_RAC = 50 x R SAT
(EQ. 6)
The Switch Hook Detect threshold current is set by resistor
RD and is calculated using Equation 7. For the above
15
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
example RD is calculated to be 41.6kΩ (500/12mA). The
next closest standard value is 41.2kΩ.
SHD threshold, 2) minimum loop current requirement or 3)
the on and off hook signal levels.
500
R D = -----------ISHD
VBH – [ V SAT + 2V + V OH ( off) ]
R LOOP(max) = ------------------------------------------------------------------------------- -2R P
ILOOP(min)
(EQ. 7)
(EQ. 12)
The true value of ISH-, for the selected value of RD is given
by Equation 8:
SLIC in the Active Mode
500
ISH- = ---------- (0.6)
RD
Figure 17 shows a simplified AC transmission model. Circuit
analysis yields the following design equations:
(EQ. 8)
TIP TO RING VOLTAGE
For the example above, ISH- equals 7.28mA (500 x 0.6/
41.2K). Verify that the value of ISH- is above the suspected
line leakage of the application. The UniSLIC family will
provide a constant on hook voltage level for leakage
currents up to this value of line leakage.
DC FEED CURVE
VBH
VSAT
2.5V
OFF HOOK
OVER HEAD
VOH(off)
The ROH resistor, which
is used to set the offhook
overhead voltage, is
calculated using
Equations 9 and 10.
IOH
IOH is defined as the
difference between the
ILOOP(min)
ISHILOOP(min) and ISH-.
LOOP CURRENT
Substituting Equation 8
for ISH- into Equation 9 and solving for ROH defines R OH in
terms of ILOOP(min) and RD.
500
500
R OH = ---------- = -------------------------------------------ILOOP(min) - ISHIOH
(EQ. 9)
1
V A = IM × 2R S × ---------- × 200 ( ZTR – 2RP ) × 5
80k
(EQ. 13)
IM
V A = ------- ( ZTR – 2R P )
2
(EQ. 14)
Node Equation
VA
VRX
------------- - ------------- = I X
500k 50 0k
Substitute Equation 14 into Equation 15
I M ( Z T R – 2R P )
VRX
I X = ------------- - ----------------------------------------500k
1000k
R D 500
R OH = ------------------------------------------------------------ 500(.6)
RD I
(EQ. 10)
LOOP(min)
I X 500k - VTX ′ + IX 500k = 0
(EQ. 17)
Substitute Equation 16 into Equation 17
V TX ′ = 2V RX – I M ( Z TR – 2R P )
V TR -I M 2R P + V TX ′ = 0
(EQ. 18)
(EQ. 19)
Substitute Equation 18 into Equation 19
V TR = IM Z T R – 2V RX
(EQ. 20)
Substituting -V TR/ZL into Equation 20 for IM and rearranging
to solve for V TR results in Equation 21
The current limit is set by a single resistor and is calculated
using Equation 11.
ZTR

V TR  1 + ----------- = – 2 V RX
ZL 

1000
R LIM = ----------------------------ILOOP(max)
where:
(EQ. 11)
(EQ. 16)
Loop Equation
Loop Equation
Equation 10 can be used to determine the actual ISH- value
resulting from the R D resistor selected. The value of RD
should be the next standard value that is lower than that
calculated. This will insure meeting the ILOOP(min)
requirement. ROH for the above example equals 39.1kΩ.
(EQ. 15)
(EQ. 21)
VRX = The input voltage at the VRX pin.
TIP TO RING VOLTAGE
The maximum loop
resistance is calculated
using Equation 12. The
2.5V
VSAT
resistance of the
VOH(off)
protection resistors
AX)
(2RP) is subtracted out
(M
P
R LOO
to obtain the maximum
ILOOP(min)
loop length to meet the
LOOP CURRENT
required off hook
overhead voltage. If RLOOP(MAX) meets the loop length
requirements you are done. If the loop length needs to be
longer, then consider adjusting one of the following: 1) the
DC FEED CURVE
VBH
16
VA = An internal node voltage that is a function of the loop
current detector and the impedance matching networks.
IX = Internal current in the SLIC that is the difference
between the input receive current and the feedback current.
IM = The AC metallic current.
RP = A protection resistor (typical 30Ω).
ZT = An external resistor/network for matching the line
impedance.
VTX´= The tip to ring voltage at the output pins of the SLIC.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
VTR = The tip to ring voltage including the voltage across the
protection resistors.
From Equation 21 and the relationship ZT = 200(ZTR-2RP).
V TR
ZL
ZL
G 4-2 = ----------- = -2 ------------------------- = – 2 ---------------------------------------------V RX
ZL + Z TR
ZT
ZL +  ---------- + 2RP
200
ZL = The line impedance.
ZTR = The input impedance of the SLIC including the
protection resistors.
(EQ. 22)
Notice that the phase of the 4-wire to 2-wire signal is 180o
out of phase with the input signal.
(AC) 4-Wire to 2-Wire Gain
The 4-wire to 2-wire gain is equal to V TR/VRX.
IX
+
-
TIP
IM
+
500K
IM
-
RS
20Ω
RP
ZTR
RINT
A=1
+
+
20Ω
VTX
500K
+
VTX
-
ZL
+
VTR
-
PTG
500K
IX
- IM +
RING
IX
UniSLIC14
VTX´
+
+
EG
-
IX
-
+
RS
RINT
20Ω
RP
+
IX
20Ω
VRX
+
-
500K
500K
500K
+
VRX
-
1/80K
5
VA = IM(ZTR-2RP)
2
ZT
= 200 (ZTR - 2R P)
FIGURE 17. SIMPLIFIED AC TRANSMISSION CIRCUIT
(AC) 2-Wire to 4-Wire Gain
The 2-wire to 4-wire gain is equal to V TX/ EG with V RX = 0
Loop Equation
– EG + ZL IM + 2R P IM – VTX ′ = 0
(EQ. 23)
From Equation 18 with VRX = 0
V TX ′ = – I M ( Z TR – 2R P )
Rearranging Equation 27 in terms of EG, and substituting
into Equation 26 results in an equation for 2-wire to 4-wire
gain that’s a function of the synthesized input impedance of
the SLIC (ZTR) and the protection resistors (RP).
VTX Z TR - 2R P
G 2-4 = ----------- = ----------------------------V TR
ZTR
(EQ. 28)
(EQ. 24)
Substituting Equation 24 into Equation 23 and simplifying.
Notice that the phase of the 2-wire to 4-wire signal is in
phase with the input signal.
EG = I M ( Z L + Z TR )
(AC) 4-Wire to 4-Wire Gain
(EQ. 25)
The 4-wire to 4-wire gain is equal to V TX/VRX, E G = 0.
By design, VTX = -VTX´, therefore
V TX I M ( Z TR – 2R P )
( ZTR – 2R P )
G 2-4 = ---------- = ---------------------------------------- = --------------------------------EG
( Z L + ZTR )
I M ( Z L + ZTR )
(EQ. 26)
V TX ′ = – V TX = – 2 V RX + I M ( Z TR – 2R P )
A more useful form of the equation is rewritten in terms of
VTX /V TR. A voltage divider equation is written to convert
from EG to VTR as shown in Equation 27.
(EQ. 27)
Z TR 

V TR =  ------------------------ EG
 Z TR + Z L
17
From Equation 18.
(EQ. 29)
Substituting -V TR / ZL into Equation 29 for IM results in
Equation 30.
VTR ( Z TR – 2R P )
V TX = – 2 V RX – --------------------------------------------ZL
(EQ. 30)
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Substituting Equation 21 for VTR in Equation 30 and
simplifying results in Equation 31.
VT X
 Z L + 2R P
G 4 – 4 = ----------- = –2  ------------------------
VRX
 Z L + Z TR 
constant on hook overhead voltage (ISH- = ISHD (0.6)) and
the value of RSAT(off) is calculated in Equation 4.
(EQ. 31)
On hook Ring Voltage
R SAT ( off)
V R ING ( onhook ) = VBH + 1.5V + ( ISH )  --------------------------


2
(EQ. 36)
(AC) 2-Wire Impedance
The AC 2-wire impedance (ZTR) is the impedance looking
into the SLIC, including the fuse resistors. The formula to
calculate the proper ZT for matching the 2-wire impedance is
shown in Equation 32.
The calculation of the ring voltage with respect to ground in
the off hook condition is dependent upon whether the SLIC
is in current limit or not.
Equation 32 can now be used to match the SLIC’s
impedance to any known line impedance (ZTR).
The off hook ring to ground voltage (in current limit) is
calculated using Equation 37. ILIM is the programmed loop
current limit and RL is the load resistance across tip and
ring. The minus 0.2V is a correction factor for the 60kΩ slope
in Figure 15.
EXAMPLE:
Off hook Ring Voltage in Current Limit
Calculate ZT to make ZTR = 600Ω in series with 2.16µF.
RP = 30Ω.
V RING ( CL ) = VTIP ( of fhook ) – I LOOP( MAX ) R L – 0.2V
(EQ. 32)
Z T = 200 • ( ZTR – 2 RP )
1
Z T = 200  600 + ----------------------------------- – ( 2 ) ( 30 )


–6
jω 2.16X10
(EQ. 33)
ZT = 108kΩ in series with 0.0108µF.
Note: Some impedance models, with a series capacitor, will
cause the op-amp feedback to behave as an open circuit
DC. A resistor with a value of about 10 times the reactance
of the ZT capacitor (2.16µF/ 200 = 10.8nF) at the low
frequency of interest (200Hz for example) can be placed in
parallel with the capacitor in order to solve the problem
(736kΩ for a 10.8nF capacitor).
Calculating Tip and Ring Voltages
The on hook tip to ground voltage is calculated using
Equation 34. The minus 1.0 volt results from the SLIC self
programming. ISH- is the maximum loop current for a
constant on hook overhead voltage (ISH- = ISHD (0.6)) and
the value of RSAT(off) is calculated in Equation 4.
On hook Tip Voltage
R SATof f
VTIP ( onhook ) = – 1.0V + – ( ISH- )  ----------------------


2
(EQ. 34)
The off hook tip to ground voltage is calculated using
Equation 35. ILOOP(min) is the minimum loop current
allowed by the design and the value of RSAT(off) is
calculated in Equation 4.
Off hook Tip Voltage
R SAT ( off )
VTI P ( of fhook ) = – 1V – ( I LOOP ( min ) ) -------------------------2
– I LOOP( MAX ) × R P
(EQ. 35)
The on hook ring to ground voltage is calculated using
Equation 36. The 1.5 volt results from the SLIC self
programming. ISH- is the maximum loop current for a
18
(EQ. 37)
The off hook ring to ground voltage (not in current limit) is
calculated using Equation 38. The 1.5V results from the
SLIC self programming. ILOOP(min) is the minimum loop
current allowed by the design and the value of RSAT(off) is
calculated in Equation 4.
Off hook Ring Voltage not in Current Limit
R SAT ( of f )
V RING ( NC L ) = VBH + 1.5V + ( ILOOP ( min ) )  --------------------------


2
(EQ. 38)
– I LOOP ( MI N ) × R P
Layout Considerations
Systems with Dual Supplies (VBH and VBL)
If the VBL supply is not derived from the VBH supply, it is
recommended that an additional diode be placed in series
with the VBH supply. The orientation of this diode is anode
on pin 8 of the device and cathode to the external supply.
This external diode will inhibit large currents and potential
damage to the SLIC, in the event the VBH supply is shorted
to GND. If VBL is derived from VBH then this diode is not
required. Suggested (not required) supply sequence VBH VBL- VCC .
Floating the PTG Pin
The PTG pin is a high impedance pin (500kΩ) that is used to
program the 2-wire to 4-wire gain to either 0dB or -6dB.
If 0dB is required, it is necessary to float the PTG pin. The
PC board interconnect should be as short as possible to
minimize stray capacitance on this pin. Stray capacitance on
this pin forms a low pass filter and will cause the 2-wire to
4-wire gain to roll off at the higher frequencies.
If a 2-wire to 4-wire gain of -6dB is required, the PTG pin
should be grounded as close to the device as possible.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
SPM Pin
For optimum performance, the PC board interconnect the
SPM pin should be as short as possible. If pulses metering is
not being used, then this pin should be grounded as close to
the device pin as possible.
RLIM Pin
The current limiting resistor RLIM needs to be as close to the
RLIM pin as possible.
Layout of the 2-Wire Impedance Matching
Resistor ZT
Proper connection to the ZT pin is to have the external ZT
network as close to the device pin as possible.
The ZT pin is a high impedance pin that is used to set the
proper feedback for matching the impedance of the 2-wire
side. This will eliminate circuit board capacitance on this pin
to maintain the 2-wire return loss across frequency.
TABLE 1. DETECTOR STATES
OUTPUT
STATE
C3
C2
C1
SLIC OPERATING STATE
ACTIVE DETECTOR
0
0
0
0
Open Circuit State
4 wire loopback test capability
1
0
0
1
Ringing State
(Previous State cannot be Reverse
Active State)
Ring Trip Detector
2
0
1
0
Forward Active State
Loop Current Detector
SHD
HIGH
GKD_ LVM
HIGH
HIGH
Ground Key Detector
3
0
1
1
On Hook Loopback Detector
Test Active State
Requires previous state to be in the Ground Key Detector
Forward Active state to determine the
On hook or Off hook status of the line. Off Hook Loop Current Detector
LOW
HIGH
LOW
Line Voltage Detector
4
1
0
5
1
0
6
1
1
0
Tip Open - Ground Start State
Ground Key Detector
1
Reserved
Reserved
0
Reverse Active State
Loop Current Detector
N/A
N/A
Ground Key Detector
7
8
1
X
1
X
1
X
On Hook Loop Current Detector
Test Reversal Active State
Requires previous state to be in the
Reverse Active state to determine the Off Hook Loop Current Detector
On hook or Off hook status of the line. Line Voltage Detector
LOW
Thermal Shutdown
LOW
Digital Logic Inputs
Table 1 is the logic truth table for the 3V to 5V logic input
pins. A combination of the control pins C3, C2 and C1 select
1 of the possible 6 operating states. The 8th state listed is
Thermal Shutdown. Thermal Shutdown protection is invoked
if a fault condition on the tip or ring causes the junction
temperature of the die to exceed 175oC. A description of
each operating state and the control logic follows:
Open Circuit State (C3 = 0, C2 = 0, C1 = 0)
In this state, the tip and ring outputs are in a high impedance
condition (>1MΩ). No supervisory functions are available
and SHD and GKD outputs are at a TTL high level.
4-wire loopback testing can be performed in this state. With
the PTG pin floating, the signal on the VTX output is 180o out
of phase and approximately 2 times the VRX input signal. If
19
HIGH
LOW
the PTG pin is grounded, then the amplitude will be
approximately the same as its input and 180o out of phase.
Ringing State (C3 = 0, C2 = 0, C1 = 1)
In this state, the output of the ring relay driver pin (RRLY)
goes low (energizing the ring relay to connect the ringing
signal to the phone) if either of the following two conditions
are satisfied:
(1) The RSYNC_REV pin is grounded through a resistor This connection enables the RRLY pin to go low the instant
the ringing state is invoked, without any regard for the
ringing voltage (90VRMS -120VRMS) across the relay
contacts. The resistor (34.8kΩ to 70kΩ) is required to limit
the current into the RSYNC_REV pin.
(2) A ring sync pulse is applied to the RSYNC_REV pin This connection enables the RRLY pin to go low at the
command of a ring sync pulse. A ring sync pulse should go
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
low at zero voltage crossing of the ring signal. This pulse
should have a rise and fall time <400µs and a minimum
pulse width of 2ms.
Zero ring current detection is performed automatically inside
the SLIC. This feature de-energizes the ring relay slightly
before zero current occurs to partially compensate for the
delay in the opening of the relay.
The SHD output will go low when the subscriber goes off
hook. Once SHD is activated, an internal latch will prohibit
the re-ringing of the line until the ringing code is removed
and then reapplied.
The state prior to ringing the phone, can not be the Reverse
Active State. In the reverse active state the polarity of the
voltage on the CRT_REV_LVM capacitor, will make it
appear as if the subscriber is off hook. This subsequently will
activate an internal latch prohibiting the ringing of the line.
The GKD_LVM output is disabled (TTL high level) during the
ringing state. Reference the Section titled “Ringing the
Phone” for more information.
Forward Active State (C3 = 0, C2 = 1, C1 = 0)
In this state, the SLIC is fully functional. The tip voltage is more
positive than the ring voltage. The tip and ring output voltages
are an unbalanced DC feed, reference Figure 13. Both SHD
and GKD supervisory functions are active. Reference the
section titled “DC Feed Curve” for more information.
Test Active State (C3 = 0, C2 = 1, C1 = 1)
Proper operation of the Test Active State requires the
previous state be the Forward Active state to determine the
on hook or off hook status of the line. In this state, the SLIC
can perform two different tests.
If the subscriber is on hook when the state is entered, a
loopback test is performed by switching an internal 600Ω
resistor between tip and ring. The current flows through the
internal 600Ω is unidirectional via blocking diodes. (Cannot be
used in reverse.) When the loopback current flows, the SHD
output will go low and remain there until the state is exited. This
is intended to be a short test since the ability to detect
subscriber off hook is lost during loopback testing. Reference
the section titled “Loopback Tests” for more information.
If the subscriber is off hook when the state is entered, a Line
Voltage Measurement test is performed. The output of the
GKD_LVM pin is a pulse train. The pulse width of the active low
portion of the signal is proportional to the voltage across the tip
and ring pins. If the loop length is such that the SLIC is
operating in constant current, the tip to ring voltage can be used
to determine the length of the line under test. The longer the
line, the larger the tip to ring voltage and the wider the pulse.
This relationship can determine the length of the line for setting
gains in the system. Reference the section titled “Operation of
Line Voltage Measurement” for more information.
20
Tip Open State (C3 = 1, C2 = 0, C1 = 0)
In this state, the tip output is in a high impedance state
(>250kΩ) and the ring output is capable of full operation, i.e.
has full longitudinal current capability. The Tip Open/Ground
Start state is used to interface to a PBX incoming 2-wire
trunk line. When a ground is applied through a resistor to the
ring lead, this current is detected and presented as a TTL
logic low on the SHD and GKD_LVM output pins.
Reserved (C3 = 1, C2 = 0, C1 = 1)
This state is undefined and reserved for future use.
Reverse Active State (C3 = 1, C2 = 1, C1 = 0)
In this state, the SLIC is fully functional. The ring voltage is
more positive than the tip voltage. The tip and ring output
voltages are an unbalanced DC feed, reference Figure 13.
The polarity reversal time is determined by the RC time
constant of the RSYNC_REV resistor and the
CRT_REV_LVM capacitor. Capacitor CRT_REV_LVM
performs three different functions: Ring trip filtering, polarity
reversal time and line voltage measurement. It is
recommended that programming of the reversal time be
accomplished by changing the value of RSYNC_REV resistor
(see Figure 18). The value of RSYNC_REV resistor is limited
between 34.8K (10ms) and 73.2k (21ms). Equation 39 gives
the formula for programming the reversal time.
RSYNC – REV = 3.47kΩ × ReversalTim e ( ms )
(EQ. 39)
Both SHD and GKD supervisory functions are active.
Reference the section titled “Polarity Reversal” for more
information.
Test Reversal Active State (C3 = 1, C2 = 1, C1 = 1)
Proper operation of the Test Reversal Active State requires
the previous state be the Reverse Active state to determine
the on hook or off hook status of the line.
If the subscriber is on hook when the state is entered, the
SLIC’s tip and ring voltages are the same as the Reverse
Active state. The SHD output will go low when the subscriber
goes off hook and the GKD_LVM output is disabled (TTL
level high). (Note: operation is the same as the Reverse
Active state with the GKD_LVM output disabled.)
If the subscriber is off hook when the state is entered, a
Line Voltage Measurement test is performed.
The output of the GKD_LVM pin is a pulse train. The pulse width
of the active low portion of the signal is proportional to the voltage
across the tip and ring pins. If the loop length is such that the
SLIC is operating in constant current mode, the tip to ring voltage
can be used to determine the length of the line under test. The
longer the line, the larger the tip to ring voltage and the wider the
pulse. This relationship can determine the length of the line for
setting gains in the system. Reference the section titled
“Operation of Line Voltage Measurement” for more information.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Thermal Shutdown
The UniSLIC14’s thermal shutdown protection is invoked if a
fault condition causes the junction temperature of the die to
exceed about 175oC. Once the thermal limit is exceeded,
both detector outputs go low (SHD and GKD_LVM) and one
of two things can happen.
For marginal faults where loop current is flowing during the
time of the over-temperature condition, foldback loop current
limiting reduces the loop current by reducing the tip to ring
voltage. An equilibrium condition will exist that maintains the
junction temperature at about 175oC until the fault condition
is removed.
For short circuit faults (tip or ring to ground, or to a supply,
etc.) that result in an over-temperature condition, the
foldback current limiting will try to maintain an equilibrium at
about 175oC. If the junction temperature keeps rising, the
device will thermally shutdown and disconnect tip and ring
until the junction temperature falls to approximately 150oC.
Supervisory Functions
Switch Hook Detect Threshold
The Switch Hook Detect Threshold is programmed with a
single external resistor (RD). The output of the SHD pin goes
low when an off hook condition is detected.
Ground Key Detect Threshold
The Ground Key Detect Threshold is set internally and is not
user programmable.
Ringing the Phone
The UniSLIC14 family handles all the popular ringing
formats with high or low side ring trip detection. High side
detection is possible because of the high common mode
range on the ring signal detect input pins (DT, DR). To
minimize power drain from the ring generator, when the
phone is not being rung, the sense resistors are typically
2MΩ. This reduces the current draw from the ring generator
to just a few microamps.
When the subscriber goes off hook during ringing, the
UniSLIC14 family automatically releases the ring relay and
DC feed is applied to the loop. The UniSLIC14 family has
very low power dissipation in the on hook active mode. This
enables the SLIC (during the ring cadence) to be powered
up in the active state, avoiding unnecessary powering up
and down of the SLIC. The control logic is designed to
facilitate easy implementation of the ring cadence, requiring
only one bit change to go from active to ringing and back
again.
DT, DR AND RRLY INPUTS
Ring trip detection will occur when the DR pin goes more
positive than DT by approximately 4V.
21
The ring relay driver pin, RRLY, has an internal clamp
between it’s output and ground. This eliminates the need to
place an external snubber diode across the ring relay.
Reducing Impulse Noise During Ringing
With an increase in digital data lines being installed next to
analog lines, the threat from impulse noise on analog lines is
increasing. Impulse noise can cause large blocks of high
speed data to be lost, defeating most error correcting
techniques. The UniSLIC14 family has the capability to
reduce impulse noise by closing the ring relay at zero
voltage and opening the ring relay at zero current.
CLOSING THE RING RELAY AT ZERO VOLTAGE
Closing the ring relay at zero voltage is accomplished by
providing a ring sync pulse to the RSYNC_REV pin. The ring
sync pulse is synchronized to go low at the zero voltage
crossing of the ring signal. The resistor R1 in Figure 18 limits
the current into the RSYNC_REV pin. If a particular polarity
reversal time is required, then make R1 equal to the
calculated value in Equation 39. If a specific polarity reversal
time is not desired, R1 equal to 50kΩ is suggested.
The RSYNC_REV pin is designed to allow the ring sync
pulse to be present at all times. There is no need to gate the
ring sync pulse on and off. The logic control for the
RSYNC_REV pin cannot be an open collector. It must be
high (push-pull logic output stage / pull up resistor to VCC),
low or being clocked by the ring sync pulse. When the
RSYNC_REV pin is high the ring relay pin is disabled. When
the RSYNC_REV pin is low the ring relay pin is activated the
instant the logic code for ringing is applied.
OPENING THE RING RELAY AT ZERO CURRENT
The ring relay is automatically opened at zero current by the
SLIC. The SLIC logic requires zero ringing current in the
loop and either a valid switch hook detect (SHD) or a change
in the operating mode (cadence of the ringing signal) to
release the ring relay.
UniSLIC14
RSYNC_REV
24
R1
50kΩ
INPUT FOR THE
RING SYNC PULSE
5V
0V
FIGURE 18. REDUCING IMPULSE NOISE USING THE
RSYNC_REV PIN AND SETTING THE POLARITY
REVERSAL TIME
If the subscriber goes off hook during ringing, the SHD
output will go low. An internal latch will sense SHD is low
and disable the ring relay at zero ringing current. This
prevents the ring signal from being reapplied to the line. To
ring the line again, the SLIC must toggle between logic
states. (Note: The previous state can not be the Reverse
Active State. In the reverse state, the voltage on the
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Figure 19 shows the sequence of events from ringing the
phone to ring trip. The ring relay turns on when both the
ringing code and ring sync pulse are present (A). SHD is
high at this point. When the subscriber goes off hook the
SHD pin goes low and stays low until the ringing control
code is removed (B). This prevents the SHD output from
pulsing after ring trip occurs. At the next zero current
crossing of the ring signal, ring trip occurs and the ring relay
releases the line to allow loop current to flow in the loop (C).
active state (forward or reverse) and the subscriber is
unaware the measurement is being taken.
TIP
RING
UniSLIC14
RING
GEN
FREQ
GKD_LVM
PULSE WIDTH
PROPORTIONAL TO
LOOP LENGTH
DR
DT
RING
GEN
PULSE
WIDTH
CRT_REV_LVM capacitor will activate an internal latch
prohibiting the ringing of the line.
LOOP LENGTH
RINGING VOLTAGE
FIGURE 20. OPERATION OF THE LINE VOLTAGE
MEASUREMENT CIRCUIT
RING SYNC
PULSE
(A)
Polarity Reversal
RINGING CODE
APPLIED
(B)
SHD OUTPUT
RINGING CURRENT
IN LINE
(C)
RELAY DRIVER
OFF
ON
OFF
FIGURE 19. RINGING SEQUENCE
Operation of Line Voltage Measurement
A few of the SLICs in the UniSLIC14 family feature Line
Voltage Measurement (LVM) capability. This feature
provides a pulse on the GKD_LVM output pin that is
proportional to the loop voltage. Knowing the loop voltage
and thus the loop length, other basic cable characteristics
such as attenuation and capacitance can be inferred.
Decisions can be made about gain switching in the CODEC
to overcome line losses and verification of the 2-wire circuit
integrity.
The LVM function can only be activated in the off hook
condition in either the forward or reverse operating states. The
LVM uses the ring signal supplied to the SLIC as a timebase
generator. The loop resistance is determined by monitoring
the pulse width of the output signal on the GKD_LVM pin. The
output signal on the GKD_LVM pin is a square wave for which
the average duration of the low state is proportional to the
average voltage between the tip and ring terminals. The loop
resistance is determined by the tip to ring voltage and the
constant loop current. Reference Figure 20.
Although the logic state changes to the Test Active State
when performing this test, the SLIC is still powered up in the
22
Most of the SLICs in the UniSLIC14 family feature full
polarity reversal. Full polarity reversal means that the SLIC
can: transmit, determine the status of the line (on hook and
off hook) and provide “silent” polarity reversal. The value of
RSYNC_REV resistor is limited between 34.8k (10ms) and
73.2k (21ms). Reference Equation 39 to program the polarity
reversal time.
Transhybrid Balance
If a low cost CODEC is chosen that does not have a transmit
op-amp, the UniSLIC14 family of SLICs can solve this
problem without the need for an additional op-amp. The
solution is to use the Programmable Transmit Gain pin (PTG)
as an input for the receive signal (VRX). In theory, when the
PTG pin is connected to a divider network (R1 and R2
Figure 21) and the value of R1 and R2 is much less than the
internal 500kΩ resistors, two things happen. First the transmit
gain from VRX to VTX is reduced by half. This is the result of
shorting out the bottom 500kΩ resistor with the much smaller
external resistor. And second, the input signal from VRX is
also decreased by the voltage divider R1 and R2. Transhybrid
balance occurs when these two, equal but opposite in phase,
signals are cancelled at the input to the output buffer. The
calculation of the value of R2, once R1 is selected, is effected
by the line feed resistors. EQ. 40 can be used to calculate the
value of R2. Where : ZL= Line Impedance, ZTR = input
impedance of SLIC including the protection resistor, and
RP = protection resitors (typical 30Ω).
·
·
R 1 II500K  ZL + ZTR  R 1 II500K
R 2 = --------------------------  ------------------------------ – -------------------------1.02  ZL + 2ZR P
1.02
(EQ. 40)
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
+
A=1
500K
IX
500K
network (including SLIC) to be tested up to the subscriber
loop.
VTX
VTX
+
R1
IX
500K
R2
VRX
+
500K
VRX
-
5
UniSLIC14
FIGURE 21. TRANSHYBRID BALANCE USING THE PTG PIN
Loopback Tests
This feature can be very useful in the testing of line cards
during the manufacturing process and in field use. The test
is unobtrusive, allowing it to be used in live systems.
Reference Figure 22.
Most systems do not provide 4-wire loopback test capability
because of costly relays needed to switch in external loads.
All the SLICs in the UniSLIC14 family can easily provide
this function when configured in the Open Circuit logic
state. With the PTG pin floating, the signal on the VTX
output is 180o out of phase and approximately 2 times the
VRX input signal. If the PTG pin is grounded, then the
amplitude will be approximately the same as the input
signal and 180 o out of phase.
UniSLIC14
INTERNAL
600Ω
RING
VTX
PTG
+
DUAL SUPPLY
CODEC/FILTER
VRX
2-WIRE LOOPBACK
1) Providing adequate signal gain and current drive to the
subscriber metering equipment to overcome the attenuation
of this (12kHz, 16kHz) out of band signal.
2) Attenuating the pulse metering transhybrid signal without
severely attenuating the voice band signal to avoid clipping
in the CODEC/Filter.
3) Tailoring the overload levels in the SLIC to avoid clipping
of the combined voiceband and pulse metering signal.
4-Wire Loopback Test
TIP
Pulse Metering
The HC55121, HC55142, HC35143, HC55150 and the
HC55151 are designed to support pulse metering. They offer
solutions to the following pulse metering design issues:
PTG
4-WIRE LOOPBACK
FIGURE 22. 4-WIRE AND 2-WIRE LOOPBACK TESTS
2-Wire Loopback Test
Most of the SLICs in the UniSLIC14 family feature 2-Wire
loopback testing. This loopback function is only activated
when the subscriber is on hook and the logic command to
the SLIC is in the Test Active State. (Note: if the subscriber
is off hook and in the Test Active State, the function
performed is the Line Voltage Measurement.)
During the 2-wire loopback test, a 2kΩ internal resistor is
switched across the tip and ring terminals of the SLIC. This
allows the SHD function and the 4-wire to 4-wire AC
transmission, right up to the subscriber loop, to be tested.
Together with the 4-wire loopback test in the Open Circuit
logic state, this 2-wire loopback test allows the complete
23
4) Having the provision of silent polarity reversal as a backup
in the case where the loop attenuates the out of band signal
too much for it to be detected by the subscriber’s metering
equipment.
Adequate Signal Gain
Adequate signal gain and current drive to the subscriber’s
metering equipment is made easier by the network shown in
Figure 23. The pulse metering signal is supplied to a
dedicated high impedance input pin called SPM. The circuit
in Figure 23 shows the connection of a network that sets the
2-wire impedance (ZTR), at the pulse metering frequencies,
to be approximately 200Ω. If the line impedance (Z L) is
equal to 200Ω at the pulse metering frequencies, then the 4Wire to 2-wire gain (VTR / SPM) is equal 4. Thereby lowering
the input signal requirements of the pulse metering signal.
Note: The automatic pulse metering 2-wire impedance
matching is independent of the programmed 2-wire
impedance matching at voiceband frequencies.
Calculation of the pulse metering gain is achieved by
replacing VRX / 500k in Equation 15 with SPM/ 125k and
following the same process through to Equation 21. The
UniSLIC14 sets the 2-wire input impedance of the SLIC
(ZTR), including the protection resistors, equal to 200Ω. The
results are shown in Equation 41.
ZL
V TR
200
A4-2 = ------------- = – 8 ------------------------- = – 8 --------------------------- = – 4
200 + 200
SPM
ZL + Z TR
(EQ. 41)
Avoiding Clipping in the CODEC/Filter
The amplitude of the returning pulse metering signal is often
very large and could easily over drive the input to the
CODEC/Filter. By using the same method discussed in
section “Transhybrid Balance”, most if not all of the pulse
metering signal can be canceled out before it reaches the
input to the CODEC/Filter. This connection is shown in
Figure 23.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Overload Levels and Silent Polarity Reversal
The pulse metering signal and voice are simultaneously
transmitted, and therefore require additional overhead to
prevent distortion of the signal. Reference section “Off hook
Overhead Voltage” to account for the additional pulse
metering signal requirements.
of the CODEC/Filter, one of the DC blocking capacitors can
be eliminated (Figure 24B).
+
A=1
VTX
+
DUAL SUPPLY
CODEC/FILTER
VOUT
VRX
5V
GND
-5V
UniSLIC14
FIGURE 24A.
500K
+
A=1
VTX
VIN
PTG
FIGURE 23. PULSE METERING WITH TRANSHYBRID
BALANCE
Most of the SLICs in the UniSLIC14 family feature full
polarity reversal. Full polarity reversal means that the SLIC
can: transmit, determine the status of the line (on hook and
off hook) and provide “silent” polarity reversal. Reference
Equation 39 to program the polarity reversal time.
Interface to Dual and Single Supply
CODECs
VREF SINGLE SUPPLY
DSP
CODEC/FILTER
VOUT
500K
VRX
5V
GND
UniSLIC14
FIGURE 24B.
FIGURE 24. INTERFACE TO DUAL AND SINGLE SUPPLY
CODECs
Power Management
Great care has been taken to minimize the number of external
components required with the UniSLIC14 family while still
providing the maximum flexibility. Figures 24A, 24B) shows
the connection of the UniSLIC14 to both a dual supply
CODEC/Filter and a single supply DSP CODEC/Filter.
The UniSLIC14 family provides two distinct power
management capabilities:
To eliminate the DC blocking capacitors between the SLIC
and the CODEC/Filter when using a dual supply
CODEC/Filter, both the receive and transmit leads of the
SLIC are referenced to ground. This leads to a very simple
SLIC to CODEC/Filter interface, as shown in Figure 24A.
Power sharing is a method of redistributing the power away
from the SLIC in short loop applications. The total system
power is the same, but the die temperature of the SLIC is
much lower. Power sharing becomes important if the
application has a single battery supply (-48V on hook
requirements for faxes and modems) and the possibility of
high loop currents (reference Figure 25). This technique
would prevent the SLIC from getting too hot and thermally
shutting down on short loops.
When using a single supply DSP CODEC/Filter the output
and input of the CODEC/Filter are no longer referenced to
ground. To achieve maximum voltage swing with a single
supply, both the output and input of the CODEC/Filter are
referenced to its own VCC /2 reference. Thus, DC blocking
capacitors are once again required. By using the PTG pin of
the UniSLIC14 and the externally supplied VCC/2 reference
24
Power Sharing and Battery Selection
Power Sharing
The power dissipation in the SLIC is the sum of the smaller
quiescent supply power and the much larger power that
results from the loop current. The power that results from the
loop current is the loop current times the voltage across the
SLIC. The power sharing resistor (RPS) reduces the voltage
across the SLIC, and thereby the on-chip power dissipation.
The voltage across the SLIC is reduced by the voltage drop
across RPS. This occurs because RPS is in series with the
loop current and the negative supply.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
A mathematical verification follows:
Battery Selection
Given: V BH = VBL = -48V, Loop current = 30mA, RL (load
across tip and ring) = 600Ω, Quiescent battery power =
(48V) (0.8mA) = 38.4mW, Quiescent VCC power = (5V)
(2.7mA) = 13.5mW, Power sharing resistor = 600Ω.
Battery selection is a technique, for a two battery supply
system, where the SLIC automatically diverts the loop
current to the most appropriate supply for a given loop
length. This results in significant power savings and lowers
the total power consumption on short loops. This technique
is particularly useful if most of the lines are short, and the on
hook condition requires a -48V battery. In Figure 26, it can
be seen that for long loops the majority of the current comes
from the high battery supply (VBH ) and for short loops from
the low battery supply (VBL).
1. Without power sharing, the on-chip power dissipation
would be 952mW (Equation 42).
2. With power sharing, the on-chip power dissipation is
412mW (Equation 43). A power redistribution of 540mW.
On-chip power dissipation without power sharing resistor.
PD = ( VBH ) ( 30mA ) + 38.4mW + 13.5 mW – ( RL ) ( 30m A )
2
40
35
On-chip power dissipation with 600Ω power sharing resistor.
PD = ( VBH ) ( 30mA ) + 38.4mW + 13.5 mW
(EQ. 43)
PD = 412mW
25
VBH = -48V
VBL = -24V
RILim = 33.2kΩ
20
15
10
5
150
100
200
250
300
350
400
450
475
500
525
550
575
600
700
800
VTX
LOOP RESISTANCE (Ω)
RING
ON SHORT LOOPS, THE
MAJORITY OF CURRENT
FLOWS OUT THE VBL PIN
VBH
0
UniSLIC14
2000
TIP
VBL
900
– ( R L ) ( 30mA ) – ( R PS ) ( 30mA )
2
VBL
VBH
30
1000
2
LOOP CURRENT (mA)
(EQ. 42)
PD = 952m W
VRX
VBL
FIGURE 26. BATTERY SELECTION (DUAL SUPPLY SYSTEMS)
VBH
RPS
-48V
-48V
FIGURE 25. POWER SHARING (SINGLE SUPPLY SYSTEMS)
Pinouts - 28 Lead PLCC Packages
CH
RRLY
PTG
VTX
NC
VRX
ZT
CH
RRLY
PTG
VTX
SPM
VRX
HC55121
(28 LEAD PLCC)
TOP VIEW
ZT
HC55120
(28 LEAD PLCC)
TOP VIEW
4
3
2
1
28
27
26
4
3
2
1
28
27
26
RING 5
25 AGND
RING 5
BGND 6
24 RSYNC
BGND 6
25 AGND
24 RSYNC_REV
TIP 7
23 ILIM
TIP 7
23 ILIM
VBH 8
22 ROH
VBH 8
22 ROH
VBL 9
21 RD
VBL 9
21 RD
15
16
17
18
12
13
14
15
16
17
18
C3
C2
C1
SHD
14
DR
13
DT
12
CDC
19 GKD
SHD
CRT_REV 11
C1
19 GKD
C2
CRT 11
C3
20 VCC
DR
RDC_RAC 10
DT
20 VCC
CDC
RDC_RAC 10
25
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Pinouts - 28 Lead PLCC Packages
(Continued)
CH
RRLY
PTG
VTX
NC
VRX
ZT
CH
RRLY
PTG
VTX
NC
VRX
HC55140
(28 LEAD PLCC)
TOP VIEW
ZT
HC55130
(28 LEAD PLCC)
TOP VIEW
4
3
2
1
28
27
26
4
3
2
1
28
27
26
RING 5
25 AGND
RING 5
BGND 6
24 RSYNC
BGND 6
25 AGND
24 RSYNC_REV
TIP 7
23 ILIM
TIP 7
23 ILIM
VBH 8
22 ROH
VBH 8
22 ROH
VBL 9
21 RD
VBL 9
21 RD
17
18
12
13
SHD
CDC
DT
14
15
16
17
18
SHD
16
C1
15
C2
14
C3
13
C1
19 GKD_LVM
C2
CRT_REV_ 11
LVM
C3
19 NC
20 VCC
DR
CDC
12
RDC_RAC 10
DT
CRT 11
20 VCC
DR
RDC_RAC 10
HC55150
(28 LEAD PLCC)
TOP VIEW
ZT
CH
RRLY
PTG
VTX
SPM
VRX
ZT
CH
RRLY
PTG
VTX
SPM
VRX
HC55142
(28 LEAD PLCC)
TOP VIEW
4
3
2
1
28
27
26
4
3
2
1
28
27
26
RING 5
25 AGND
RING
5
25 AGND
BGND
6
24 RSYNC_REV
TIP
7
23 ILIM
TIP 7
23 ILIM
VBH
8
22 ROH
VBH 8
22 ROH
VBL
9
21 RD
VBL 9
21 RD
20 VCC
RDC_RAC 10
CRT_REV_ 11
LVM
15
16
17
18
12
13
14
15
16
17
18
CDC
DT
DR
C3
C2
C1
SHD
DR
19 LVM
SHD
DT
CRT_REV_ 11
LVM
C1
14
20 VCC
C2
13
RDC_RAC 10
C3
12
CDC
19 GKD_LVM
24 RSYNC_REV
BGND 6
26
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Pinouts - 32 Lead PLCC Packages
CH
RRLY
PTG
TRLY1
TRLY2
VTX
ZT
CH
RRLY
PTG
TRLY1
TRLY2
VTX
HC55141
(32 LEAD PLCC)
TOP VIEW
ZT
HC55131
(32 LEAD PLCC)
TOP VIEW
4
3
2
1
32
31
30
4
3
2
1
32
31
30
RING 5
29 NC
RING 5
29 NC
BGND 6
28 VRX
BGND 6
28 VRX
TIP 7
27 AGND
TIP 7
VBH 8
26 RSYNC
VBH 8
26 RSYNC_REV
VBL 9
25 ILIM
VBL 9
25 ILIM
RDC_RAC 10
24 ROH
RDC_RAC 10
24 ROH
16
17
18
19
20
14
15
C3
C2
C1
SHD
DR
C5
16
17
18
19
20
SHD
15
C4
DR
14
21 GKD_LVM
DT 13
C5
DT 13
22 VCC
CDC 12
C1
21 NC
23 RD
C2
CDC 12
22 VCC
CRT_REV_LVM 11
C3
23 RD
C4
CRT 11
27 AGND
HC55151
(32 LEAD PLCC)
TOP VIEW
ZT
CH
RRLY
PTG
TRLY1
TRLY2
VTX
ZT
CH
RRLY
PTG
TRLY1
TRLY2
VTX
HC55143
(32 LEAD PLCC)
TOP VIEW
4
3
2
1
32
31
30
4
3
2
1
32
31
30
RING
5
29 SPM
RING 5
29 SPM
BGND
6
28 VRX
BGND 6
28 VRX
27 AGND
TIP 7
VBH
26 RSYNC_REV
8
27 AGND
TIP 7
VBH 8
26 RSYNC_REV
VBL 9
25 ILIM
VBL 9
25 ILIM
RDC_RAC 10
CRT_REV_
11
LVM
CDC 12
24 ROH
RDC_RAC 10
CRT_REV_
11
LVM
CDC 12
24 ROH
DT 13
21 LVM
23 RD
22 VCC
21 GKD_LVM
19
20
14
15
16
17
18
19
20
DR
C5
C4
C3
C2
C1
SHD
C4
18
SHD
C5
17
C1
16
C2
15
22 VCC
C3
14
DR
DT 13
23 RD
27
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Pinouts - 28 Lead SOIC Packages
HC55121
(28 LEAD SOIC)
TOP VIEW
HC55120
(28 LEAD SOIC)
TOP VIEW
ZT 1
28 AGND
ZT 1
28 AGND
PTG 2
27 VTX
PTG 2
27 VTX
RRLY 3
26 NC
RRLY 3
26 SPM
CH 4
25 VRX
25 VRX
CH 4
RING 5
24 RSYNC
RING 5
24 RSYNC_REV
BGND 6
23 ILIM
BGND 6
23 ILIM
TIP 7
22 ROH
TIP 7
22 ROH
VBH 8
21 RD
VBH 8
21 RD
VBL 9
20 VCC
VBL 9
20 VCC
RDC_RAC 10
19 SHD
RDC_RAC 10
19 SHD
CDC 11
18 C1
CDC 11
18 C1
DT 12
17 C2
DT 12
17 C2
DR 13
16 C3
DR 13
16 C3
CRT 14
15 GKD
CRT_REV 14
HC55140
(28 LEAD SOIC)
TOP VIEW
HC55130
(28 LEAD SOIC)
TOP VIEW
ZT 1
15 GKD
28 AGND
ZT 1
28 AGND
PTG 2
27 VTX
PTG 2
27 VTX
RRLY 3
26 NC
RRLY 3
26 NC
25 VRX
CH 4
RING 5
24 RSYNC
CH 4
RING 5
25 VRX
24 RSYNC_REV
BGND 6
23 ILIM
BGND 6
23 ILIM
TIP 7
22 ROH
TIP 7
22 ROH
VBH 8
21 RD
VBH 8
21 RD
VBL 9
20 VCC
VBL 9
20 VCC
RDC_RAC 10
19 SHD
RDC_RAC 10
19 SHD
CDC 11
18 C1
CDC 11
18 C1
DT 12
17 C2
DT 12
17 C2
DR 13
16 C3
DR 13
16 C3
CRT 14
15 NC
CRT_REV_LVM 14
28
15 GKD_LVM
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Pinouts - 28 Lead SOIC Packages
(Continued)
HC55142
(28 LEAD SOIC)
TOP VIEW
ZT 1
HC55150
(28 LEAD SOIC)
TOP VIEW
28 AGND
ZT 1
28 AGND
PTG 2
27 VTX
PTG 2
27 VTX
RRLY 3
26 SPM
RRLY 3
26 SPM
CH 4
25 VRX
CH 4
25 VRX
RING 5
24 RSYNC_REV
RING 5
24 RSYNC_REV
BGND 6
23 ILIM
BGND 6
23 ILIM
TIP 7
22 ROH
TIP 7
22 ROH
VBH 8
21 RD
VBH 8
21 RD
VBL 9
RDC_RAC 10
20 VCC
VBL 9
20 VCC
19 SHD
RDC_RAC 10
19 SHD
CDC 11
18 C1
CDC 11
18 C1
DT 12
17 C2
DT 12
17 C2
DR 13
16 C3
DR 13
16 C3
CRT_REV_LVM 14
15 GKD_LVM
CRT_REV_LVM 14
15 LVM
Pin Descriptions
28
PIN
PLCC
32
PIN
PLCC
28
PIN
SOIC
SYMBOL
DESCRIPTION
1
1
2
PTG
Programmable Transmit Gain - The 2-wire to 4-wire transmission gain is 0dB if this pin is left floating
and -6.02dB if tied to ground. The -6.02dB gain option is useful in systems where Pulse Metering is
used. See Figure 23.
2
2
3
RRLY
3
3
4
CH
AC/DC Separation Capacitor - CH is required to properly process the AC current from the DC loop
current. Recommended value 0.1µF.
4
4
1
ZT
2-Wire Impedance Matching Pin - Impedance matching of the 2-wire side is accomplished by placing
an impedance between the ZT pin and ground. See Equation 32.
Ring Relay Driver Output - The relay coil may be connected to a maximum of 14V.
5
5
5
RING
Connects via protection resistor RP to ring wire of subscriber pair.
6
6
6
BGND
Battery ground.
7
7
7
TIP
Connects via protection resistor RP to tip wire of subscriber pair.
8
8
8
VBH
High Battery Supply (negative with respect to GND).
9
9
9
VBL
Low Battery Supply (negative with respect to GND, magnitude ≤ VBH).
10
10
10
RDC_RAC
Resistive Feed/Anti Clipping - Performs anti clipping function on constant current application and sets
the slope of the resistive feed curve for constant voltage applications.
11
11
14
CRT_REV
_LVM
Ring Trip, Soft Polarity Reversal and Line Voltage Measurement - A capacitor when placed between the
CRT_REV_LVM pin and +5V performs 3 mutually exclusive functions. When the SLIC is configured in the
Ringing mode it provides filtering of the ringing signal to prevent false detect. When the SLIC is transitioning
between the Forward Active State and Reverse Active State it provides Soft Polarity Reversal and
performs charge storage in the Line Voltage Measurement State. Recommended value 0.47µF.
12
12
11
CDC
13
13
12
DT
Tip side of Ring Trip Detector - Ring trip detection is accomplished by connecting an external network
to a detector in the SLIC with inputs DT and DR. Ring trip occurs when the voltage on DT is more
negative than the voltage on DR.
14
14
13
DR
Ring Side of Ring Trip Detector - Ring trip detection is accomplished by connecting an external
network to a detector in the SLIC with inputs DT and DR. Ring trip occurs when the voltage on DR is
more positive than the voltage on DT.
-
15
-
C5
Activates Test Relay TRLY2. TTL Compatible Logic Input. C5 input high, test relay TRLT2 Low(ON).
C5 input floating, test relay TRLY2 High(OFF). This is due to an internal 100kΩ pull down resistor.
29
Filter Capacitor - The CDC Capacitor removes the VF signals from the battery feed control loop.
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Pin Descriptions
(Continued)
28
PIN
PLCC
32
PIN
PLCC
28
PIN
SOIC
SYMBOL
DESCRIPTION
-
16
-
C4
Activates Test Relay TRLY1. TTL Compatible Logic Input. C4 input high, test relay TRLT1 Low(ON).
C4 input floating, test relay TRLY1 High(OFF). This is due to an internal 100kΩ pull down resistor.
15
17
16
C3
TTL Compatible Logic Input. The logic states of C1, C2 and C3 determine the operating states of the
SLIC. Reference Table 1 for details.
16
18
17
C2
TTL Compatible Logic Input. The logic states of C1, C2 and C3 determine the operating states of the
SLIC. Reference Table 1 for details.
17
19
18
C1
TTL Compatible Logic Input. The logic states of C1, C2 and C3 determine the operating states of the
SLIC. Reference Table 1 for details.
18
20
19
SHD
Switch Hook Detect - Active during off hook, ground key and loopback. Reference Table 1 for details.
19
21
15
GKD_LVM
20
22
20
VCC
5V Supply.
21
23
21
RD
Loop Current Threshold Programming Pin - A resistor between this pin and ground will determine the
trigger level for the loop current detect circuit. See Equation 7.
22
24
22
ROH
Off Hook Overload Setting Resistor - Used to set combined overhead for voice and pulse metering
signals. See Equation 10.
23
25
23
ILIM
Current Limit Programming Pin - A resistor between this pin and ground will determine the constant
current limit of the feed curve. See Equation 11.
24
26
24
RSYNC_REV
25
27
28
AGND
26
28
25
VRX
Receive Input - Ground referenced 4-wire side.
27
29
26
SPM
Pulse Metering Signal Input. If pulse metering is not used, then this pin should be grounded as close
to the device pin as possible. Input impedance to ground = 125kΩ.
28
30
27
VTX
Transmit Output - Ground referenced 4-wire side.
-
31
-
TRLY2
Test Relay Driver 2. Open Collector Transistor. Internal Clamp between it’s output and ground
elimnates the need to place an external snubber diode across Test Relay Driver. TRLY2 may be
connected to maximum of 14V.
-
32
-
TRLY1
Test Relay Driver 1. Open Collector Transistor. Internal Clamp between it’s output and ground
elimnates the need to place an external snubber diode across Test Relay Driver. TRLY1 may be
connected to maximum of 14V.
30
Ground Key Detector and Line Voltage Measurement - Reference Table 1 for details.
Ring Synchronization Input and Reversal Time Setting. A resistor between this pin and GND
determines the polarity reversal time. Synchronization of the closing of the relay at zero voltage is
achieved via a ring sync pulse (5V to 0V) synchronized to the ring signal zero voltage crossing
(Reference Figure 18).
Analog ground
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Basic Application Circuit
Voice Only 28 Lead PLCC Package
R11
+5V
20
+5V OR
+12V
C1
2
RELAY
3
RING
VCC
U1
RRLY
PTG
CH
SPM
C2
RP
5
C8
U2
VTX
6
VRX
RING
AGND
BGND
ZT
TIP
C9
RP
7
D1
-24V
-48V
8
OPTIONAL
C7
C5
9
R1
C6
+
R2
10
- 12
C3
VBAT
VBH
VBL
27
RDC_RAC
CDC
SHD
GKD_LVM
DT
C1
14
DR
C2
11
CRT_REV_LVM
C3
†R10
††C11
26
25
4
R8
24
R7
23
R6
22
R5
21
R4
ILIM
RD
† R9
1
ROH
13
R12
R3
RING
GENERATOR
TIP
RSYNC_REV
††C10
28
CODEC/FILTER
†
PERFORM TRANSHYBRID BALANCE
WHEN USING A NON-DSP CODEC.
NOT REQUIRED FOR DSP CODEC.
††
NOT REQUIRED FOR
NON-DSP CODEC’s.
REQUIRED FOR DSP CODEC’s
18
19
17
16
15
C4
CONTROL LOGIC
+5V
FIGURE 27. UniSLIC14 VOICE ONLY BASIC APPLICATION CIRCUIT
TABLE 2. BASIC APPLICATION CIRCUIT COMPONENT LIST
COMPONENT
U1 - SLIC
U2 - Dual Asymmetrical Transient Voltage Suppressor
VALUE
TOLERANCE
RATING
UniSLIC14 Family
N/A
N/A
TISP1072F3
N/A
N/A
RP (Line Feed Resistors)
30Ω
Matched 1%
2.0W
R1 (RDC_RAC Resistor)
21kΩ
1%
1/16W
R2, R3
2MΩ
1%
1/16W
41.2kΩ
1%
1/16W
R4 (RD Resistor)
R5 (ROH Resistor)
38.3kΩ
1%
1/16W
R6 (RILIM Resistor)
33.2kΩ
1%
1/16W
R7 (RSYNC_REV Resistor)
34.8kΩ
1%
1/16W
R8 (RZT Resistor)
107kΩ
1%
1/16W
20kΩ
1%
1/16W
R9, R10, R11
R12
400Ω
5%
2W
C1 (Supply Decoupling), C2
0.1µF
20%
10V
C5 (Supply Decoupling)
0.1µF
20%
50V
C6 (Supply Decoupling)
0.1µF
20%
100V
C4, C7, C10, C11
0.47µF
20%
10V
C3
4.7µF
20%
50V
C8, C9
2200pF
20%
100V
D1, Recommended if the VBL supply is not derived from the VBH Supply
1N4004
-
-
Design Parameters: Maximum on hook voltage = 0.775V RMS, Maximum Off hook Voice = 3.2VPEAK, Switch Hook Threshold = 12mA, Loop Current
Limit = 31mA, Synthesize Device Impedance = 540Ω (600 - 60), with 30Ω protection resistors, impedance across Tip and Ring terminals = 600Ω.
Where applicable, these component values apply to the Basic Application Circuits for the HC55120, HC55121, HC55130/1, HC55140/1, HC55142/3
and HC55150/1. Pins not shown in the Basic Application Circuit are no connect (NC) pins.
31
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Basic Application Circuit
Pulse Metering 28 Lead PLCC Package
R11
+5V
20
+5V OR
+12V
VCC
C1
2
RELAY
RING
U1
3
CH
SPM
C2
RP
5
C8
U2
6
AGND
C9
RP
-24V
-48V
7
D1
OPTIONAL
C5
C6
8
C7
VBH
- 12
C3
R12
13
14
RDC_RAC
CDC
24
R7
23
R6
22
R5
21
R4
CODEC/FILTER
12/16kHz
PULSE METERING
INPUT SIGNAL
†
PERFORM TRANSHYBRID BALANCE
WHEN USING A NON-DSP CODEC.
NOT REQUIRED FOR DSP CODEC.
18
SHD
GKD_LVM
DT
C1
DR
C2
CRT_REV_LVM
C3
11
R3
R8
ROH
RD
10
4
ILIM
VBL
+
RING
GENERATOR
VBAT
RSYNC_REV
9
R1
R2
TIP
†R10
††C11
25
BGND
ZT
TIP
27
26
VRX
RING
†R9
1
PTG
RRLY
††C10
28
VTX
††
19
17
NOT REQUIRED FOR
NON-DSP CODEC’s.
REQUIRED FOR DSP CODEC’s
16
15
C4
CONTROL LOGIC
+5V
FIGURE 28. UniSLIC14 PULSE METERING BASIC APPLICATION CIRCUIT
TABLE 3. BASIC APPLICATION CIRCUIT COMPONENT LIST
COMPONENT
U1 - SLIC
U2 - Dual Asymmetrical Transient Voltage Suppressor
VALUE
TOLERANCE
RATING
UniSLIC14 Family
N/A
N/A
TISP1072F3
N/A
N/A
RP (Line Feed Resistors)
30Ω
Matched 1%
2.0W
R1 (RDC_RAC Resistor)
26.1kΩ
1%
1/16W
2MΩ
1%
1/16W
R4 (RD Resistor)
R2, R3
41.2kΩ
1%
1/16W
R5 (ROH Resistor)
38.3kΩ
1%
1/16W
R6 (RILIM Resistor)
33.2kΩ
1%
1/16W
R7 (RSYNC_REV Resistor)
34.8kΩ
1%
1/16W
R8 (RZT Resistor)
107kΩ
1%
1/16W
R9, R10, R11
20kΩ
1%
1/16W
R12
400Ω
5%
2W
C1 (Supply Decoupling), C2
0.1µF
20%
10V
C5 (Supply Decoupling)
0.1µF
20%
50V
C6 (Supply Decoupling)
0.1µF
20%
100V
C4, C7, C10, C11
0.47µF
20%
10V
C3
4.7µF
20%
50V
C8, C9
2200pF
20%
100V
D1, Recommended if the VBL supply is not derived from the VBH Supply
1N4004
-
-
Design Parameters: Maximum on hook voltage = 0.775VRMS, Maximum off hook voice = 1.1VPEAK, Maximum simultaneous pulse metering
signal = 2.2V RMS, Switch Hook Threshold = 12mA, Loop Current Limit = 31mA, Synthesize Device Impedance = 540Ω (600 - 60), with 30Ω
protection resistors, impedance across Tip and Ring terminals = 600Ω . Where applicable, these component values apply to the Basic Application
Circuits for the HC55120, HC55121, HC55130/1, HC55140/1, HC55142/3 and HC55150/1. Pins not shown in the Basic Application Circuit are
no connect (NC) pins.
32
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Basic Application Circuit - Voice Only 28 Lead SOIC Package
R11
+5V
20
+5V OR
+12V
VCC
C1
3
RELAY
4
RING
U1
CH
SPM
5
C8
U2
6
VRX
RING
AGND
BGND
ZT
TIP
RP
C9
7
D1
-48V
8
OPTIONAL
-24V
C5
C6
C7
9
R1
10
+
R2
C3
11
13
14
R3
RING
GENERATOR
VBAT
RSYNC_REV
TIP
VBH
† R9
26
VBL
RDC_RAC
28
1
R8
24
R7
23
R6
22
R5
21
R4
ILIM
CDC
RD
SHD
GKD_LVM
DT
C1
DR
C2
CRT_REV_LVM
C3
†R10
††C11
25
ROH
12
R12
††C10
27
RRLY
C2
RP
VTX
CODEC/FILTER
†
PERFORM TRANSHYBRID BALANCE
WHEN USING A NON-DSP CODEC.
NOT REQUIRED FOR DSP CODEC.
††
NOT REQUIRED FOR
NON-DSP CODEC’s.
REQUIRED FOR DSP CODEC’s
19
15
18
17
16
C4
CONTROL LOGIC
+5V
FIGURE 29. UniSLIC14 VOICE ONLY BASIC APPLICATION CIRCUIT
TABLE 4. BASIC APPLICATION CIRCUIT COMPONENT LIST
COMPONENT
U1 - SLIC
U2 - Dual Asymmetrical Transient Voltage Suppressor
VALUE
TOLERANCE
RATING
UniSLIC14 Family
N/A
N/A
TISP1072F3
N/A
N/A
RP (Line Feed Resistors)
30Ω
Matched 1%
2.0W
R1 (RDC_RAC Resistor)
21kΩ
1%
1/16W
R2, R3
2MΩ
1%
1/16W
R4 (RD Resistor)
41.2kΩ
1%
1/16W
R5 (ROH Resistor)
38.3kΩ
1%
1/16W
R6 (RILIM Resistor)
33.2kΩ
1%
1/16W
R7 (RSYNC_REV Resistor)
34.8kΩ
1%
1/16W
R8 (RZT Resistor)
107kΩ
1%
1/16W
20kΩ
1%
1/16W
R9, R10, R11
R12
400Ω
5%
2W
C1 (Supply Decoupling), C2
0.1µF
20%
10V
C5 (Supply Decoupling)
0.1µF
20%
50V
C6 (Supply Decoupling)
0.1µF
20%
100V
C4, C7, C10, C11
0.47µF
20%
10V
C3
4.7µF
20%
50V
C8, C9
2200pF
20%
100V
D1, Recommended if the VBL supply is not derived from the VBH Supply
1N4004
-
-
Design Parameters: Maximum on hook voltage = 0.775V RMS, Maximum Off hook Voice = 3.2VPEAK, Switch Hook Threshold = 12mA, Loop Current
Limit = 31mA, Synthesize Device Impedance = 540Ω (600 - 60), with 30Ω protection resistors, impedance across Tip and Ring terminals = 600Ω.
Where applicable, these component values apply to the Basic Application Circuits for the HC55120, HC55121, HC55130/1, HC55140/1, HC55142/3
and HC55150/1. Pins not shown in the Basic Application Circuit are no connect (NC) pins.
33
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Small Outline Plastic Packages (SOIC)
M28.3 (JEDEC MS-013-AE ISSUE C)
N
28 LEAD WIDE BODY SMALL OUTLINE PLASTIC PACKAGE
INDEX
AREA
H
0.25(0.010) M
B M
INCHES
E
SYMBOL
-B-
1
2
3
L
SEATING PLANE
-A-
h x 45o
A
D
-C-
e
A1
B
0.25(0.010) M
C
0.10(0.004)
C A M
B S
1. Symbols are defined in the “MO Series Symbol List” in Section 2.2
of Publication Number 95.
2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Dimension “D” does not include mold flash, protrusions or gate
burrs. Mold flash, protrusion and gate burrs shall not exceed
0.15mm (0.006 inch) per side.
4. Dimension “E” does not include interlead flash or protrusions. Interlead flash and protrusions shall not exceed 0.25mm (0.010
inch) per side.
5. The chamfer on the body is optional. If it is not present, a visual
index feature must be located within the crosshatched area.
6. “L” is the length of terminal for soldering to a substrate.
7. “N” is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. The lead width “B”, as measured 0.36mm (0.014 inch) or greater
above the seating plane, shall not exceed a maximum value of
0.61mm (0.024 inch)
10. Controlling dimension: MILLIMETER. Converted inch dimensions are not necessarily exact.
34
MILLIMETERS
MIN
MAX
NOTES
A
0.0926
0.1043
2.35
2.65
-
0.0040
0.0118
0.10
0.30
-
B
0.013
0.0200
0.33
0.51
9
C
0.0091
0.0125
0.23
0.32
-
D
0.6969
0.7125
17.70
18.10
3
E
0.2914
0.2992
7.40
7.60
4
0.05 BSC
10.00
h
0.01
0.029
0.25
0.75
5
L
0.016
0.050
0.40
1.27
6
8o
0o
28
0o
10.65
-
0.394
N
0.419
1.27 BSC
H
α
NOTES:
MAX
A1
e
α
MIN
28
-
7
8o
Rev. 0 12/93
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Plastic Leaded Chip Carrier Packages (PLCC)
0.042 (1.07)
0.048 (1.22)
PIN (1) IDENTIFIER
0.042 (1.07)
0.056 (1.42)
0.004 (0.10)
C
0.025 (0.64)
R
0.045 (1.14)
0.050 (1.27) TP
C
L
D2/E2
C
L
E1 E
D2/E2
VIEW “A”
0.020 (0.51)
MIN
A1
A
D1
D
0.026 (0.66)
0.032 (0.81)
0.013 (0.33)
0.021 (0.53)
0.025 (0.64)
MIN
0.045 (1.14)
MIN
VIEW “A” TYP.
NOTES:
1. Controlling dimension: INCH. Converted millimeter dimensions are
not necessarily exact.
2. Dimensions and tolerancing per ANSI Y14.5M-1982.
3. Dimensions D1 and E1 do not include mold protrusions. Allowable
mold protrusion is 0.010 inch (0.25mm) per side. Dimensions D1
and E1 include mold mismatch and are measured at the extreme
material condition at the body parting line.
4. To be measured at seating plane -C- contact point.
5. Centerline to be determined where center leads exit plastic body.
6. “N” is the number of terminal positions.
35
INCHES
MILLIMETERS
SYMBOL
MIN
MAX
MIN
MAX
NOTES
A
0.165
0.180
4.20
4.57
-
A1
0.090
0.120
2.29
3.04
-
D
0.485
0.495
12.32
12.57
-
D1
0.450
0.456
11.43
11.58
3
D2
0.191
0.219
4.86
5.56
4, 5
E
0.485
0.495
12.32
12.57
-
E1
0.450
0.456
11.43
11.58
3
E2
0.191
0.219
4.86
5.56
4, 5
N
28
28
6
Rev. 2 11/97
SEATING
-C- PLANE
0.020 (0.51) MAX
3 PLCS
N28.45 (JEDEC MS-018AB ISSUE A)
28 LEAD PLASTIC LEADED CHIP CARRIER PACKAGE
HC55120,HC55121,HC55130,HC55131,HC55140,HC55141,HC55142,HC55143,HC55150,HC55151
Plastic Leaded Chip Carrier Packages (PLCC)
0.042 (1.07)
0.048 (1.22)
N32.45x55
0.042 (1.07)
0.056 (1.42)
PIN (1)
IDENTIFIER
0.004 (0.10)
0.050 (1.27) TP
0.025 (0.64)
R
0.045 (1.14)
ND
CL
C
D2/E2
C
L
E1 E
D2/E2
NE
VIEW “A”
A1
A
D1
D
0.015 (0.38)
MIN
SEATING
-C- PLANE
0.020 (0.51) MAX
3 PLCS
0.026 (0.66)
0.032 (0.81)
0.050 (1.27)
MIN
(JEDEC MS-016AE ISSUE A)
32 LEAD PLASTIC LEADED CHIP CARRIER PACKAGE
INCHES
MILLIMETERS
SYMBOL
MIN
MAX
MIN
MAX
NOTES
A
0.125
0.140
3.18
3.55
-
A1
0.060
0.095
1.53
2.41
-
D
0.485
0.495
12.32
12.57
-
D1
0.447
0.453
11.36
11.50
3
D2
0.188
0.223
4.78
5.66
4, 5
E
0.585
0.595
14.86
15.11
-
E1
0.547
0.553
13.90
14.04
3
E2
0.238
0.273
6.05
6.93
4, 5
N
28
28
6
ND
7
7
7
NE
9
9
7
Rev. 0 7/98
NOTES:
1. Controlling dimension: INCH. Converted millimeter dimensions are not necessarily exact.
2. Dimensions and tolerancing per ANSI Y14.5M-1982.
0.013 (0.33)
0.021 (0.53)
0.025 (0.64)
MIN
(0.12)
M A S -B S D S
0.005
VIEW “A” TYP.
3. Dimensions D1 and E1 do not include mold protrusions. Allowable mold protrusion is 0.010 inch (0.25mm) per side.
Dimensions D1 and E1 include mold mismatch and are measured at the extreme material condition at the body parting
line.
4. To be measured at seating plane -C- contact point.
5. Centerline to be determined where center leads exit plastic
body.
6. “N” is the number of terminal positions.
7. ND denotes the number of leads on the two shorts sides of the
package, one of which contains pin #1. NE denotes the number of leads on the two long sides of the package.
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36