Datasheet CPC7582BB-TR, CPC7582BB, CPC7582BA-TR, CPC7582BA Datasheet (CPCLA)

Part # Description

CPC7582BA 6 Pole with protection SCR
CPC7582BB 6 Pole without protection SCR
CPC7582BA-TR Tape & Reel Version
CPC7582BB-TR Tape & Reel Version

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DS-CPC7582-R1.0

CPC7582

Line Card Access Switch

1

Applications

Features

Description

Ordering Information

The CPC7582 is a monolithic solid state switch in a 16
pin surface mount SOIC package. It provides the nec­essary functions to replace two 2-Form-C electro­mechanical relays on analog line cards found in
Central Office, Access and PBX equipment. The
device contains solid state switches for tip and ring line
break, ring injection/ring return and line test access.
The CPC7582 requires only a +5V supply and offers
“break-before-make” or “make-before-break” switch
operation using simple logic level input control. There
are two versions of the CPC7582, the CPC7582BA
and the CPC7582BB. The “BA” version has a protec­tion SCR which provides protection to the SLIC device
and subsequent circuitry during fault conditions.

• Central office (CO)

• Digital Loop Carrier (DLC)

• PBX Systems

• Digitally Added Main Line (DAML)

• Hybrid Fiber Coax (HFC)

• Fiber in the Loop (FITL)

• Pair Gain System

• Channel Banks

• Small 16 pin surface mount SOIC package

• Monolithic IC reliability

• Low matched RDS

ON

• Eliminates the need for zero cross switching

• Flexible switch timing to transition from ringing mode

to idle/talk mode.

• Clean, bounce free switching

• Tertiary protection consisting of integrated current

limiting, thermal shutdown and SLIC protection

• 5V operation with power consumption <10mW

• Intelligent battery monitor

• Latched logic level inputs, no drive circuitry

• Pin to pin compatible to the Lucent 7582 family

Block Diagram

R1

R2

Ring

TIP

Secondary
Protection

SW1

Break

SW2

Break

SW3

Ringing

Return

SW5

Line Test

Access

SW6

Line Test

Access

SW4
Ringing
Access

SCR

and Trip

Circuit

SLIC

Ring Generator

V

BAT

Reference

CPC7582BA

Battery

+

-

T

ACCESS

(5)

T

RING

(4)

T

LINE

R

LINE

(3)

(14)

R

ACCESS

(12)

R

RING

(13)

R

BAT

(15)

T

BAT

(2)

(16)

Table 1. Break Switch, SW1 and SW2

Parameters Conditions Symbol Min Typ Max Units

Off-state Leakage Current:
+25˚C Vsw (differential)= -320V to Gnd Isw - 0.1 1 µA

Vsw (differential)= -60V to +260V

+85˚C Vsw (differential)= -330V to Gnd Isw - 0.3 1 µA

Vsw (differential)= -60V to +270V

-40˚C Vsw (differential)= -310V to Gnd Isw - 0.1 1 µA
Vsw (differential)= -60V to +250V

RDSON(SW1,SW2):
+25˚C T

LINE

= +/-10 mA, +/-40mA, T

BAT

= -2V ∆ V - 14.5 - Ω

+85˚C T

LINE

= +/-10 mA, +/-40mA, T

BAT

= -2V ∆ V - 20.5 28 Ω

-40˚C T

LINE

= +/-10 mA, +/-40mA, T

BAT

= -2V ∆ V - 10.5 - Ω

RDS

ON

Match Per ON-resistance Test Condition of Magnitude - 0.15 0.8 Ω

SW1, SW2RONSW1-RONSW2

dc Current Limit:
+25˚C Vsw(on) = +/- 10V lsw - 300 - mA
+85˚C Vsw(on) = +/- 10V lsw 80 160 - mA

-40˚C Vsw(on) = +/- 10V lsw - 400 425 mA

Dynamic Current Limit: Break switches in ON state, Ringing Isw - 2.5 - A

(t=<0.5µs) access switches OFF, Apply +/- 1000V

at 10/1000ms pulse, Appropriate
secondary protection in place.

ESD Rating (HBM)

1000V

Power Supply Specifications

Supply Min Typ Max Unit

V

DD

+4.5 +5.0 +5.5 V

V

BAT

1

-19 - -72 V

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2

CPC7582

Rev. 1.0

Absolute Maximum Ratings are stress ratings. Stresses in
excess of these ratings can cause permanent damage to
the device. Functional operation of the device at these or
any other conditions beyond those indicated in the opera­tional sections of this data sheet is not implied. Exposure of
the device to the absolute maximum ratings for an extend­ed period may degrade the device and effect its reliability.

Absolute Maximum Ratings (@ 25˚ C)

Electrical Characteristics TA = -40oC to +85oC

(unless otherwise specified)

Minimum and maximum values are production testing
requirements. Typical values are characteristic of the
device and are the result of engineering evaluations.
Typical values are provided for information purposes
only and are not part of the testing requirements.

1

V

BAT

is used only as a reference for internal protection circuitry.

If V

BAT

rises above -10V, the device will enter an all off state and will remain in the all off state

until the battery voltage drops below -15V.

Parameter Min Max Units

Operating Temperature Range -40 +110 ˚C
Storage Temperature Range -40 +150 ˚C
Relative Humidity Range 5 95 %
Pin Soldering Temperature - +260 ˚C

(t=10 s max)
+5V Power Supply - 7 V
Battery Supply - -85 V
Logic Input Voltage - 7 V
Logic Input to Switch Output Isolation - 330 V
Switch Isolation (SW1, SW2, SW3, SW5, SW6) - 330 V
Switch Isolation

(SW4) -

480 V

CPC7582

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3

Rev. 1.0

Table 1. Break Switch, SW1 and SW2 (Continued)

Parameters Conditions Symbol Min Typ Max Units

Logic Input to Switch Output Isolation:
+25˚C Vsw (T

LINE

, R

LINE

) = +/-320V Isw - 0.1 1 µA

Logic Inputs = Gnd

+85˚C Vsw (T

LINE

, R

LINE

) = +/-330V Isw - 0.3 1 µA

Logic Inputs = Gnd

-40˚C Vsw (T

LINE

, R

LINE

) = +/-310V Isw - 0.1 1 µA

Logic Inputs = Gnd

dv/dt Sensitivity

1

- - - 200 - V/µs

1

Applied voltage is 100 Vp-p square wave at 100Hz.

Table 2. Ring Return Switch, SW3

Parameters Conditions Symbol Min Typ Max Units

Off-state Leakage Current
+25˚C Vsw (differential)= -320V to Gnd Isw - 0.1 1 µA

Vsw (differential)= -60V to +260V

+85˚C Vsw (differential)= -330V to Gnd Isw - 0.3 1 µA

Vsw (differential)= -60V to +270V

-40˚C Vsw (differential)= -310V to Gnd Isw - 0.1 1 µA
Vsw (differential)= -60V to +250V

dc Current Limit:
+25˚C Vsw (on) = +/- 10V Isw - 135 - mA
+85˚C Vsw (on) = +/- 10V Isw - 85 - mA

-40˚C Vsw (on) = +/- 10V Isw - 210 - mA

Dynamic Current Limit: Break switches in ON state, Ringing Isw - 2.5 - A

(t=<0.5ms) access switches OFF, Apply +/- 1000V

at 10/1000ms pulse, Appropriate
secondary protection in place.

RDS

ON

+25˚C Isw (on) = +/-0mA, +/-10mA ∆ V-60-Ω
+85˚C Isw (on) = +/-0mA, +/-10mA ∆ V - 85 100 Ω

-40˚C Isw (on) = +/-0mA, +/-10mA ∆ V-45-Ω

Logic Input to Switch Output Isolation
+25˚C Vsw (T

RING

, T

LINE

) = +/-320V Isw - 0.1 1 µA

Logic Inputs = Gnd

+85˚C Vsw (T

RING

, T

LINE

) = +/-330V Isw - 0.3 1 µA

Logic Inputs = Gnd

-40˚C Vsw (T

RING

, T

LINE

) = +/-310V Isw - 0.1 1 µA

Logic Inputs = Gnd

Table 4. Loop Access Switches, SW5 and SW6

Parameters Conditions Symbol Min Typ Max Units

Off-state Leakage Current
+25˚C Vsw (differential)= -320V to Gnd Isw - 0.1 1 µA

Vsw (differential)= -60V to +260V

+85˚C Vsw (differential)= -330V to Gnd Isw - 0.3 1 µA

Vsw (differential)= -60V to +270V

-40˚C Vsw (differential)= -310 to Gnd Isw - 0.1 1 µA
Vsw (differential)= -60V to +250V

DC Current Limit:
+25˚C Vsw (on) = +/- 10V Isw - 175 - mA
+85˚C Vsw (on) = +/- 10V Isw 80 110 - mA

-40˚C Vsw (on) = +/- 10V Isw - 210 250 mA

Dynamic Current Limit: Break switches in ON state, Ringing Isw - 2.5 - A

(t=<0.5µs) access switches OFF, Apply +/- 1000V

at 10/1000ms pulse, Appropriate
secondary protection in place.

RDSON:
+25˚C Isw (on) = +/-10 mA, +/-40mA ∆ V-38-Ω
+85˚C Isw (on) = +/-10 mA, +/-40mA ∆ V - 46 70 Ω

-40˚C Isw (on) = +/-10 mA, +/-40mA ∆ V-28-Ω

Logic Input to Switch Output Isolation:
+25˚C Vsw (T

ACCESS

, T

LINE

) = +/-320V Isw - 0.1 1 µA

Logic Inputs = Gnd

+85˚C Vsw (T

ACCESS

, T

LINE

) = +/-330V Isw - 0.3 1 µA

Logic Inputs = Gnd

-40˚C Vsw (T

ACCESS

, T

LINE

) = +/-310V Isw - 0.1 1 µA

Logic Inputs = Gnd

Table 3. Ringing Access Switch, SW4

Parameters Conditions Symbol Min Typ Max Units

Off-state Leakage Current
+25˚C Vsw (differential)= -255V to +210V Isw - 0.05 1 µA

Vsw (differential)= +255V to -210V

+85˚C Vsw (differential)= -270V to +210V Isw - 0.1 1 µA

Vsw (differential)= +270V to -210V

-40˚C Vsw (differential)= -245V to +210V Isw - .05 1 µA
Vsw (differential)= +245V to -210V

ON Voltage Isw (on) = +/- 1mA - - 1.5 3 V
Ring Generator Current Vcc = 5V, INaccess = 0 I

R

- 0.1 0.25 mA

During Ring
Surge Current - - - - 2 A
Release Current - - - 300 - µA
RDS

ON

Isw (on) = +/-70mA, +/-80mA ∆ V - 8.5 12 Ω
Logic Input to Switch Output Isolation:
+25˚C Vsw (R

RING

, R

LINE

) = +/-320V Isw - .05 1 µA

Logic Inputs = Gnd
+85˚C Vsw (R

RING

, R

LINE

) = +/-330V Isw - 0.1 1 µA

Logic Inputs = Gnd

-40˚C Vsw (R

RING

, R

LINE

) = +/-310V Isw - .05 1 µA

Logic Inputs = Gnd

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4

CPC7582

Rev. 1.0

Table 6. Make-Before-Break Operation (Ringing to Idle/Talk Transition)

Ring Ring

Break Return Access Line Access

Switches Switch Switch Switches

Access Input TSD State Timing 1 & 2 3 4 5 & 6

0V 5V Float Ringing - Open Closed Closed Open
0V 0V Float Make-before-break SW4 waiting for next zero current Closed Open Closed Open

crossing to turn off. Maximum
time is one half of ringing. In this
transition state, current that is
limited to the dc break switch
current limit value will be sourced
from the ring node of the SLIC

0V 0V Float Idle / Talk Zero cross current has occurred Closed Open Open Open

Table 5. Additional Electrical Characteristics

Parameters Conditions Symbol Min Typ Max Units

Digital Input Characteristics

Input Low Voltage - - - - 1.5 V
Input High Voltage - - 3.5 - - V
Input Leakage Current (High) V

DD

= 5.5V, V

BAT

= -75V, I

log

- 0.1 1 µA

V

log

= 5V

Input Leakage Current (Low) V

DD

= 5.5V, V

BAT

= -75V, I

log

- 0.1 1 µA

V

log

= 0V

Power Requirements

Power Dissipation VDD= 5V, V

BAT

= -48V,

Idle/Talk State or All Off State IDD, I

BAT

- 5.5 7.5 mW

Ringing State or Access State I

DD

- 6.5 10 mW

VDDCurrent VDD= 5V,

Idle/Talk State or All Off State I

DD

- 1.1 1.5 mA

Ringing State or Access State I

DD

- 1.3 1.9 mA

V

BAT

Current V

BAT

= -48V,

Idle/Talk State or All Off State I

BAT

- 0.1 10 µA

Ringing State or Access State I

BAT

- 0.1 10 µA

Temperature Shutdown Requirements

1

Shutdown Activation Temperature - - 110 125 150 ˚C
Shutdown Circuit Hysteresis - - 10 - 25 ˚C

1

Temperature shutdown flag (TSD) will be high during normal operation and low during temperature shutdown state.

CPC7582

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5

Rev. 1.0

Table 7. Break-Before-Make Operation (Ringing to Idle/Talk Transition)

Ring Ring

Break Return Access Line Access

Switches Switch Switch Switches

Access Input TSD State Timing 1 & 2 3 4 5 & 6

0V 5V Float Ringing - Open Closed Closed Open
5V 5V Float All Off Hold this state for <= 25ms. Open Open Closed Open

SW4 waiting for zero current to
turn off.

5V 5V Float All Off Zero current has occurred. Open Open Open Open

SW4 has opened.

0V 0V Float Idle/Talk Release Break Switches Closed Open Open Open

Alternate “Break-Before-Make” Operation

Note that the “break-before-make” operation can also be achieved using TSD as an input. In lines 2 & 3 of Table 7,
instead of using the logic input pins to force the “all off” state, force TSD to ground. This will override the logic inputs
and also force the all off state. Hold this state for 25 ms. During this 25 ms all off state, toggle the inputs from the
ringing state (Input=5V, Access=0V) to the idle/talk state (Input=0V, Access=0V). After 25 ms, release TSD to return
switch control to the input pins which will set the idle talk state.

When using the CPC7582 in this mode, forcing TSD to ground will override the INPUT pins and force an all off state.
Setting TSD to +5V will allow switch control via the logic INPUT pins. However, setting TSD to +5V will also disable
the thermal shutdown mechanism. This is not recommended. Therefore, to allow switch control via the logic INPUT
pins, allow TSD to float.

Thus when using TSD as an input, the two recommended states are 0 (overrides logic input pins and forces all off
state) and float (allows switch control via logic input pins and thermal shutdown mechanism is active). This may
require use of an open collector buffer.

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CPC7582

Rev. 1.0

Table 8. Electrical Specifications, Protection Circuitry

Parameters Conditions Symbol Min Typ Max Units

Parameters Related to Diodes

(in Diode Bridge)

Voltage Drop @ Continuous Apply +/-dc current limit of break Forward - 2.1 3 V

Current (50/60 Hz) switches Voltage

Voltage Drop @ Surge Apply +/-dynamic current limit of Forward - 5 - V

Current break switches Voltage

Parameters Related to

Protection SCR

1

Surge Current - - - - * A
Trigger Current (+25˚C) - I

TRIG

-60 - mA

Hold Current (+25˚C) - I

HOLD

- 100 - mA

Trigger Current (+85˚C) - I

TRIG

-35 - mA

Hold Current (+85˚C) I

HOLD

60 70 - mA

Gate Trigger Voltage Trigger Current - V

BAT

- 4 - V

BAT

- 2 V

Reverse Leakage Current V

BAT

- - - 1.0 µA

ON State Voltage

1

0.5A t = 0.5 ms V

on

--3 - V

2.0A t = 0.5 ms - - -5 - V

1

Only for the CPC7581BA.

* Passes GR1089 & ITU-T K.20 with appropriate secondary protection in place.

Pin Name Function

1F

GND

Fault ground

2T

BAT

Connect to TIP on SLIC side

3T

LINE

Connect to TIP on line side

4T

RING

Connect to return ground for ringing

generator

5T

ACCESS

Test access

6VDD+5V supply

7 TSD Temperature shutdown pin. Can be

used as a logic level input or output.
See Tables 6, 7 and 9 for more
details. As an output, will read +5V
when device is in its operational mode
and 0V in the thermal shutdown mode.
To disable the thermal shutdown
mechanism, tie this pin to +5V
(NOT Recommended).

8D

GND

Digital ground

9IN

ACCESS

Logic level switch control

10 IN

RING

Logic level input switch control

11 LATCH Data latch control, active high,

transparent low

12 R

ACCESS

Test access

13 R

RING

Connect to ringing generator

14 R

LINE

Connect to RING on line side

15 R

BAT

Connect to RING on SLIC side

16 V

BAT

Battery voltage. Used as a reference
for protection circuit

Table 9. Truth Table

Input Access TSD Tip Break Ring Ringing Ring Tip Ring

Switch Break Return Switch Access Access

Switch Switch Switch Switch

0V 0V 5V/Float

5

On On Off Off Off Off

1

5V 0V 5V/Float

5

Off Off On On Off Off

2

0V 5V 5V/Float

5

Off Off Off Off On On

3

5V 5V 5V/Float

5

Off Off Off Off Off Off

4

Don’t Don’t 0V

6

Off Off Off Off Off Off

4

Care Care

1

Idle/Talk State

2

Power Ringing State

3

Test out message waiting state.

4

All OFF State

5

If TSD = 5V, the thermal shutdown mechanism is disabled.

If TSD if floating, the thermal shutdown mechanism is active.

6

Forcing TSD to ground overrides the logic input pins and forces an all off state.

CPC7582

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7

Rev. 1.0

CPC7582

1

2

3

4

16

15

14

13

5

6

7

8

T

BAT

12

11

10

9

SCR
and
Tri p

Circuit

SW3

SW5

SW1

SW4

SW6

SW2

Control Logic

F

GND

T

LINE

T

RING

T

ACCESS

V

DD

TSD

D

GND

V

BAT

R

BAT

R

LINE

R

RING

R

ACCESS

LATCH

IN

RING

IN

ACCESS

Package Pinout

* Only the CPC7582BA contains the protection SCR.

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8

CPC7582

Rev. 1.0

Functional Description
Introduction

The CPC7582 has four states:

• Idle/talk state (line break switches SW1, and SW2

closed, ringing switches SW3, SW4 open and loop
access switches SW5, SW6 open),

• Ringing state (line break switches SW1, and SW2

open, ringing switches SW3, SW4 closed and loop
access switches SW5, SW6 open)

• Loop access (line break switches SW1, and SW2

open, ringing switches SW3, SW4 open and loop
access switches SW5, SW6 closed)

• All Off state (line break switches SW1, and SW2

open, ringing switches SW3, SW4 open and loop
access switches SW5, SW6 open)

The CPC7582 offers break-before-make and make­before-break switching with simple logic level input con­trol. Solid state switch construction means no impulse
noise is generated when switching during ring cadence
or ring trip, thus eliminating the need for external “zero
cross” switching circuitry. State control is via logic level
input so no additional driver circuitry is required. The
line break switches SW1 and SW2 are linear switches
that have exceptionally low RDSONand excellent
matching characteristics. The ringing access switch
SW4 has a breakdown voltage rating of >480V which is
sufficiently high, with proper protection, to prevent
breakdown in the presence of a transient fault condition
(i.e., passing the transient on to the ring generator).

Integrated into the CPC7582 is a diode bridge/SCR
clamping circuit, current limiting and thermal shut­down mechanism to provide protection to the SLIC
device during a fault condition. Positive and negative
surges are reduced by the current limiting circuitry and
steered to ground via diodes and the integrated SCR.
Power cross transients are also reduced by the cur­rent limiting and thermal shutdown circuits. Please
note that only the CPC7582BA has the integrated pro­tection SCR.

To protect the CPC7582 from an overvoltage fault
condition, use of a secondary protector is required.
The secondary protector must limit the voltage seen at
the tip and ring terminals to a level below the max
breakdown voltage of the switches. To minimize the
stress on the solid-state contacts, use of a foldback or
crowbar type secondary protector is recommended.
With proper selection of the secondary protector, a
line card using the CPC7582 will meet all relevant
ITU, LSSGR, FCC or UL protection requirements.

The CPC7582 operates from a +5V supply only. This
gives the device extremely low idle and active power

dissipation and allows use with virtually any range of
battery voltage. A battery voltage is also used by the
CPC7582 as a reference for the integrated protection
circuit. In the event of a loss of battery voltage, the
CPC7582 will enter an “all off” state.

Switch Timing

The CPC7582 provides, when switching from the ring­ing state to the idle/talk state, the ability to control the
timing when the ringing access switches SW3 and
SW4 are released relative to the state of the line break
switches SW1 and SW2 using simple logic level input.
This is referred to a “make before break” or “break
before make” operation. When the line break switch
contacts (SW1, SW2) are closed (or made) before the
ringing access switch contact (SW3, SW4) is opened
(or broken), this is referred to a ‘make-before-break’
operation. Break-before-make operation occurs when
the ringing access contact (SW3, SW4) is opened
(broken) before the line break switch contacts (SW1,
SW2) are closed (made). With the CPC7582 the
“make before break” and “break before make” opera­tions can easily be selected by applying logic level
inputs to pins 9 and 10 (IN

ring

and IN

access

) of the

device.

The logic sequences for either mode of operation are
given in Tables 6 and 7. Logic states and explanations
are given in Table 9.

Break-before make operation can also be achieved
using pin 7 (TSD) as an input. In table 7 lines 2 and 3
it is possible to induce the switches to “all off” by
grounding pin 7 (TSD) instead of apply logic input to
the pins. This has the effect of overriding the logic
inputs and forcing the device to the “all off” state. Hold
this input state for 25ms. During this hold period, tog­gle the inputs from the ringing state (10) to the idle/talk
state (00). After the 25ms release pin 7 (TSD) to return
the switch control to the input pins 9 and 10 and reset
the device to the idle/talk state.

Setting TSD to +5V will allow switch control using the
logic pins 9 and 10. This setting, however, will also dis­able the thermal shutdown circuit and is therefore not
recommended. When using logic controls via the input
pins 9 and 10, pin 7 (TSD) should be allowed to float.
As a result the two recommended states when using
pin 7 (TSD) as a control are 0 which forces the device
to the “all of state” or float which allows logic inputs to
pins 9 and 10 to remain active. This may require use
of an open collector buffer.

CPC7582

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9

Rev. 1.0

Ring Access Switch Zero Cross Current Turn Off

After the application of a logic input to turn SW4 off,
the ring access switch is designed to delay the change
in state until the next zero crossing. Once on, the
switch requires a zero current cross to turn off and
therefore should not be used to switch a pure DC sig­nal. The switch will remain in the on state no matter
what logic input until the next zero crossing. For prop­er operation, pin 13 (R

Ring

) should be connected using
proper impedance to a ring generator or other ac
source. These switching characteristics will reduce
and possibly eliminate overall system impulse noise
normally associated with ringing access switches. The
attributes of ringing access switch SW4 may make it
possible to eliminate the need for a zero cross switch­ing scheme. A minimum impedence of 300Ω in series
with the ring generator is recommended.

Power Supplies

Both a +5V supply and battery voltage are connected
to the CPC7582. CPC7582 switch state control is
powered exclusively by the +5V supply. As a result,
the CPC7582 exhibits extremely low power dissipa­tion during both active and idle states.

The battery voltage is not used for switch control but
rather as a reference by the integrated secondary pro­tection circuitry. The integrated SCR is designed to
trigger when pin 2 (T

BAT

) or pin 15 (R

BAT

) drops 2 to 4V
below the battery. This trigger prevents a fault induced
overvoltage event at the T

BAT

or R

BAT

nodes.

Battery Voltage Monitor

The CPC7582 also uses the voltage reference to mon­itor battery voltage. If battery voltage is lost, the
CPC7582 will immediately enter the “all off” state and
remain in this state until the battery voltage is restored.
The device will also enter the “all off” state if the battery
voltage rises above –10V and will remain there until the
battery voltage drops below –15V. This battery monitor
feature draws a small current from the battery (<1

µA

typ.) and will add slightly to the device’s overall power
dissipation.

Protection

Diode Bridge/SCR

The CPC7582 uses a combination of current limited
break switches, a diode bridge/SCR clamping circuit
and a thermal shutdown mechanism to protect the
SLIC device or other associated circuitry from damage
during line transient events such as lightning. During a

positive transient condition, the fault current is con­ducted through the diode bridge to ground. Voltage is
clamped to the diode drop above ground. During a
negative transient of 2 - 4 volts more negative than the
battery, the SCR conducts and faults are shunted to
ground via the SCR and diode bridge.

Also, in order for the SCR to crowbar or foldback, the
on voltage (see Table 8) of the SCR must be less neg­ative than the battery reference voltage. If the battery
voltage is less negative the SCR on voltage, the SCR
will not crowbar, however it will conduct fault currents to
ground.

For power induction or power cross fault conditions,
the positive cycle of the transient is clamped to the
diode drop above ground and the fault current direct­ed to ground. The negative cycle of the transient will
cause the SCR to conduct when the voltage exceeds
the battery reference voltage by two to four volts,
steering the current to ground.

Current Limiting function

If a lightning strike transient occurs when the device in
the talk/idle state, the current is passed along the line
to the integrated protection circuitry and limited by the
dynamic current limit response of break switches SW1
and SW2. When a 1000V 10x1000 pulse (LSSGR
lightning) is applied to the line though a properly
clamped external protector, the current seen at pins 2
(T

BAT

) and pin 15 (R

BAT

) will be a pulse with a typical

magnitude and duration of 2.5A and < 0.5ms.

If a power cross fault occurs with device in the talk/idle
state, the current is passed though the break switches
SW1 and SW2 on to the integrated protection circuit
and is limited by the dynamic DC current limit
response of the two break switches. The DC current
limit, specified over temperature, is between 80mA
and 425mA and the circuitry has a negative tempera­ture coefficient. As a result, if the device is subjected
to extended heating due to power cross fault, the
measured current at pin 2 (T

BAT

) and pin 15 (R

BAT

) will
decrease as the device temperature increases. If the
device temperature rises sufficiently, the temperature
shutdown mechanism will activate and the device will
default to the “all off” state.

Temperature Shutdown

The thermal shutdown mechanism will activate when
the device temperature reaches a minimum of 110°C
placing the device in the “all off” state regardless of
logic input. During this thermal shutdown mode, pin 7
(TSD) will read 0V. Normal output of TSD is +V

DD

www.clare.com

10

CPC7582

Rev. 1.0

If presented with a short duration transient such as a
lightning event, the thermal shutdown feature will not
typically activate. But in an extended power cross
transient, the device temperature will rise and the ther­mal shutdown will activate forcing the switches to an
“all off” state. At this point the current measured at pin
2 (T

BAT

) and pin 15 (R

BAT

) will drop to zero. Once the
device enters thermal shutdown it will remain in the
“all off” state until the temperature of the device drops
below the activation level of the thermal shutdown cir­cuit. This will return the device to the state prior to
thermal shutdown. If the transient has not passed,
current will flow at the value allowed by the dynamic
DC current limiting of the switches and heating will
begin again, reactivating the thermal shutdown mech­anism. This cycle of entering and exiting the thermal
shutdown mode will continue as long as the fault con­dition persists. If the magnitude of the fault condition is
great enough, the external secondary protector could
activate and shunt all current to ground.

The thermal shutdown mechanism of the CPC7582
can be disable by applying +VDDto pin 7 (TSD)

External Protection Elements

The CPC7582 requires only one overvoltage second­ary protector on the loop side of the device. The inte­grated protection feature described above negates the
need for protection on the line side. The purpose of
the secondary protector is to limit voltage transients to
levels that do not exceed the breakdown voltage or
input-output isolation barrier of the CPC7582. A fold­back or crowbar type protector is recommended to
minimize stresses on the device.

Consult Clare’s application note, AN-100, “Designing
Surge and Power Fault Protection Circuits for Solid
State Subscriber Line Interfaces” for equations related
to the specifications of external secondary protectors,
fused resistors and PTCs.

Data Latch

The CPC7582 has an integrated data latch. The latch
operation is controlled by logic level input pin 11
(LATCH). The data input of the latch is pin 10 (IN

RING

)

and pin 9 (IN

ACCESS

) of the device while the output of
the data latch is an internal node used for state con­trol. When LATCH control pin is at logic 0, the data
latch is transparent and data control signals flow
directly through to state control. A change in input will
be reflected in a change is switch state. When LATCH
control pin is at logic 1, the data latch is now active
and a change in input control will not affect switch

state. The switches will remain in the position they
were in when the LATCH changed from logic 0 to logic
1 and will not respond to changes in input as long as
the latch is at logic 1. In addition, TSD input is not tied
to the data latch. Therefore, TSD is not affected by
the LATCH input and TSD input will override state
control via pin 10 (IN

RING

) and pin 9 (IN

ACCESS

) and the

LATCH.

CPC7582

www.clare.com

11

Rev. 1.0

Dimensions

mm

(Inches)

MECHANICAL DIMENSIONS

7.40 MIN /

(.291 MIN /

0.23 MIN / 0.32 MAX

(.0091 MIN / .0125 MAX)

2.44 MIN / 2.64 MAX

(.096 MIN / .104 MAX)

0.51 MIN / 1.01 MAX

(.020 MIN / .040 MAX)

16 Pin SOIC (JEDEC Package)

7.40 MIN / 7.60 MAX

(.291 MIN / .299 MAX)

1.27

(.050)

10.11 MIN / 10.51 MAX
(.398 MIN / .414 MAX)

0.36 MIN / 0.46 MAX

(.014 MIN / .018 MAX)

10.11 MIN / 10.31 MAX
(.398 MIN / .406 MAX)

PC Board Pattern
(Top View)

1.193

(.047)

9.728 ± .051

(.383 ± .002)

.787

(.031)

1.270
(.050)

Clare, Inc. makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication and reserves the right to make changes to specifications and product descriptions
at any time without notice. Neither circuit patent licenses nor indemnity are expressed or implied. Except as set forth in Clare’s Standard Terms and Conditions of Sale, Clare, Inc. assumes no liability whatsoever, and
disclaims any express or implied warranty, relating to its products including, but not limited to, the implied warranty of merchantability, fitness for a particular purpose, or infringement of any intellectual property right.

The products described in this document are not designed, intended, authorized or warranted for use as components in systems intended for surgical implant into the body, or in other applications intended to sup­port or sustain life, or where malfunction of Clare’s product may result in direct physical harm, injury, or death to a person or severe property or environmental damage. Clare, Inc. reserves the right to discontinue or
make changes to its products at any time without notice.

Specification: DS-CPC7582BA-R1.0
©Copyright 2001, Clare, Inc.
All rights reserved. Printed in USA.
9/20/01

For additional information please visit our website at: www.clare.com