Agere ATTL7581AAE-TR Ringing access switch Datasheet

Data Sheet
November 1999
L7581 Ringing Access Switch
Features
■
Small size/surface-mount packaging
■
Monolithic IC reliability
■
Low impulse noise
■
Make-before-break, break-before-make operation
■
Clean, bounce-free switching
■
Low, matched ON-resistance
■
Built-in current limiting, thermal shutdown, and
SLIC protection
■
5 V only operation, very low power consumption
■
Battery monitor, all OFF state upon loss of battery
■
No EMI
■
Latched logic level inputs, no drive circuitry
■
Only one external protector required
Applications
■
Central office
■
DLC
■
PBX
■
DAML
■
HFC/FITL
Description
The L7581 Ringing Access Switch is a monolithic
solid-state device that provides the switching functionality of a 2 form C switch.
The L7581 is designed to provide power ringing
access to tip and ring in central office, digital loop
carrier, private branch exchange, digitally added
main line, and hybrid fiber coax/fiber-in-the-loop analog line card applications. The L7581 has three
states: the idle talk state (line break switches closed,
ringing access switches open), the power ringing
state (line break switches open, ringing access
switches closed), and an all OFF state.
The L7581 offers break-before-make or make-beforebreak switching, with simple logic level input control.
Because of the solid-state construction, voltage transients generated when switching into an inductive
ringing load during ring cadence or ring trip are minimized, possibly eliminating the need for external zero
cross switching circuitry. State control is via logic
level inputs, so no additional driver circuitry is
required.
The line break switch is a linear switch that has
exceptionally low ON-resistance and an excellent
ON-resistance matching characteristic. The ringing
access switch has a breakdown voltage rating
>480 V 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 ringing generator).
Incorporated into the L7581Axx is a diode bridge/
SCR clamping circuit, current-limiting circuitry, and a
thermal shutdown mechanism to provide protection
to the SLIC device and subsequent circuitry during
fault conditions (see Figure 1). Positive and negative
lightning is reduced by the current-limiting circuitry
and steered to ground via diodes and the integrated
SCR. Power cross is also reduced by the currentlimiting and thermal shutdown circuits.
The L7581Bxx version provides only an integrated
diode bridge along with current limiting and thermal
shutdown, as shown in Figure 2. This will cause positive faults to be directed to ground and negative
faults to battery. In either polarity, faults are reduced
by the current-limit and/or thermal shutdown mechanisms.
Data Sheet
November 1999
L7581 Ringing Access Switch
Description (continued)
To protect the L7581 from an overvoltage fault condition, use of a secondary protector is required. The secondary protector must limit the voltage seen at the tip/
ring terminals to prevent the breakdown voltage of the
switches from being exceeded. To minimize stress on
the solid-state contacts, use of a foldback- or crowbartype secondary protector is recommended. With proper
choice of secondary protection, a line card using the
L7581 will meet all relevant ITU-T, LSSGR, FCC, or
UL* protection requirements.
The L7581 operates off of a 5 V supply only. This gives
the device extremely low idle and active power dissipation and allows use with virtually any range of battery
voltage. This makes the L7581 especially appropriate
for remote power applications such as DAML or FOC/
FITL or other Bellcore TA 909 applications where
power dissipation is particularly critical.
Pin Information
SCR
AND
TRIP
CKT
FGND
1
NC
2
TBAT
3
TLINE
4
TRINGING
5
VDD
6
11 LATCH
NC
7
10 INPUT
TSD
8
16 VBAT
15 NC
SW2
SW1
14 RBAT
13 RLINE
SW3
SW4
12 RRINGING
TEMPERATURE
SHUTDOWN
9
A battery voltage is also used by the L7581, only as a
reference for the integrated protection circuit. The
L7581 will enter an all OFF state upon loss of battery.
During power ringing, to turn on and maintain the ON
state, the ring access switch will draw a nominal 2 mA
or 4 mA from the ring generator.
DGND
12-2306.a (C)
Note: Shown with A version protection. The 16-pin DIP is available
with either A or B version protection.
Figure 1. 16-Pin, Plastic DIP
The L7581 device is packaged in a 16-pin, plastic DIP
package (L7581AC/BC) and a 16-pin, plastic SOG
package (L7581AAE/BAE). These devices are pin
compatible with the L7541 device.
* UL is a registered trademark of Underwriters Laboratories, Inc.
FGND
1
TBAT
2
16 VBAT
15 RBAT
SW1
TLINE
3
NC
4
NC
5
12 RRINGING
TRINGING
6
11 LATCH
VDD
7
10 INPUT
TSD
8
SW2
SW3
SW4
TEMPERATURE
SHUTDOWN
14 RLINE
13 NC
9
DGND
12-2307.a (F)
Note: Shown with B version protection. The 16-pin SOG is available
with either A or B version protection.
Figure 2. 16-Pin, Plastic SOG
2
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Pin Information (continued)
Table 1. Pin Descriptions
DIP SOG
1
1
Symbol
FGND
2
3
4
5
4
2
3
6
NC
TBAT
TLINE
TRINGING
6
7
VDD
7
8
5
8
NC
TSD
Description
Fault ground.
DIP SOG
16
16
Symbol
VBAT
No connection.
Connect to TIP on SLIC side.
Connect to TIP on line side.
Connect to return ground for
ringing generator.
5 V supply.
15
14
13
12
13
15
14
12
NC
RBAT
R LINE
RRINGING
11
11
LATCH
No connection.
10
9
Temperature shutdown pin. Can
be used as a logic level input or
output. See Table 12, Truth
Table, and the Switching Behavior section of this data sheet for
input pin description. As an output, will read 5 V when device is
in its operational mode and 0 V
in the thermal shutdown mode.
In the L7581, the thermal shutdown mechanism cannot be disabled.
10
9
INPUT
DGND
Description
Battery voltage. Used as a reference for protection circuit.
No connection.
Connect to RING on SLIC side.
Connect to RING on line side.
Connect to ringing generator.
Data latch control, active-high,
transparent low.
Logic level input switch control.
Digital ground.
Absolute Maximum Ratings
Handling Precautions
Stresses in excess of the absolute maximum ratings
can cause permanent damage to the device. These are
absolute stress ratings only. Functional operation of the
device is not implied at these or any other conditions in
excess of those given in the operational sections of the
data sheet. Exposure to absolute maximum ratings for
extended periods can adversely affect device reliability.
Although protection circuitry has been designed into
this device, proper precautions should be taken to
avoid exposure to electrostatic discharge (ESD) during
handling and mounting. Lucent Technologies Microelectronics Group employs a human-body model
(HBM) and a charged-device model (CDM) for ESDsusceptibility testing and protection design evaluation.
ESD voltage thresholds are dependent on the circuit
parameters used to define the model. No industry-wide
standard has been adopted for CDM. However, a standard HBM (resistance = 1500 Ω, capacitance = 100 pF)
is widely used and therefore can be used for comparison purposes. The HBM ESD threshold presented
here was obtained by using these circuit parameters.
Table 2. Absolute Maximum Ratings Parameters
Parameter
Min
Max
Unit
Operating Temperature Range
Storage Temperature Range
Relative Humidity Range
Pin Soldering Temperature
5 V Power Supply
Battery Supply
Logic Input Voltage
Input-to-output Isolation
Pole-to-pole Isolation
–40
–40
5
—
—
—
—
—
—
110
150
95
10
7
–85
7
330
330
°C
°C
%
°C
V
V
V
V
V
Lucent Technologies Inc.
Table 3. HBM ESD Threshold Voltage
Device
L7581
Rating
1000 V
3
Data Sheet
November 1999
L7581 Ringing Access Switch
Electrical Characteristics
TA = –40 °C to +85 °C, unless otherwise specified.
Minimum and maximum values are testing requirements. Typical values are characteristics of the device and are
the result of engineering evaluations. Typical values are for information purposes only and are not part of the testing requirements.
Table 4. Power Supply Specifications
Supply
VDD
VBAT*
Min
4.5
–19
Typ
5
—
Max
5.5
–72
Unit
V
V
* VBAT is used only as a reference for internal protection circuitry. If VBAT rises above –10 V, the device will enter an all OFF state and remain in
this state until the battery voltage drops below –15 V.
Table 5. Break Switches, 1 and 2
Parameter
OFF-state Leakage
Current:
+25 °C
+85 °C
–40 °C
ON-resistance
(SW1, SW2):
+25 °C
+85 °C
–40 °C
ON-resistance Match
ON-state Voltage*
dc Current Limit:
+85 °C
–40 °C
Dynamic Current Limit
(t = <0.5 µs)
Isolation:
+25 °C
+85 °C
–40 °C
dV/dt Sensitivity†
Test Condition
Measure
Min Typ Max
Unit
Vswitch (differential) = –320 V to Gnd
Vswitch (differential) = –60 V to +260 V
Vswitch (differential) = –330 V to Gnd
Vswitch (differential) = –60 V to +270 V
Vswitch (differential) = –310 V to Gnd
Vswitch (differential) = –60 V to +250 V
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
TLINE = ±10 mA, ±40 mA, TBAT = –2 V
TLINE = ±10 mA, ±40 mA, TBAT = –2 V
TLINE = ±10 mA, ±40 mA, TBAT = –2 V
Per ON-resistance test
condition of SW1, SW2
Iswitch = ILIMIT @ 50 Hz/60 Hz
∆ VON
∆ VON
∆ VON
Magnitude
RON SW1 – RON SW2
VON
—
—
—
—
19.5
—
14.5
0.2
—
28
—
1.0
Ω
Ω
Ω
Ω
—
—
220
V
Vswitch (on) = ±10 V
Vswitch (on) = ±10 V
Break switches in ON state; ringing
access switches off; apply ±1000 V at
10/1000 µs pulse; appropriate secondary protection in place
Iswitch
Iswitch
Iswitch
80
—
—
—
—
2.5
—
250
—
mA
mA
A
Vswitch (both poles) = ±320 V,
Logic inputs = Gnd
Vswitch (both poles) = ±330 V,
Logic inputs = Gnd
Vswitch (both poles) = ±310 V,
Logic inputs = Gnd
—
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
—
—
200
—
V/µs
* This parameter is not tested in production. Choice of secondary protector should ensure this rating is not exceeded.
† Applied voltage is 100 Vp-p square wave at 100 Hz.
4
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Electrical Characteristics (continued)
Table 6. Ring Return Switch, 3
Parameter
OFF-state Leakage
Current (SW3):
+25 °C
+85 °C
–40 °C
dc Current Limit
Dynamic Current
Limit (t = <0.5 µs)
ON-resistance
ON-state Voltage*
Isolation:
+25 °C
+85 °C
–40 °C
Test Condition
Vswitch (differential) = –320 V to Gnd
Vswitch (differential) = –60 V to +260 V
Vswitch (differential) = –330 V to Gnd
Vswitch (differential) = –60 V to +270 V
Vswitch (differential) = –310 V to Gnd
Vswitch (differential) = –60 V to +250 V
Vswitch (on) = ±10 V
Break switches in ON state; ringing access switches
off; apply ±1000 V at 10/1000 µs pulse; appropriate
secondary protection in place
Iswitch (on) = 0 mA, ±10 mA
Iswitch = ILIMIT @ 50 Hz/60 Hz
dV/dt Sensitivity†
Vswitch (both poles) = ±320 V, Logic inputs = Gnd
Vswitch (both poles) = ±330 V, Logic inputs = Gnd
Vswitch (both poles) = ±310 V, Logic inputs = Gnd
—
Measure Min Typ Max Unit
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
Iswitch
Iswitch
—
—
200
2.5
—
—
mA
A
∆ VON
VON
—
—
—
—
100
130
Ω
V
Iswitch
Iswitch
Iswitch
—
—
—
—
—
—
—
—
200
1
1
1
—
µA
µA
µA
V/µs
* This parameter is not tested in production. Choice of secondary protector should ensure this rating is not exceeded.
† Applied voltage is 100 Vp-p square wave at 100 Hz.
Table 7. Ringing Access Switch, 4
Parameter
OFF-state Leakage
Current (SW3):
+25 °C
+85 °C
–40 °C
Test Condition
Measure
Vswitch (differential) = –255 V to +210 V
Vswitch (differential) = +255 V to –210 V
Vswitch (differential) = –270 V to +210 V
Vswitch (differential) = +270 V to –210 V
Vswitch (differential) = –245 V to +210 V
Vswitch (differential) = +245 V to –210 V
Iswitch (on) = ±70 mA, ±80 mA
Iswitch (on) = ± 1 mA
VCC = 5 V
INPUT = 1
—
—
—
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
Iswitch
—
—
1
µA
—
—
—
—
—
*
12
3
—
Ω
V
mA
—
—
—
—
—
500
150
2
—
mA
A
µA
—
—
—
—
—
—
—
200
1
1
1
—
µA
µA
µA
V/µs
ON-resistance
∆ VON
ON Voltage
—
IRINGSOURCE
Ring Generator Current
During Ring
Steady-state Current†
—
Surge Current†
—
Release Current
—
Isolation:
Iswitch
Vswitch (both poles) = ±320 V, Logic inputs = Gnd
+25 °C
Iswitch
Vswitch (both poles) = ±330 V, Logic inputs = Gnd
+85 °C
Iswitch
Vswitch (both poles) = ±310 V, Logic inputs = Gnd
–40 °C
‡
—
—
dV/dt Sensitivity
Min Typ Max Unit
* At the time of publication of this data sheet, the current device design will be a nominal 4 mA. Devices are being redesigned to reduce this
current to less than 2 mA nominally. Consult your Lucent Technologies Microelectronics Group account executive for additional details.
† Choice of secondary protector and series current-limit resistor should ensure these ratings are not exceeded.
‡ Applied voltage is 100 Vp-p square wave at 100 Hz.
Lucent Technologies Inc.
5
Data Sheet
November 1999
L7581 Ringing Access Switch
Electrical Characteristics (continued)
Table 8. Additional Electrical Characteristics
Parameter
Digital Input Characteristics:
Input Low Voltage
Input High Voltage
Input Leakage Current (high)
Input Leakage Current (low)
Power Requirements:
Power Dissipation
VDD Current
VBAT Current
Test Condition
Measure
Min
Typ
—
—
VDD = 5.5 V, VBAT = –75 V,
Vlogicin = 5 V
VDD = 5.5 V, VBAT = –75 V,
Vlogicin = 0 V
—
—
llogicin
—
3.5
—
—
—
—
1.5
—
1
V
V
µA
llogicin
—
—
1
µA
IDD, IBAT
IDD
—
—
3
6
5
10
mW
mW
IDD
IDD
—
—
560 900
0.750 1.9
µA
mA
IBAT
IBAT
—
—
4
4
10
10
µA
µA
—
—
110
10
125
—
150
25
°C
°C
VDD = 5 V, VBAT = –48 V,
Idle/talk state or all OFF state,
ringing state
VDD = 5 V,
Idle/talk state or all OFF state,
ringing state
VBAT = –48 V,
Idle/talk state or all OFF state,
ringing state
Temperature Shutdown Requirements:*
Shutdown Activation Temperature
Shutdown Circuit Hysteresis
—
—
Max Unit
* Temperature shutdown flag (TSD) will be high during normal operation and low during temperature shutdown state.
Zero Cross Current Turn Off
Switching Behavior
The ring access switch (SW4) is designed to turn off on
the next zero current crossing after application of the
appropriate logic input control. This switch requires a
current zero cross to turn off. Switch 4, once on, will
remain in the ON state (regardless of logic input) until a
current zero cross. Therefore, to ensure proper operation of switch 4, this switch should be connected, via
proper impedance, to the ringing generator or some
other ac source. Do not attempt to switch pure dc with
switch 4.
When switching from the power ringing state to the idle/
talk state via simple logic level input control, the L7581
is able to provide control with respect to the timing
when the ringing access contacts are released relative
to the state of the line break contacts.
For a detailed explanation of the operation of switch 4,
please refer to the An Introduction to L758X Series of
Line Card Access Switches Application Note.
6
Make-before-break operation occurs when the line
break switch contacts are closed (or made) before the
ringing access switch contact is opened (or broken).
Break-before-make operation occurs when the ringing
access contact is opened (broke) before the line break
switch contacts are closed (made).
Using the logic level input pins INPUT and TSD, either
make-before-break or break-before-make operation of
the L7581 is easily achieved. The logic sequences for
either mode of operation are given in Table 9 and Table
10. See the Truth Table (Table 12) for an explanation of
the logic states.
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Switching Behavior (continued)
When using an L7581 in the make-before-break mode,
during the ring-to-idle transition, for a period of up to
one-half the ringing frequency, the ring break switch
and the pnpn-type ring access switch can both be in
the ON state. This is the maximum time after the logic
signal at INRING has transitioned that the ring access
switch is waiting for the next zero current cross so it can
close. During this interval, current that is limited to the
dc break switch current-limit value will be sourced from
the ring node of the SLIC.
This current is presented to the internal protection circuit. If the SCR-type protector is used (A code), if by
random probability the ring-to-idle transition occurs
during a portion of the ring cycle when the ringing voltage exceeds the protection circuit SCR turn-on voltage,
and if current in excess of the SCR’s turn-on current is
also available, the SCR may turn on. Once the SCR is
triggered on, if the SLIC is capable of supplying current
in excess of the holding current, the SCR may be
latched on by the SLIC.
The probability of this event depends on the characteristics of the given SLIC and of the holding current of the
L7581A device. The SCR hold current distribution is
designed to be safely away from the test limit of 80 mA.
The higher the distribution, the lower the probability of
the latch.
If this situation is of concern for a given board design,
either use the A series device in the break-before-make
mode (eliminates the original 25 ms current pulse) or
use a B series device (eliminates the SCR).
Table 9. Make-Before-Break Operation
INPUT
TSD
5V
5 V/Float
0V
5 V/Float
0V
5 V/Float
State
Timing
Power
—
Ringing
Make- SW4 waiting for next zero current
before- crossing to turn off, maximum
break time—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.
Idle/Talk Zero cross current has occurred.
Break
Ring Return
Switches 1 & 2
Switch 3
Ring Access
Switch 4
Open
Closed
Closed
Closed
Open
Closed
Closed
Open
Open
Table 10. Break-Before-Make Operation
INPUT
TSD
State
Timing
5V
5 V/Float
—
5V
0V
Power
Ringing
All Off
0V
0V
0V
5 V/Float
Hold this state for ≤25 ms. SW4
waiting for zero current to turn off.
All Off Zero current has occurred and
SW4 has opened. Transition on
INPUT should occur during 25 ms
hold.
Idle/Talk Release break switch pair.
Lucent Technologies Inc.
Break
Ring Return
Switches 1 & 2
Switch 3
Ring Access
Switch 4
Open
Closed
Closed
Open
Open
Closed
Open
Open
Open
Closed
Open
Open
7
Data Sheet
November 1999
L7581 Ringing Access Switch
Power Supplies
Protection
Both the 5 V and battery supply are brought onto the
L7581. The L7581 requires only the 5 V supply for
switch operation; that is, state control is powered exclusively off of the 5 V supply. Because of this, the L7581
offers extremely low power dissipation, both in the idle
and active states.
Integrated SLIC Protection
The battery voltage is not used for switch state control.
The battery is used as a reference voltage by the integrated secondary protection circuit. When the voltage
at TBAT or RBAT drops 2 V to 4 V below the battery, the
integrated SCR will trigger, thus preventing faultinduced overvoltage situations at the TBAT/RBAT nodes.
Loss of Battery Voltage
As an additional protection feature, the L7581 monitors
the battery voltage. Upon loss of battery voltage, the
L7581 will automatically enter an all OFF state and
remain in that state until the battery voltage is restored.
The L7581 is designed so that the device will enter the
all OFF state if the battery rises above –10 V and will
remain off until the battery drops below –15 V.
Monitoring the battery for the automatic shutdown feature will draw a small current from the battery, typically
4 µA. This will add slightly to the overall power dissipation of the device.
Impulse Noise
Using the L7581 will minimize and possibly eliminate
the contribution to the overall system impulse noise
that is associated with ringing access switches.
Because of this characteristic of the L7581, it may not
be necessary to incorporate a zero cross switching
scheme. This ultimately depends upon the characteristics of the individual system and is best evaluated at
the board level.
Diode Bridge/SCR
In the L7581Axx version, protection to the SLIC device
or other subsequent circuitry is provided by a combination of current-limited break switches, a diode bridge/
SCR clamping circuit, and a thermal shutdown mechanism. In the L7581Bxx version, protection to the SLIC
device or other subsequent circuitry is provided by a
combination of current-limited break switches, a diode
bridge, and a thermal shutdown mechanism.
In both versions, during a positive lightning event, fault
current is directed to ground via steering diodes in the
diode bridge. Voltage is clamped to a diode drop above
ground. In the A version, negative lightning causes the
SCR to conduct when the voltage goes 2 V to 4 V more
negative than the battery, and fault currents are
directed to ground via the SCR and steering diodes in
the diode bridge.
Note that for the SCR to foldback or crowbar, the ON
voltage (see Table 10) of the SCR must be less negative than the battery reference voltage. If the battery
voltage is less negative than the SCR ON voltage, the
SCR will conduct fault currents to ground; however, it
will not crowbar.
In the B version, negative lightning is directed to battery
via steering diodes in the diode bridge.
For power cross and power induction faults, in both versions, the positive cycle of the fault is clamped a diode
drop above ground and fault currents steered to
ground. In the A version, the negative cycle will cause
the SCR to trigger when the voltage exceeds the battery reference voltage by 2 V to 4 V. When the SCR
triggers, fault current is steered to ground. In the B version, the negative cycle of the power cross is steered to
battery.
Current Limiting
During a lightning event, the current that is passed
through the break switches and presented to the integrated protection circuit and subsequent circuitry is limited by the dynamic current-limit response of the break
switches (assuming idle/talk state). When the voltage
seen at the TLINE/RLINE nodes is properly clamped by
an external secondary protector, upon application of a
1000 V 10 x 1000 pulse (LSSGR lightning), the current
seen at the TBAT/RBAT nodes will typically be a pulse of
magnitude 2.5 A and duration less than 0.5 µs.
8
Lucent Technologies Inc.
Data Sheet
November 1999
Protection (continued)
Integrated SLIC Protection (continued)
During a power cross event, the current that is passed
through the break switches and presented to the integrated protection circuit and subsequent circuitry is limited by the dc current-limit response of the break
switches (assuming idle/talk state). The dc current limit
is specified over temperature between 100 mA and
250 mA.
Note that the current-limit circuitry has a negative temperature coefficient. Thus, if the device is subjected to
an extended power cross, the value of current seen at
TBAT/RBAT will decrease as the device heats due to the
fault current. If sufficient heating occurs, the temperature shutdown mechanism will activate and the device
will enter an all off mode.
Temperature Shutdown Mechanism
When the device temperature reaches a minimum of
110 °C, the thermal shutdown mechanism will activate
and force the device into an all OFF state, regardless of
the logic input pins. Pin TSD, when used as an output,
will read 0 V when the device is in the thermal shutdown mode and +VDD during normal operation.
During a lightning event, due to the relatively short
duration, the thermal shutdown will not typically activate.
During an extended power cross, the device temperature will rise and cause the device to enter the thermal
shutdown mode. This forces an all off mode, and the
current seen at TBAT/RBAT drops to zero. Once in the
thermal shutdown mode, the device will cool and exit
the thermal shutdown mode, thus reentering the state it
was in prior to thermal shutdown. Current, limited to the
dc current-limit value, will again begin to flow and
device heating will begin again. This cycle of entering
and exiting thermal shutdown will last as long as the
power cross fault is present. The frequency of entering
and exiting thermal shutdown will depend on the magnitude of the power cross.
If the magnitude of the power cross is great enough,
the external secondary protector may trigger shunting
all current to ground.
Lucent Technologies Inc.
L7581 Ringing Access Switch
In the L7581, the thermal shutdown mechanism
cannot be disabled by logic control at the TSD pin.
The functionality of TSD differs from the L7541, L7582,
and L7583. For the proper use of and understanding of
any caveats related to TSD, please refer to the appropriate data sheet specifications.
Electrical specifications relating to the overvoltage
clamping circuit are outlined in Table 11.
External Secondary Protector
With the above integrated protection features, only one
overvoltage secondary protection device on the loop
side of the L7581 is required. The purpose of this
device is to limit fault voltages seen by the L7581 so as
not to exceed the breakdown voltage or input-output
isolation rating of the device. To minimize stress on the
L7581, use of a foldback- or crowbar-type device is recommended. A detailed explanation and design equations on the choice of the external secondary
protection device are given in the An Introduction to
L758X Series of Line Card Access Switches Application Note. Basic design equations governing the choice
of external secondary protector are given below:
■
■
■
|VBATmax| + |Vbreakovermax| < |Vbreakdownmin(break)|
|Vringingpeakmax| + |VBATmax| + |Vbreakovermax| <
|Vbreakdownmin(ring)|
|Vringingpeakmax| + |VBATmax| < |Vbreakovermin|
where:
VBATmax—Maximum magnitude of battery voltage.
Vbreakovermax—Maximum magnitude breakover voltage
of external secondary protector.
Vbreakovermin—Minimum magnitude breakover voltage
of external secondary protector.
Vbreakdownmin(break)—Minimum magnitude breakdown
voltage of L7581 break switch.
Vbreakdownmin(ring)—Minimum magnitude breakdown
voltage of L7581 ring access switch.
Vringingpeakmax—Maximum magnitude peak voltage of
ringing signal.
Series current-limiting fused resistors or PTCs should
be chosen so as not to exceed the current rating of the
external secondary protector. Refer to the manufacturer’s data sheet for specifications.
9
Data Sheet
November 1999
L7581 Ringing Access Switch
Protection (continued)
Integrated SLIC Protection (continued)
Table 11. Electrical Specifications, Protection Circuitry
Parameters Related to Diodes (in Diode Bridge)
Parameter
Test Condition
Measure
Min
Voltage Drop @ Continuous CurApply ±dc current limit
Forward
—
rent (50 Hz/60 Hz)
of break switches
Voltage
Voltage Drop @ Surge
Apply ±dynamic curForward
—
Current
rent limit of break
Voltage
switches
Parameters Related to Protection SCR
Surge Current
—
—
—
—
—
—
Gate Trigger Current*†
Gate Trigger Current† Temperature
—
—
—
Coefficient
Hold Current
—
—
70
Gate Trigger Voltage
Trigger current
—
VBAT – 4
Reverse Leakage Current
VBAT
—
—
§
ON
ON-State Voltage
0.5 A, t = 0.5 µs
V
—
2.0 A, t = 0.5 µs
—
—
Typ
—
Max
3
Unit
V
5
—
V
—
25
–0.5
‡
50
—
A
mA
%/°C
—
—
—
–3
–5
VBAT – 2
1.0
—
—
mA
V
µA
V
V
* Previous versions of this data sheet specified a Trigger Current of 50 mA minimum. Trigger Current is defined as the minimum current drawn
from tip and ring to turn on the SCR. The specification in this data sheet is Gate Trigger Current, which is defined as the maximum current
that can flow into the battery before the SCR turns on.
† Typical at 25 °C.
‡ Twice ± dynamic current limit of break switches.
§ In some instances, the typical ON-state voltage can range as low as –25 V.
10
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Typical Performance Characteristics
CURRENT
LIMITING
+I
ILIMIT
2/3 RON
dc CURRENT-LIMIT
BREAK SWITCHES
VBAT – 2
VBAT – 4
RON
–1.5 V
VBAT
–V
VON
<1 µA
3V
1.5 V
RON
+V
2/3 RON
ILIMIT
CURRENT
LIMITING
50 mA
–I
12-2311 (F)
dc CURRENT LIMIT
(OF BREAK SWITCHES)
Figure 5. Switches 1—3
IH
12-2309.f (F)
Figure 3. Protection Circuit A Version
+I
RON
dc CURRENT-LIMIT
BREAK SWITCHES
–VOS
–V
VBAT – 3
+VOS
+V
VBAT
<1 µA
3V
–I
12-2312 (F)
dc CURRENT LIMIT
(OF BREAK SWITCHES)
Figure 6. Switch 4
12-2309.b (F)
Figure 4. Protection Circuit B Version
Lucent Technologies Inc.
11
Data Sheet
November 1999
L7581 Ringing Access Switch
Application
VBAT
(REFERENCE)
SW3
SW1
R1
TIP
TIP
SCR
AND
TRIP
CKT
CROWBAR
PROTECTION
BATTERY
FEED
RING
R2
SW2
RING
SW4
RING
GENERATOR
BATTERY
12-3074.e (F)
Figure 7. Typical RAS Application, A Version, Idle, or Talk State Shown
Table 12. Truth Table
INPUT
0V
5V
Don’t Care
TSD
Tip Break Switch Ring Break Switch
On
On
5 V/Float1
1
5 V/Float
Off
Off
0 V2
Off
Off
Ringing Return Switch
Off
On
Off
Ring Switch
Off3
On4
Off5
1. Thermal shutdown mechanism is active with TSD floating or equal to 5 V.
2. Forcing TSD to ground overrides the logic input pins and forces an all OFF state.
3. Idle/Talk state.
4. Power ringing state.
5. All OFF state.
A parallel in/parallel out data latch is integrated into the L7581. Operation of the data latch is controlled by the logic
level input pin LATCH. The data input to the latch is the INPUT pin of the L7581, and the output of the data latch is
an internal node used for state control.
When the LATCH control pin is at logic 0, the data latch is transparent and data control signals flow directly from
INPUT, through the data latch to state control. Any changes in INPUT will be reflected in the state of the switches.
When the LATCH control pin is at logic 1, the data latch is active—the L7581 will no longer react to changes at the
INPUT control pin. The state of the switches is now latched; that is, the state of the switches will remain as they
were when the LATCH input transitioned from logic 0 to logic 1. The switches will not respond to changes in INPUT
as long as LATCH is held high.
Note that the TSD input is not tied to the data latch. TSD is not affected by the LATCH input. TSD input will override
state control via INPUT and LATCH.
12
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Outline Diagrams
16-Pin, Plastic SOG (L7581AAE/BAE)
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics
to assist your design efforts, please contact your Lucent Technologies Sales Representative.
L
N
B
1
PIN #1 IDENTIFIER ZONE
W
H
SEATING PLANE
0.10
1.27 TYP
0.51 MAX
0.61
0.28 MAX
Number
of Pins
(N)
Maximum
Length
(L)
Maximum Width
Without Leads
(B)
Maximum Width
Including Leads
(W)
Maximum Height
Above Board
(H)
16
10.49
7.62
10.64
2.67
5-4414r2 (C)
Lucent Technologies Inc.
13
Data Sheet
November 1999
L7581 Ringing Access Switch
Outline Diagrams (continued)
16-Pin, Plastic DIP (L7581AC/BC)
Note: The dimensions in this outline diagram are intended for informational purposes only. For detailed schematics
to assist your design efforts, please contact your Lucent Technologies Sales Representative.
L
N
B
1
W
PIN #1 IDENTIFIER ZONE
H
SEATING PLANE
0.38 MIN
2.54 TYP
0.58 MAX
Number
of Pins
(N)
Maximum
Length
(L)
Maximum Width
Without Leads
(B)
Maximum Width
Including Leads
(W)
Maximum Height
Above Board
(H)
16
20.57
6.48
7.87
5.08
5-4410 (F)
14
Lucent Technologies Inc.
Data Sheet
November 1999
L7581 Ringing Access Switch
Ordering Information
Device Part No.
ATTL7581AAE
ATTL7581AAE-TR*
ATTL7581AC
ATTL7581BAE
ATTL7581BAE-TR*
ATTL7581BC
Description
Ringing Access Switch
Ringing Access Switch
Ringing Access Switch
Ringing Access Switch
Ringing Access Switch
Ringing Access Switch
Package
16-Pin SOG
16-Pin SOG (Tape & Reel)
16-Pin DIP
16-Pin SOG
16-Pin SOG (Tape & Reel)
16-Pin DIP
Comcode
107338469
107338493
107338436
107392839
107392953
107392995
*Devices on tape and reel must be ordered in 1000-piece increments.
Lucent Technologies Inc.
15
For additional information, contact your Microelectronics Group Account Manager or the following:
INTERNET:
http://www.lucent.com/micro
E-MAIL:
[email protected]
N. AMERICA: Microelectronics Group, Lucent Technologies Inc., 555 Union Boulevard, Room 30L-15P-BA, Allentown, PA 18103
1-800-372-2447, FAX 610-712-4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)
ASIA PACIFIC: Microelectronics Group, Lucent Technologies Singapore Pte. Ltd., 77 Science Park Drive, #03-18 Cintech III, Singapore 118256
Tel. (65) 778 8833, FAX (65) 777 7495
CHINA:
Microelectronics Group, Lucent Technologies (China) Co., Ltd., A-F2, 23/F, Zao Fong Universe Building, 1800 Zhong Shan Xi Road, Shanghai
200233 P. R. China Tel. (86) 21 6440 0468, ext. 316, FAX (86) 21 6440 0652
JAPAN:
Microelectronics Group, Lucent Technologies Japan Ltd., 7-18, Higashi-Gotanda 2-chome, Shinagawa-ku, Tokyo 141, Japan
Tel. (81) 3 5421 1600, FAX (81) 3 5421 1700
EUROPE:
Data Requests: MICROELECTRONICS GROUP DATALINE: Tel. (44) 7000 582 368, FAX (44) 1189 328 148
Technical Inquiries: GERMANY: (49) 89 95086 0 (Munich), UNITED KINGDOM: (44) 1344 865 900 (Ascot),
FRANCE: (33) 1 40 83 68 00 (Paris), SWEDEN: (46) 8 594 607 00 (Stockholm), FINLAND: (358) 9 4354 2800 (Helsinki),
ITALY: (39) 02 6608131 (Milan), SPAIN: (34) 1 807 1441 (Madrid)
Lucent Technologies Inc. reserves the right to make changes to the product(s) or information contained herein without notice. No liability is assumed as a result of their use or application. No
rights under any patent accompany the sale of any such product(s) or information.
Copyright © 1999 Lucent Technologies Inc.
All Rights Reserved
November 1999
DS00-050ALC (Replaces DS99-014ALC)
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