STMICROELECTRONICS STLC5444B1

STLC5444
QUAD FEEDER POWER SUPPLY
SUPPLIES POWER FOR UP TO FOUR DIGITAL TELEPHONE LINES
CONFORMS TO THE CCITT RECOMMENDATIONS FOR POWER FEED AT THE S OR
T REFERENCE POINTS
SUPPORTS POINT-TO-POINT AND POINT
TO MULTIPOINT CONFIGURATIONS
EACH OF THE FOUR LINES IS INDIVIDUALLY CONTROLLED
HIGH-VOLTAGE BCD TECHNOLOGY SUPPORTING UP TO -130V
AUTOMATIC THERMAL SHUTDOWN
STATUS CONDITION DETECTION (BY MICROPROCESSOR) FOR EACH LINE:
– Low output voltage
– Openloop
– Current overload
– Thermal overload
– Normal line condition
PROGRAMMABLE CURRENT LIMITING
OUTPUT CURRENT UP TO 120mA
DESCRIPTION
The ISDN Quad Feeder Power Supply (IQFPS)
provides a power source for up to four line interfaces. The power source to the device is a local
battery or a centralized regulated power supply.
It can operate in point-to-point and point-to-multipoint configurations as far as S interface is concerned.
By the device microprocessor interface, each
powered line is individually controlled and monitored.
Therefore, overloads and faults are easy to detect
and localize even in a large system.
The status conditions detected by the device on
each line that may be read by the microprocessor
are :
low output voltage
openloop
current overload
thermal overload
normal line conditions
A hardware current limiting programmable feature
is available.
December 1997
DIP24
PLCC44
ORDERING NUMBERS: STLC5444B1 (DIP24)
STLC5444FN (PLCC44)
DIP24 PIN CONNECTION (Top view)
D1
1
24
D2
D0
2
23
D3
INT
3
22
A0
BGND
4
21
DGND
VCC
5
20
ALE
ILIM
6
19
WR
N.C.
7
18
CS
VBB
8
17
RD
N.C.
9
16
RESET
S0
10
15
S3
S1
11
14
RSRVD
VBB
12
13
S2
D94TL102
1/17
STLC5444
D1
VBB
N.C.
3
2
1 44 43 42 41 40
A0
D0
4
D3
N.C.
5
D2
INT
6
N.C.
VBB
PLCC44 PIN CONNECTION (Top view)
VBB
7
39
VBB
N.C.
8
38
N.C.
BGND
9
37
N.C.
N.C.
10
36
DGND
VCC
11
35
ALE
ILIM
12
34
N.C.
N.C.
13
33
WR
N.C.
14
32
CS
VBB
15
31
RD
N.C.
16
30
RESET
VBB
17
29
VBB
S3
N.C.
N.C.
N.C.
S2
N.C.
VBB
S1
N.C.
S0
N.C.
18 19 20 21 22 23 24 25 26 27 28
D94TL103
BLOCK DIAGRAM
THERMAL
OVERLOAD
STATUS GROUP BUS
STATUS
DETECTOR
MUX
LINE ENABLE REGISTER BUS
ADDRESS
BUS 0/2
O/3
INPUT BUS D3/D0
INDIRECT
ADDRESS
REGISTER
BIT 3
2/17
S0
S1
S2
S3
VBB(12)
LER EN
BGND
µP
INTERFACE
VOLTAGE
REFERENCE
OUTPUT
BUS D3/D0
ALE
S
DRIVERS
LINE
ENABLE
REGISTER
IAR EN
INT EN
LINE
STATUS
BUS
S DRIVERS
DISABLE
DGND
VCC
VBB(8)
A0
CS
D3/D0
RD
WR
INT
RESET
ILIM
D94TL104B
STLC5444
PIN DESCRIPTION
Name
No
PLCC
No
DIP
D1
1
1
NC
2,4,8,10,
13,14,
16,18,
20,23,
25,26,
28,34,
37,38,44
7,9
Function
Bit 1 of the tri state I/O data bus
No connection
D0
3
2
Bit 0 of the tri state I/O data bus
INT
5
3
Active low interrupt output for the µP (open drain)
VBB
6,7
15,17
22,29,
39,40
8,12
BGND
9
4
Battery ground line
VCC
11
5
+5V supply line
ILIM
12
6
Current limit programming
S0
19
10
Output of the power switch controller 0
S1
21
11
Output of the power switch controller 1
S2
24
13
Output of the power switch controller 2
RSRVD
–
14
Reserved pin: it must be left floating
S3
27
15
Output of the power switch controller 3
Battery supply line (negative battery‘s terminal)
RESET
30
16
Active high reset input
RD
31
17
Active low read input
CS
32
18
Active low chip select input
WR
33
19
Active low write input
ALE
35
20
Active high address latch enable
DGND
36
21
Digital ground
A0
41
22
Address bit for R/W operations on the data bus
D3
42
23
Bit 3 of the I/O tri state data bus
D2
43
24
Bit 2 of the I/O tri state data bus
FUNCTIONAL DESCRIPTION
BGND - Ground Battery
ADDRESS LINE (Input)
A0 selects source and destination locations for
read and write operations on the data bus. A0
must be valid on the falling edge of ALE or during
RD and WR if ALE is tied High.
CS - Chip Select (Input; Active Low)
CS must be Low to enable the read or write operations of the device. Data transfer occurs over
the D3-D0 lines.
ALE - Address Latch Enable (Input; Active
High)
ALE is an input control pulse used to strobe the
address on the A0 line into the address latch.
This signal is active High to admit the input address. The address is latched on the High-Low
transition of ALE. While ALE is High, the address
latch is transparent. For an unmultiplexed microprocessor bus, ALE must be tied High.
D3-D0 - DATA BUS (Input/Output; Three-State)
The four bidirectional data bus lines are to exchange information with a microprocessor. D0 is
the least significant bit and D3 is the most significant bit. A High on the data bus corresponds to a
logical 1. These lines act as input when WR and
CS are active and as output when RD and CS are
active. When CS is inactive, the D3-D0 pins are
placed in a high-impedance state.
3/17
STLC5444
FUNCTIONAL DESCRIPTION (continued)
transferred to D3-D0.
DGND - Ground Digital
ILIM - Current Limit Programming (Input)
ILIM programs the current limit of the Output drivers using an external resistor connected between
ILIM and VBB. The ILIM pin is 1.25V more positive than VBB. The current limit is 5mA plus 1000
times the current in the external resistor. The programmed current limit applies to each driver.
INT - Interrupt (Output; Open-Collector, Active
Low)
INT augments the Microprocessor Interface by
generating an interrupt when a Current Overload
Detector (COD) occurs. INT is active whenever
any bits in the COD register are active. INT is not
latched; when the COD register is zero, INT goes
inactive (High). INT will also go inactive if the
IQFPS automatically disables the S-output driver
that caused the interrupt (due to Thermal Overload), or if the microprocessor disables that line
via the Line Enable Register (LER). COD interrupts can be masked via the Indirect Address
Register (IAR); RESET always disables the INT
pin.
RD - Read (Input; Active Low)
The active Low read signal is conditioned by CS
and transfers internal information to the data bus.
If A0 is a logical 0, logic levels of the Indirect Address Register (IAR) and Thermal Shutdown
Status bit will be transferred to D3-D0. If A0 is a
logical 1, the data addressed by the IAR will be
4/17
RESET - Reset (Input; Active High)
RESET initialize the registers in the device, leaving the drivers switched off.
S3-S0 - Drivers (Output)
S3-S0 each supply power to one line. The outputs
can sink up to 120 mA each. The voltage at the
line is connected to VBB through a DMOS switch.
VBB - Battery Voltage (input)
VBB is the internal negative supply voltage. VBB
must always be connected to the most negative
supply voltage. The MPI Registers will not function properly when the battery power is disconnected, that is, when VBB is floating or grounded.
The IQFPS should also be reset if a drastic transient is applied to VBB.
VCC - +5V Power Supply (Input)
WR - Write (Input; Active Low)
The active Low write signal is conditioned by CS
and transfers information from the data bus to an
internal register selected by A0. If A0 is a logical
1, D3-D0 is written into the Line Enable Register
(LER). If A0 is a logical 0, D3-D0 is written into
the IAR. LER and IAR are the only two writable
registers in the device.
STLC5444
DC CHARACTERISTICS (VBB = -54V; VCC = 5V; unless otherwise specified)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
2
Unit
VIH
Input Voltage High Level
V
VIL
Input Voltage Low Level
IOH
High Level Output Current
VOH = 2.4V
400
µA
IOL
Low Level Output Current
VOL = 0.4V
2
mA
IIH
High Level Input Current
VIH = 2V
10
µA
IIL
Low Level Input Current
VIL = 0.8V
60
µA
IOZH
Output Hi-Z Current High
2.4V < VOZ < VCC
10
µA
IOZL
Output Hi-Z Current Low
0V < VOZ < 0.4V
10
µA
ICC
VCC supply Current
1.4
5
mA
CL
Logic I/O Capacitance
10
0.8
V
pF
VSAT
Saturation Voltage
IS = 80mA
2
V
Ron
Output DMOS Saturation Resistivity
IS = 80mA
25
Ω
IBB
VBB Supply Current
VBB = -54V, R LIM = 26.6KΩ,
Output Disabled
6
mA
∆ISLIM
Delta Limit Current vs.
Theoretical Programmed Value
ISLIM
RLIM = 26.6KΩ, VBB = -96V
RLIM = 10.9KΩ, VBB = -54V
VLVD
Low Voltage Detector Threshold
(relative to VBB)
S3 - S0 output active
ISOL
Current Overload Detector
Threshold (as % of ISLIM)
75
ISOC
Open Loop Detector Threshold
1.5
3.2
±10%
2.7
3
3
VBB = -110V
3.3
V
90
%
4
mA
100
µA
ISZ
Si Leakage Current to ground @
Si disabled
HLVD
Low Voltage Detector Hysteresis
18
200
mV
H OLD
Open Loop Detector Hysteresis
0.6
1.6
mA
HCOD
Current Overload Detector
Hysteresis
2.4
4.0
mA
H1
130°C Thermal Detector
Hysteresis
10
°C
H2
160°C Thermal Detector
Hysteresis
10
°C
TH1
Thermal Overload Recovery
Time H1
80
µs
5/17
STLC5444
SWITCHING CHARACTERISTICS (VBB = -54V; VCC = 5V; unless otherwise specified)
MICROPROCESSOR READ/WRITE TIMING NON MULTIPLEXED MODE (for references see figure 1a
and 2b).
Symbol
tRLRH
tRHRL
tRLDA
tRHDZ
tASRL
tAHRH
tASWL
tAHWH
tADDA
tWLWH
tWHWL
tDAWH
tWHDZ
tRES
Parameter
RD, CS pulse width
RD, recovery time
T amb: -40 to 0°C and
RD, CS low to data available
RD or CS high to data Z
T amb: -40 to 0°C and
Address setup time to READ active
Address hold time to READ inactive
Address setup time to WRITE active
Addess hold time to WRITE inactive
Address stable to data available
T amb: -40 to 0°C and
WR or CS pulse width
Write recovery time
Data setup time
Data hold time
T amb: -40 to 0°C and
Reset Pulse with
T amb: 0 to 70°C
+70°C to +85°C
Min.
260
200
220
260
130
160
T amb: 0 to 70°C
+70°C to +85°C
T amb: 0 to 70°C
+70°C to +85°C
T amb: 0 to 70°C
+70°C to +85°C
Max.
0
0
30
50
360
390
200
200
100
20
40
200
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: AC timings are tested at 0.8V and 2V with input levels of 0.4V and 2.4V.
SWITCHING CHARACTERISTICS (VBB = -54V; VCC = 5V; unless otherwise specified)
MICROPROCESSOR READ/WRITE TIMING MULTIPLEXED MODE (for references see figure 1 and 2).
Symbol
tRLRH
tRHRL
tRLDA
tRHDZ
tAHAL
tADAL
tADAZ
tAZRL
tAZWL
tADDA
tWLWH
tWHWL
tDAWH
tWHDZ
tRES
Parameter
RD, CS pulse width
RD, recovery time
T amb:
RD, CS low to data available
RD or CS high to data Z
T amb:
ALE pulse width
Address setup time
Address hold time
Address Z to RD low
Address Z to WR Low
Address stable to data available
T amb:
WR or CS pulse width
Write recovery time
Data setup time
Data hold time
T amb:
Reset Pulse with
T amb: 0 to 70°C
-40 to 0°C and +70°C to +85°C
Min.
260
200
220
260
130
160
T amb: 0 to 70°C
-40 to 0°C and +70°C to +85°C
T amb: 0 to 70°C
-40 to 0°C and +70°C to +85°C
T amb: 0 to 70°C
-40 to 0°C and +70°C to +85°C
Max.
100
60
50
0
0
360
390
200
200
100
20
40
200
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note: AC timings are tested at 0.8V and 2V with input levels of 0.4V and 2.4V.
Si Timing (at 10% of final value)
Symbol
tEN
tDIS
6/17
Parameter
Si output enable time (from LER)
Si output disable time (from LER or RESET)
Test condition
R LOAD = 3kΩ
Typ.
2
3
Max.
5
6
Unit
µs
µs
STLC5444
Figure 1: Microprocessor Read Timing.
tAHAL
ALE
tADAL
tADAZ
AO
tCLRL (Note 1)
tRHCH (Note 2)
CS
tAZRL
tRHRL
tADDA
RD
tRLRH
tRHDZ
tRLDA
DATA
Read Data
D94TL108A
Notes:
1 - If tCLRL is negative, tRHRL, tRLRH, tAZRL, and tRLDA are measured from CS rather than RD.
2 - If tRHCH is negative, tRHRL, tRLRH and tRHDZ are measured from CS rather than RD.
When a read from the LER immediately follows a write to the LER a minimum of 1 µs is required between these operations.
Figure 2: Microprocessor Write Timing.
tAHAL
ALE
tADAL
tADAZ
AO
tWHCH (Note 2)
CS
tWHWL
tCLWL (Note 1)
tWLWH
WR
tAZWL
DATA
tDAWH
tWHDZ
Write Data
(Note 3)
INT
D94TL109A
Notes:
1 - If tCLWL is negative t WHWL and tWLWH are measured from CS rather than WR.
2 - If tWHCH is negative, t WHWL, tWLWH, tDAWH and tWHDZ are measured from CS rather than WR.
The propagation delay from the writing of the T/I bit to the effect on the INT pin is approximately 1µs for both mask and enable operations.
7/17
STLC5444
Figure 1a: Microprocessor Read Timing non multiplexed mode.
ALE
tAHRH
AO
tCLRL (Note 1)
tRHCH (Note 2)
CS
tASRL
tRHRL
tADDA
RD
tRLRH
tRHDZ
tRLDA
DATA
Read Data
D97TL301A
Notes:
1 - If tCLRL is negative, tRHRL, tRLRH, tAZRL, and tRLDA are measured from CS rather than RD.
2 - If tRHCH is negative, tRHRL, tRLRH and tRHDZ are measured from CS rather than RD.
When a read from the LER immediately follows a write to the LER a minimum of 1 µs is required between these operations.
Figure 2a: Microprocessor Write Timing non multiplexed mode.
ALE
tASWL
t AHWH
AO
tWHCH (Note 2)
CS
t WHWL
tCLWL (Note 1)
WR
tWLWH
tDAWH
DATA
t WHDZ
Write Data
(Note 3)
INT
D97TL302A
Notes:
1 - If tCLWL is negative t WHWL and tWLWH are measured from CS rather than WR.
2 - If tWHCH is negative, t WHWL, tWLWH, tDAWH and tWHDZ are measured from CS rather than WR.
The propagation delay from the writing of the T/I bit to the effect on the INT pin is approximately 1µs for both mask and enable operations.
8/17
STLC5444
OPERATIVE DESCRIPTION.
Initialization
The device is initialized by the RESET pin. In this
state the analog drivers are switched off, the Indirect Address Register (IAR) is cleared, and the internally latched address A0 is cleared.
Power at Output drivers
The voltage at the Output drivers is approximately
VBB (more precisely: VBB - VSAT).
Analog Section
The analog section consists of four line drivers,
which are DMOS transistor switches capable of
sinking up to 120 mA each. The power to the drivers is derived from the negative supply voltage
(VBB). The output voltage to each line is slaved to
VBB, and the voltage drop in each driver is approximately 1.5V.
Line driver protection is provided through the integration of current limit and over-temperature shutoff. The current limit is hardware-programmable
via an external resistor (RLIM) connected between ILIM and VBB.
The output limit is : 5mA + 1000 x 1.25V/RLIM.
This 1000 x gain makes the ILIM pin susceptible
to external noise, care should be taken to connect
RLIM as close as possible to the component.
The thermal shut-off is internally set at approximately 160oC.
At this temperature all the drivers are unconditionally switched off. However, at approximately
130oC, only the drivers that are in the currentoverload condition will be turned off.
Status detectors, associated with each of the line
drivers, monitor the load conditions on each line
by comparing an electrical parameter (e.g., current and voltage at the line) with reference level.
The output of each detector can be read by the
microprocessor. In addition to these status detectors, the temperature of the device is monitored
via integrated temperature detectors. The detectors respond at approximately 130oC and 160oC,
as defined above, and the 160oC detector can be
monitored by the microprocessor via the MPI. The
status detectors provide the following information
from each of the lines (all detectors have built-in
hysteresis) :
*) Low Output Voltage Detection
The low-output-voltage status bit becomes active when the voltage across the output DMOS
transistor exceeds the proper voltage threshold
(VLVD).
*) Open Loop Detection
The open-loop status bit becomes active when
the current on the line drops below a minimum
value.
*) Current Overload Detection
The current-overload status bits become active
when the current on the line nears the current
limit. These bits active the INT output if COD interrupts are enabled via the IAR Register.
*) Thermal Overload Detection
If the device temperature reaches 130oC, then
all the line drivers in the current-overload condition will be switched off and the corresponding
bits in the Thermal Overload Register will be
activated. If the device temperature increases
to 160oC, all the line drivers will be turned off,
and all the bits in the Thermal Overload Register will be activated.
The T-bit will also be set, and it can be read
along with the Indirect Address Register (IAR)
to indicate that all the drivers have been turned
off. To initialize any of the bits in the Thermal
Overload Register, the microprocessor must
first turn off the line drivers that must not be reactivated until the T-bit in the address register
is cleared by the temperature detector in the
device.
MPI Section
The MPI allows the user to access the detectors
defined in the analog section. The line driver’s
status bits are grouped by function. Bits 3-0 of the
detectors correspond to lines 3-0, respectively.
The status group are :
Low Voltage Detector (LVD)
Open Loop Detector (OLD)
Current Overload Detector (COD)
Thermal Overload Register (TOR)
The data is not latched in these status groups except in the TOR.
Thus, the user should filter (multiple samples) the
received data to ensure its integrity. There are
two other registers in the MPI: the Indirect Address Register (IAR), and Line Enable Register
(LER).
The IAR contains 3 bits that address the desired
status group or the LER. The IAR is read along
with the T-bit defined in the analog section. The
microprocessor can read the IAR to check the validity of the address. A 1us delay is required between a write to the LER register, followed by a
Read of the same register. Subsequent reads of
the LER do not have this constraint.
9/17
STLC5444
The LER is used to enable or disable the individual line drivers. The line drivers will only become
active if the corresponding bit in the TOR is inactive. The LER is a read/write register.
The MPI is the interface containing the following
pins :
D3-D0
Bidirectional
Data Bus
A0
Input
Address Line
ALE
Input
Address Latch Enable
RD
Input
Read Enable
WR
Input
Write Enable
CS
Input
Chip Select
INT
Output
COD Interrupt
RESET
Input
Reset pin
The 4-bit bidirectional data bus (D3-D0) is used to
communicate with the registers. Access to the
registers is controlled by CS, RD, WR, ALE, and
A0 as shown below. A read or write cycle must be
preceded by a valid A0. A0 is latched internally in
a transparent latch by ALE. The selection of the
status group or the LER is determined by the content of the IAR.
The truth table for the MPI control is shown below
:
CS
RD
WR
A0
0
1
0
0
Write IAR (T bit is read only)
0
0
1
0
Read IAR and T bit
0
1
0
1
Write LER
0
0
1
1
Read status groups or LER
1
X
X
X
No access
Indirect Address Register (IAR) and T/I Bit
The IAR is 3 bits wide and accessible through the
data port, D2-D0. The content of the Indirect Address Register (IAR2-IARO) determines the selection of the status groups or the LER. The thermal overload bit T/I is read and written at the
same time as IAR and occupies D3.
This register has the following format :
Bit
Symbol
0
1
2
3
IARO
IAR1
IAR2
T/I
Bit 0 of the IAR
Bit 1 of the IAR
Bit 2 of the IAR
T bit: (Read only)
Logical 0: temperature normal (default value)
Logical 1: temperature above 160°C (all drivers shut off)
I bit
: (write only)
Logical 0: INT pin disabled
Logical 1: COD interrupts enabled via INT pin‘
IAR2-IAR0 address the status groups and the LER as shown below:
10/17
IAR2
IAR1
IAR0
Select
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
LVD
OLD
COD
LEC
RESERVED
RESERVED
LER
TOR
STLC5444
The contents and format of the status groups and the LER are as follows :
LVD:
Bit
0
1
2
3
Logical 1
O0
O1
O2
O3
low voltage
low voltage
low voltage
low voltage
Logical 0 (default value)
O0 voltage normal
O1 voltage normal
O2 voltage normal
O3 voltage normal
The Low Voltage Detector (LVD) indicates the voltage level on the output lines, even when the lines are
disabled. The low-voltage condition becomes active (logical 1) if the output reaches the Low Voltage
Threshold (VLVD).
LEC:
Bit
Logical 1
SWITCH
SWITCH
SWITCH
SWITCH
0
1
2
3
ON
ON
ON
ON
Logical 0
SWITCH OFF
SWITCH OFF
SWITCH OFF
SWITCH OFF
The Line Enable Command (LEC) indicates the status of the DMOS SWITCH OUTPUT.
OLD:
Bit
Logical 1
0
1
2
3
O0 open loop
O1 open loop
O2 open loop
O3 open loop
Logical 0 (default value)
O0
O1
O2
O3
current normal
current normal
current normal
current normal
The Open Loop Detector (OLD) indicates the open-loop condition on the output lines. The open-loop
condition becomes active (logical 1) if the current on the line drops below the threshold value ISOC.
COD:
Bit
0
1
2
3
Logical 1
O0
O1
O2
O3
current overload
current overload
current overload
current overload
Logical 0 (default value)
O0
O1
O2
O3
current normal
current normal
current normal
current normal
The Current Overload Detector (COD) indicates the current-overload condition on the output lines. The
overload condition becomes active (logical 1) if the output current approaches the value programmed by
an external resistor between ILIM and VBB.
TOR :
Bit
Logical 1 (default value)
Logical 0
0
1
2
3
O0 operational
O1 operational
O2 operational
O3 operational
O0 off
O1 off
O2 off
O3 off
The Thermal Overload Register (TOR) contains the overload status of the output line drivers. If the device temperature reaches 130oC, then the output line drivers that are in the current-overload condition
will be switched off. The corresponding bits in the TOR will be set to a logical 0. To initialize any of the
bits in the TOR, the microprocessor must first turn off the output line drivers via the LER. However, the
TOR bits cannot be deactivated if the 160oC detector is active. The µp may re-enable the output drivers
via the LER after the TOR condition is removed. The TOR is a read-only register.
11/17
STLC5444
LER :
Bit
Logical 1
Logical 0 (default value)
0
1
2
3
O0 on
O1 on
O2 on
O3 on
O0 off
O1 off
O2 off
O3 off
The Line Enable Register (LER) is used to enable or disable the individual output line drivers. The output
line will only become active if the corresponding bit in the TOR is set to a logical 1. The LER can be written directly and read indirectly.
ABSOLUTE MAXIMUM RATINGS (TA = 0°C to 70°C)
Parameter
Voltage from Digital Input to DGND
Voltage from VCC to DGND
Voltage from VBB to DGND
100ns Pulse voltage from Si to DGND (See Notes)
Voltage from BGND to DGND
Storage Temperature
Value
-0.4V to VCC
-0.4V to +7V
-130V to +0.4V
-130V to +2V
+0.5V, -3V
T = -60°C to +150°C
Note : Si stands for O0, O1, O2 or O3 outputs.
RECOMMENDED OPERATING CONDITIONS
Parameter
(*) Ambient Temperature
for standard type
for ext. temperature type
Supply Voltage
Programmed Limiting Current
Symbol1
TA
TA
VCC
VBB
DGND
BGND
ISLIM
Min.
0
-40
4.75
-115
0
-3
Max.
70
85
5.25
-38
0
+0.5
120
Units
°C
°C
V
V
V
V
mA
Note: The test condition is specified with a diode in series with V BB.
(*): Specifications in this data sheet are guaranteed by testing from 0°C to +70°C. For extended temperature range types, performance from
–40°C to +85°C is guaranteed by characterization and periodic sampling of production units.
ORDERING TYPES:
STLC5444B1, PDIP24 package: 0 to 70°C Temperature range.
STLC5444FN, PLCC44 package: 0 to 70°C Temperature range.
STLC5444B1-X, PDIP24 package: -40 to 85°C Temperature range.
STLC5444FN-X, PLCC44 package: -40 to 85°C Temperature range.
APPLICATION HINT
In the Absolute Maximum Ratings table it is specified that the voltage applied on the -Vbat pin
should never exceed by more than 0.4V the voltage applied on the Ground pin.
As long as the external circuitry assures compliance with the above, no more considerations are
needed.
In some cases however it may be not possible to
exclude that conditions may occur (hot insertion,
power supply transients, etc.) where the negative
supply has a transient overshoot above ground
voltage. Then a protection circuitry that clamps
such overshoot can add to the equipment reliability. Such protection can be designed taking into
considerations that typically the devices behave
as follows:
12/17
- if the Vbat pin is not connected, and the other
pins are normally biased, the chip generates
on it an open circuit voltage of +420mV.
- if all the other pins are normally biased and
the -Vbat pin forced at +600mV, a current of
10mA flows into it. At the same time from +5V
a current of 4mA is absorbed (this low current
from +5V simply means that no parasitic
latch-ups are triggered inside the chip). No
deterioration of the device occurs.
- if all the other pins are normally biased, and
the -Vbat pin is forced at +1.5V for a transient
period, no deterioration of the device occurs.
Transient period can be considered any time
interval that lasts for less than 10µs and is not
repeated more than 5000 times during the
device lifetime.
STLC5444
COUNTER FEEDING
It is possible that, in some applications, a communication channel that the STLC5444 feeds, is also
biased at the other end by another feeding device.
What considerations apply to the STLC5444 in
this case?
Let’s use a generic example for reference (see Fig. 3)
Figure 3: Typical PABX connection.
S
U
S
STLC5444
D95TL229
S
Si
Si
STLC5444
VBB
V BB
NT
A PABX with S-interfaces may have some of
them connected to Terminal Equipments, and one
to the S-interface of a Nertwork Termination. The
S-interface of the PABX connected to the NT has
one channel of the STLC5444 available for feeding. It will be programmed in the ”OFF” state to
avoid interference with the feeding coming from
the NT (of course the feeding coming from the NT
will not be loaded by this PABX connection).
The following considerations are relevant in the
above example:
1) The VBB of the STLC5444 in the PABX must
be equal or more negative than the feeding
voltage coming from the NT (unless decoupling diodes are externally provided - see 4)
2) The STLC5444 channel of the PABX must be
programmed OFF.
PABX
3) In the channel of the STLC5444 on the PABX
side, the only effect will be on the relevant
LVD bit that will be set to 1 if the feeding voltage coming from the NT is 3V more positive
than the local VBB. No interrupts or alarms are
generated.
4) It is good common practice to provide every Sinterface with protection circuitry against transient overvoltages (see Fig. 4). This includes a
diode in series with each Si pin of the
STLC5444. If this is the case, absolute levels
of local VBB and NT feeding are no concern at
all. (If such diodes are not present, care must
be paid to the power supply of the PABX, and
to the connected circuits. When the PABX
supply is OFF, the NT feeding will find a connection through the relevant channel of the
STLC5444 to the VBB point).
Figure 4: Protection of the STLC5444 against overvoltage.
D2
BGND
BGND
TPAXX
Si
D1
FUSE RESISTORS
S INTERFACE
D3
STLC5444
VBB
BATTERY
D95TL230
13/17
STLC5444
NOTE
Possible effect on the device of a Vbat variation
Be aware that a variation of Vbat during operation, when the switches are on can cause anomalous behaviour. To avoid that a turn-off occurs the variation should have a rise time equal or lower than
20V/µs (fig. 5), and a fall time equal or lower than 2.0V/µs (fig.6).
Figure 6: Typical fall time behaviour.
Figure 5: Typical rise time behaviour.
D97TL304
D97TL303
Vbat1
Vbat1
Fail dV/dt > 25V/µs
OK dV/dt < 2.0V/µs
OK dV/dt < 20V/µs
Fail dV/dt > 2.4V/µs
Vbat0
14/17
Vbat0
STLC5444
DIP24 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
TYP.
inch
MAX.
MIN.
TYP.
a1
0.63
0.025
b
0.45
0.018
b1
0.23
b2
0.31
1.27
D
E
0.009
0.012
0.050
32.2
15.2
16.68
1.268
0.598
0.657
e
2.54
0.100
e3
27.94
1.100
F
MAX.
14.1
0.555
I
4.445
0.175
L
3.3
0.130
15/17
STLC5444
PLCC44 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
TYP.
MAX.
MIN.
TYP.
MAX.
A
17.4
17.65
0.685
0.695
B
16.51
16.65
0.650
0.656
C
3.65
3.7
0.144
0.146
D
4.2
4.57
0.165
0.180
d1
2.59
2.74
0.102
0.108
d2
E
0.68
14.99
0.027
16
0.590
0.630
e
1.27
0.050
e3
12.7
0.500
F
0.46
0.018
F1
0.71
0.028
G
16/17
inch
0.101
0.004
M
1.16
0.046
M1
1.14
0.045
STLC5444
ESD - The SGS-THOMSON Internal Quality Standards set a target of 2 KV that each pin of the devic e should withstand in a series of tests
based on the Human Body Model (MIL-STD 883 Method 3015): with C = 100pF; R = 1500Ω and performing 3 pulses for each pin versus VCC
and GND.
Device characterization showed that, in front of the SGS-THOMSON Internaly Quality Standards, all pins of STLC5444 withstand at least
1000V.
The above points are not expected to represent a pratical limit for the correct device utilization nor for its reliability in the field. Nonetheless
they must be mentionned in connection with the applicability of the different SURE 6 requirements to STLC5444.
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility for the
consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No
license is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics. Specification mentioned
in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGSTHOMSON Microelectronics products are not authorized for use as critical components in life support devices or systems without express
written approval of SGS-THOMSON Microelectronics.
 1997 SGS-THOMSON Microelectronics – Printed in Italy – All Rights Reserved
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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17/17