STMICROELECTRONICS L3000S

L3000S
L3030
SUBSCRIBER LINE INTERFACE KIT
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PRELIMINARY DAT A
PROGRAMMABLE DC FEEDING RESIS-TANCE AND LIMITINGCURRENT (fourvalues available)
THREE OPERATING MODES :
STAND-BY, CONVERSATION, RINGING
NORMAL/BOOSTBATTERY, DIRECT/REVERSE POLARITY
SIGNALLING FUNCTION (off-hook/GND-key)
FILTERED OFF-HOOK DETECTION IN
STAND-BY (10ms)
QUICK OFF-HOOK DETECTION IN CONVERSATION (< 1ms) FOR LOW DIAL PULSE DETECTION DISTORTION
HYBRID FUNCTION
RINGING GENERATION WITH QUASI ZERO
OUTPUT IMPEDANCE, ZERO CROSSING INJECTION (no ext. relay needed) AND RING
TRIP DETECTION
AUTOMATIC RINGING STOP WHEN OFFHOOK IS DETECTED
PARALLEL AND SERIAL DIGITAL INTERFACES
TELETAXE SIGNALINJECTION (2VRMS/5VRMS)
LOW NUMBER OF EXTERNAL COMPONENTS
GOOD REJECTION OF THE NOISE ON BATTERY VOLTAGE (20dB at 10Hz and 35dB at
1kHz)
POSSIBILITY TO WORK ALSO WITH HIGH
COMMON MODE CURRENTS
INTEGRATED THERMAL PROTECTION WITH
THERMAL OVERLOAD INDICATION
SURFACE MOUNT PACKAGE
(PLCC44 + PowerSO-20)
DESCRIPTION
The ST SLIC KIT (L3000S/L3030) is a set of solid
state devices designed to integratemain of the functions needed to interface a telephone line. It consists of 2 integrated devices : the L3000S line
interface circuit and the L3030 control unit.
This kit performs the main features of the BORSHT
functions :
feed
- Battery
- Ringing
- Signalling
- Hybrid
June 1997
PLCC44
FLEXIWATT15
PowerSO20
slug-up
slug-down
ORDERING NUMBERS :
L3030 (PLCC44)
L3000SX-VM (FLEXIWATT15)
L3000SX (PowerSO20 slug-up)
L3000SX-77 (PowerSO20 slug-down)
Additional functions, such as battery reversal, extra
batteryuse, line overvoltagesensing and meteringpulse injection are also featured ; most external
characteristics,as AC and DC impedances,are programmable with external components.The SLIC injects ringing in balanced mode and for that, as well
as for the operation in battery boosted, a positive
battery voltage shall be available on the subscriber
card. As the right ringing signal amplification both in
voltage and in current is provided by SLIC, the ring
signal generatorshall onlyprovide a low level signal
(0.285Vrms).
This kit is fabricatedusing a 140V Bipolar technology for L3000Sand a 12V Bipolar I2L technologyfor
L3030.
L3030 is available PLCC44 and L3000S in both
FLEXIWATT15 and PowerSO-20 for surfacemount
application.
This kit is suitable for all the following applications:
C.O. (CentralOffice),DLC (Digital LoopCarrier) and
high range PABX (Private Automatic Branch Exchange).
1/29
L3000S - L3030
PIN CONNECTIONS (top view)
FLEXIWATT15
PLCC44
VB-
10
11
VB-
RING
VBIM
9
12
AGND
VIN
8
13
REF
VB-
1
20
VB-
N.C.
2
19
TIP
3
18
N.C.
MNT
4
17
IL
VDD
7
14
C1
BGND
6
15
C2
VB+
5
16
IT
BGND
6
15
C2
VB+
5
16
IT
C1
MNT
4
17
IL
TIP
3
18
N.C.
N.C.
2
19
RING
VB-
1
20
VB-
VDD
VIN
VBIM
VB-
14
7
13
8
12
9
11
10
D97TL290
PowerSO-20 (slug-down)
2/29
REF
AGND
VB-
D94TL125
PowerSO-20 (slug-up)
L3000S - L3030
PIN DESCRIPTION (L3000S)
FLEX.
N°
1
PSO
N°
3
2
3
4
4
5
6
MNT
VB+
BGND
5
6
7
7
8
9
VDD
VIN
VBIM
8
VB–
9
10
1, 10
11, 20
12
13
AGND
REF
11
12
13
14
15
16
C1
C2
IT
14
17
IL
15
19
RING
–
2, 18
N.C.
Name
TIP
Description
A line termination output with current capability up to 100mA (Ia is the current sourced
from this pin).
Positive Supply Voltage Monitor
Positive Battery Supply Voltage
Battery ground relative to the VB+ and the VB– supply voltages.
It is also the reference ground for TIP and RING signals.
Positive Power Supply + 5V
2 wire unbalanced voltage input.
Output voltage without current capability, with the following functions :
- give an image of the total battery voltage scaled by 40 to the low voltage part.
- filter by an external capacitor the noise on VB–.
Negative Battery Supply Voltage
Analog Ground. All input signals and the VDD supply voltage must be referred to this pin.
Voltage reference output with very low temperature coefficient. The connected resistor
sets internal circuit bias current.
Digital signal input (3 levels) that defines device status with pin 12.
Digital signal input (3 levels) that defines device status with pin 11.
High precision scaled transversal line current signal.
Ia + Ib
IT =
100
Scaled longitudinal line current signal.
Ib − Ia
IL =
100
B line termination output with current capability up to 100mA (Ib is the current sunk into
this pin).
Not connected
Notes: 1) Unless otherwise specified all the diagrams in this datasheet refers to the FLEXIWATT15 pin connection.
2) All informations relative to the PowerSO-20 package option should be considered as advanced information on a new product
now in development or undergoing evaluation. Details are subject to change without notice.
3/29
L3000S - L3030
PIN DESCRIPTION (L3030)
Pin
Symbol
1
TST
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
REF
AGND
VSS
VDD
N.C.
CZS
ACF
ZAC
4/29
TST
VOUT
CM
RC
IT
RDC
EIA
NCS
DIO
DCKL
DGND
N.C.
N.C.
N.C.
CI
C1
C2
N.C.
N.C.
IL
CRTS
TTXIN
RGTTX
TTXF
ZB
TST
TX
RX/RG
VBIM
TST
Function
This pin is connected internally for test purpose. It should not be used as a tie point for
external components.
Bias Set
Analog Ground
– 5V
+ 5V
Not connected.
AC Feedback Input
AC Line Impedance Synthesis
AC Impedance Adjustement
These pins are connected internally for test purpose. It should not be used as a tie point
for external components.
Two wire unbalanced output.
Capacitor Multiplier Input
DC Feedback Input
Transversal Line Current
DC Feeding System
Read/write Command
Chip Select Command
Data Input/output
Clock Signal
Digital Ground
Not connected.
Not connected.
Not connected.
Input/output Changing Command
State Control Signal 1
State Control Signal 2
Not connected.
Not connected.
Longitudinal Line Current
Ringtrip Det. & TTX Shaping
Teletaxe Signal Input
TTX Filter Level Compensation
TTX Filter Input
Balancing Network
These pins are connected internally for test purpose. It should not be used as a tie point
for external components.
4W Sending Output
4W Receiving and Ring Input
Battery Image Input
These pins are connected internally for test purpose. It should not be used as a tie point
for external components.
L3000S - L3030
L3000S BLOCK DIAGRAM
L3030 BLOCK DIAGRAM
5/29
L3000S - L3030
ABSOLUTE MAXIMUM RATINGS
Symbol
Vb–
Vb +
|Vb–| + |Vb+|
Vdd
V ss
Vagnd – Vbgnd
Tj
Tstg
Parameter
Negative Battery Voltage
Positive Battery Voltage
Total Battery Voltage
Positive Supply Voltage
Negative Supply Voltage
Max. Voltage between Analog Ground and Battery Ground
Max. Junction Temperature
Storage Temperature
Value
– 80
80
140
+6
–6
5
+ 150
Unit
V
V
V
V
V
V
°C
– 55 to + 150
°C
Value
Unit
THERMAL DATA
Symbol
Parameter
L3000S HIGH VOLTAGE
Flexiwatt
PWSO20
Rth j-case
Thermal Resistance Junction to Case
Max. 4
Typ. 2
°C/W
R th j-amb
Thermal Resistance Junction to Ambient
Max. 50
Max. 60
°C/W
L3030 LOW VOLTAGE
R th j-amb
Max. Resistance Junction to Ambient
°C/W
80
OPERATING RANGE
Symbol
Toper
Vb –
Vb +
Vb– + Vb+
Vdd
V ss
Imax
Parameter
Operating Temperature Range
Min.
0
Typ.
Max.
70
Negative Battery Voltage
Positive Battery Voltage
Total Battery Voltage
Positive Supply Voltage
Negative Supply Voltage
Total Line Current (IL + IT)
– 70
0
– 48
+ 72
120
– 24
+ 75
130
+ 5.5
– 4.5
85
FUNCTIONAL DESCRIPTION
L3000S - High Voltage Circuit
The L3000Slineinterfaceprovidesa batteryfeeding
for telephonelines and ringing injection.The IC contains a state decoderthat underexternal controlcan
force the following operational modes : stand-by,
conversation and ringing.
In addition Power down mode can be forced connecting the bias current resistor to VDD or leaving it
open.
Two pins, IL andIT, carryout the information concerning line statuswhich is detectedby sensing the line
current into the output stage.
The L3000S amplifies both the AC and DC signals
entering at pin 6 (VIN) by a factor equal to 40.
Separate grounds are provided :
- Analog ground as a reference for analog signals
- Battery ground as a reference for the output stages
6/29
+ 4.5
– 5.5
Unit
°C
V
V
V
V
V
mA
The two groundshould be shortedtogetherat a low
impedance point.
L3030 - Control Unit
The L3030 low voltage control unit controls L3000S
line interface module, giving the proper information
to set line feed characteristic, to inject ringing and
TTX signal and synthetizes the line and balance impedances. An on chip digital interface allows a microprocessor to control all the operations. L3030
defines working states of line interface and also informs the card controller about line status.
L3000S - Working States
In order to carry out the different possible operations, the L3000S has several different working states.Each stateis definedby the voltagerespectively
applied by pins 27 and 28 of L3030 to the pins 11
and 12 of L3000S.
Three different voltage levels (– 3, 0, + 3) are available at each connection, so defining nine possible
L3000S - L3030
Table 1.
Pin 28 of L3030 / Pin 12 of L3000S
+3
+3
Pin 27 of L3030
Pin 11 of L3000S
0
(C2)
–3
Stand-by
Conversation in Normal
Battery Direct Polarity
Conversation in Normal
Battery Reverse Polar
0
Not allowed.
Conversation in Boost
Battery Direct Polarity
Conversation in Boost
Battery Reverse Polar
–3
Not allowed.
Ringing with Direct
Polarity
Not allowed.
states as listed in Table. 1.
Appropriate combinations of two pins define the
three modes of the ST SLIC, that are :
a) Stand-by (SBY)
b) Conversation (CVS), Normal and Reverse polarity
c) Ringing (RING)
d) Boost Battery (BB), Normal and Reverse polarity
A fifth status, Power down (PD), can be set disconnecting the bias resistor (RH) from pin 10 ofL3000S
by means of an external transistor.
The main difference between Stand-by and Power
down is that in SBY the power consumption on the
voltage battery VB– (– 48V) is reduced but the
L3000S DC feeding and monitoring circuits are still
active. In PD the power consumption on VB- is reduced to zero, and the L3000S is completely switched off.
The SBYstatus shouldbe used when the telephone
is in On hook and PD status onlyin emergencycondition when it is mandatory to cut any possible dissipation but no operation are requested.
OPERATING MODES
Stand-by (SBY) Mode
In this mode, the bias currents of both L3000S and
L3030are reducedas only someparts of the two circuits are completely active, control interface and
current sensors among them. The current supplied
to the line is limited at 7mA, and the slope of the DC
characteristic corresponds to :
2
R = x (RFS + 2RP)
3
The Line voltage in on Hook conditionisjust the batteryvoltage minus the voltage drop (approx. 15V)of
the output stage amplifiers (see Fig. 1).
Figure 1 : DC Characteristics in Stand-byMode.
7/29
L3000S - L3030
The AC characteristic is just the resistance of the
two serial resistors RP.
In Stand-bymode the batterypolarity is just in direct
condition,that is the TIP wire more positive than the
RING one ; boost battery is not achievable. There
are two possible line conditions where the SLIC is
expected to be in stand-by mode :
1) ON-HOOK (Iline < 5mA). Normal on-hook
condition.
2) OFF-HOOK (Iline > 7mA). Handset is unhooked,
the SLIC is waiting for command to activate
conversation.
When the SLIC is in stand-by mode, the power dissipation of L3000S does not exceed 120mW (from
-48V) eventually increased of a certain amount if
some current is flowing into the line.
The power dissipation of L3030 in the same condition, is typically 120mW.
The Stand-byMode is set when the byte sent to the
L3030 Serial Digital Interface has the first two bits
(BIT0R and BIT1R) equal to ”0”.
Settingto 0 all the 8 bits of the command sent to the
digital interface of L3030, the bias currents of both
L3000S and L3030 are reduced and only some
parts of the two circuits are active similarly to the
stand-by mode ; in this situation, named powerdown denial, the line sensors are disabled
(ON/OFF-HOOK line conditions cannot be recognized) and the current supplied to the line is limited at
0.25mA.
Conversation (CVS) or Active Mode
In conversationmodeit is possibleto selectbetween
two different DC Characteristics by the BIT5R of the
Serial Interface.
1) Normal Battery (NB)
2) Boost Battery (BB)
It is also possibleto select(BIT4R)the polarity of the
DC line voltage and (BIT6R-BIT7R) one of the four
values of limiting current (25mA or 30mA or 45mA
or 70mA).
Battery reverse can take place either before or during conversation.
As far as the DC characteristic in Normal Battery is
concerned, three different feeding conditions are
present :
a) current limiting region ; the DC impedance of the
SLIC is very high (> 20 Kohm) and therefore the
systemworkslike a currentgenerator,the current
value being set through the digital interface
(25/30/45/70mA).
b) standard feeding system region ; the
characteristic is equal to a – 48V (– 60V) battery
(note 1), in series with two resistors, whose value
is set by external components (see external
component list of L3030).
c) low impedance region ; the battery value is
reducedto 33V (45V) and the serial resistance is
reduced to the value specified in stand by mode,
2
that is : x (RFS + 2RP)
3
Switching betweenthe three region is automaticwithout discontinuity, and depends on the loop resistance.Fig. 2 shows the DC characteristic in normal
battery condition.
Whenthe boostbatteryconditionisactivatedthe low
impedance region can never be reached by the sy-
Figure 2 : DC Characteristic (n.b.) ILIM = 25/30/45/70mA.
Note :
8/29
1. This value of voltage battery, named apparent battery, is fixed internally by the control unit and is independent of the actual battery
value. So, the voltage drop in the low impedance region is 15V. It is also possible to increase up to 25V this value setting BIT3R to 1.
L3000S - L3030
stem ; in this case the internal dropout voltage is
equal to 30V.
Fig. 3 shows the DC characteristic in boost battery
condition.
In conversationmode, on request of controlprocessor, whatever condition is set (normal or boost battery, direct or reverse polarity), you can inject the
12kHz(or16kHz)signal (permanentlyapplied at the
pin 33 with 950mVrms typ. amplitude), as metering
pulses. A patented automatic control system adjust
the level of the metering signal, across the line, to
2Vrms setting BIT3 = 0, or to 5Vrms setting BIT3 =
1 ; this, regardless of the line impedance. Moreover
the metering signal is ramped at the beginningand
at the end of each pulse to prevent undesirableclicking noise ; the slope is determined by the value of
CINT (see the external component list of L3030).
The SLIC also provides, in the transmit direction
(fromline to 4-wire side), an amplifier to insert anexternal notch filter (series resonator) for suppressing
the 12/16kHz residual signal.
Fig. 4 shows a suggestednotch Filter configuration.
The metering pulses can be injected with a DC line
current equal to zero (ON-HOOK Operation).
If teletax is not used the notch filter can be replaced
by a 1KΩ resistor.
Inconversationmode theAC impedanceatthe lineterminals,ZML,issynthetizedbytheexternalcomponents
ZAC and RP, according to the following formula :
ZML = ZAC + (RP1 + RP2)
Dependingon the characteristic of the ZAC network,
ZML canbe eithera pure resistance or a complex impedance,soallowing ST SLICtomeetdifferentstandards as far as the return loss is concerned. The
capacitorCCOMP guaranteesstability to the system.
The two-to-four wire conversion is achieved by means of a Wheatstone bridge configuration,the sides
of which being :
1) the line impedance (Zline),
2) the SLIC impedance at line terminals (ZML),
3) thenetworkZA connectedbetweenpin 36and 41
of L3030 (see externalcomponentlist of L3030),
4) the network ZB between pin 36 and ground that
shall copy the line impedance.
For a perfectbalancing,the following equationshall
be verified :
ZA ZML
=
ZB Zline
It is important to underline that ZA and ZB are not
obliged to be equal to ZML and to Zline, but they
both may be multiplied by a factor (up to ten) so allowing use of smaller capacitors.
Inconversation,the L3000Sdissipatesabout250mW
foritsownoperation; thedissipationdependingonthe
current supplied to the line shall be added.
The fig 5 and fig 6 show the DC characteristicfor two
different Feeding resistance.
2 x 200 Ohm and 2 x 400 respectively.
Figure 3 : DC Characteristic (b.b.)
ILIM = 25/30/45/70mA.
Figure 4 : ExternalTeletaxe Filter.
f=
L=
1
LxC
2π √

R2 x R4 xR5
xC2
R3
9/29
L3000S - L3030
Figure 5 : DC Characteristic for 2 x 200 ohm Feeding System.
Figure 6 : DC Characteristic for 2 x 400 ohm Feeding System.
Figure 7 : Line Current Versus Loop Resistance, RFS = 200Ω, RP = 30Ω, VB– = –48V.
10/29
L3000S - L3030
Ringing Mode
When ringingis selected(BIT2R= 1,BIT0R = 0), the
control unit L3030 presets the L3000S to operate
between – 48V (– 60V) and + 72V (+ 60V) battery.
Then,settingBIT1 =1, a low levelsignal(0.285Vrms
with frequency range 16-66Hz) applied to pin 41, is
amplified and injected in balancedmode to the line
throughL3000S with a superimposedDC voltageof
24V. The impedance to the line is given by the two
external resistors and the 24V DC polarity can only
be direct.
The first and the lastringing cycles aresynchronized
by L3030 so that ringing always starts and stops at
zero crossing. Ring trip detection is performed autonomouslyby the SLIC,without anyparticularcommand, using a patented system ; when handset is
lifted, SLIC suspends the ringing signal just remaining inthe ringingmode. Inthiscondition,the control
unit L3030 checks that the loop is closed for a time
equal to two periods of the ringing signal ; if the closure is confirmed, a flag (BIT0T = 1) is set and the
SLIC waits the new command from the control processor. Whereas the loop closure is not confirmed,
the ringing signalis newly appliedto theline, without
setting BIT0T.
DIGITAL INTERFACE
Functional Description
The L3030 states and functions are controlled by
central processor through five wires defining a digital interface.It is possibleto select the interfaceworking mode between SERIAL or PARALLEL (pin 33
tied to a voltage between 4 and 5V).
1) Serial Mode
The five wires of the digital interface have the following functions :
- clock (DCLK), entering at pin 21
- data in/data out (DIO), exchanged at pin 20
- input/outputselect (EIA), entering at pin 18
- chip select (NCS), entering at pin 19
- change NCS from in to out (CI), entering at pin 26
(note 1)
The maximum clock frequency is 600Khz.
When EIAsignal is low data are transferredfrom the
card controller into I/O registers of the L3030 selected by NCS signal tied at low level ; then data are
latched for execution.In this phasea complete 8 bit
word is loaded into internalregister and consequently NCS signal must remain low for the corresponding 8 clock pulses (DCLK). The EIA signal must
remain at low level at least for the time in whichNCS
signal remain low. The device load data in input register during the positive edge of clock signal
(DCLK) and store the contents of the register on the
positive edge of NCS signal.
When EIA signal is high data are transferred from
the L3030 selected by NCS tied to low level to the
card controller. The L3030 status is described by
five bits contained in the output register ; the NCS
signalcan remain low for fiveor lessclockpulsesdepending if the card controller want to read the complete L3030 status or only a part of it.
Fig. 8, 9 showthe completewrite and read operation
timing. Table 1 shows the meaning of each bit of an
I/O data.
11/29
L3000S - L3030
Table 1 : Serial Mode.
Meaning
Value
Data in (note 2)
BIT0R = Impedance (note 3)
0 - Stand-by/ringing
1 - Conversation
BIT1R = TTX & Ring Timing (note 4)
0 - Timing off
BIT2R = Ring (note 5)
0 - TTX Signal Injection
1 - Timing on
1 - Ring Signal Injection
BIT3R = TTX Level
0 - Low Amplitude (2VRMS)
1 - High Amplitude (5V RMS)
BIT4R = Battery Polarity
0 - Normal Polarity
1 - Reverse Polarity
BIT5R = Extra Feeding
0 - Normal Battery
1 - Boosted Battery
BIT6R
BIT7R
Current
Limiting
0
25mA
0
0
30mA
1
1
45mA
1
1
70mA
0
Data Out (note 6)
BIT0T = Line Supervision
0 - On Hook
1 - Off Hook
BIT1T = Ground Key
1 - Long. Line Current < 17mA
0 - Long. Line Current > 17mA
BIT2T = Internal Line Current Limiter (note7)
0 - Off
1 - On
BIT3T = Line Voltage
0 - Normal
1 - Minus of Half Battery
BIT4T = Thermal Overload (note 8)
1 - Off
0 - On
No tes : 1. When C I si gnal i s tied to low level, NC S signal is the chip select i nput ; with CI signal at high level, the NCS signal
becomes an output that carry out the logi cal sum of the foll owing bi ts : B IT0T , BIT1T.
2. The description of the commands is ref erred to the system L3030 + LINE IN TERF ACE module.
3. To set SBY mode wi th I lim = 7mA : BIT0R = 0 and at least one of the tw o l ast bits (B IT 6R ; BIT 7R) must be set to 1.
4. TTX and R ING signals are i njected i nto t he line interface module wi th BIT1R t o ”1”.
5. To set RIN G mode at l east one of the three last bi ts (BIT 5R, BIT 6R, BIT 7R) must be set t o 1, i n addi ti on B IT0R
must be set to 0.
6. The description of the commands is ref erred to the system L3030 + LINE IN TERF ACE module.
7. The bit BIT 2T is set to 1 w hen the SLI C is oper ating in Conver sation Mode and into the l imiti ng curr ent region (short
loop) .
8. The bit BI T4T is set to 1 when the junction temper ature of L3000S i s about 140°C.
12/29
L3000S - L3030
Figure 8 : Writing Operation Timing (serial mode).
Figure 9 : Reading Operation Timing (serial mode).
13/29
L3000S - L3030
2) Parallel Mode
In this operating mode the signals at the inputs are
immediately executed,without any external clock timing ; all the internalregisters are bypassed.The informations sent back on pins 19 and 20, display in
real time the setting of internal circuits, that means
line status. In the table 2 the correspondence between the interface wires in the parallel mode and
equivalent bit in serial mode is pointed out ; where
there isn’t this correspondence, the internal setting
is shown.
This operating mode is enabled connecting pin 33
to a voltagein the rangefrom 4V to 5V. Thefive wire
have the following functions :
- power down/feeding (EIA), entering at pin 18
- timing (CI), entering at pin 26
- ring (DCLK), entering at pin 21
- on-hook/off-hook(NCS), outgoing at pin 19
- ground-key (DIO), outgoing at pin 20
Table 2 : Parallel Mode.
Pin
Rif.
18
EIA
Meaning (note 1)
Eq. Bit of Ser. Interf.
PD/feeding
BIT0R
Value
0 : High Impedance
1 : Low Impedance
26
CI
21
DCKL
Timing
BIT1R
0 : Ring Timing Off
Ring
BIT2R
0 : No Ring
1 : Ring Timing On
1 : Ring Injection
BIT3R
0 : Low Amplitude
BIT4R
0 : Normal Polarity
BIT5R
0 : Normal Battery
BIT6R
0:
1:
BIT7R
19
NCS
On-hook/off-hook
BIT0T
Line Curr. = 30mA
0 : On-hook
1 : Off-hook
20
DIO
Ground Key
BIT1T
1 : Long. Curr. < 17mA
0 : Long. Curr. > 17mA
BIT2T
BIT3T
BIT4T
Note :
1. The description of the commands is referred to the system L3030 + LINE INTERFACE module.
DIGITAL INTERFACE ELECTRICAL CHARACTERISTICS
(VDD = + 5V, VSS = – 5V, T amb. = 25oC) (refer to PLCC44 package)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
0
0.8
V
2.0
5
V
STATIC ELECTRICAL CHARACTERISTICS
Vil
Input Voltage at Logical ”0”
Vih
Input Voltage at Logical ”1”
Iil
Input Current at Logical ”0”
Vil = 0V
200
µA
Iih
Input Current at Logical ”1”
Vih = 5V
10
µA
Vol
Output Voltage at Logical ”0”
Pins 19, 20 Iout = – 1mA
0.4
V
Voh
Output Voltage at Logical ”1”
Pins 19, 20 Iout = 1mA
Tristate Leak. Current
Pin 20 NCS = ”1”
Ilk
14/29
Pins 18, 19, 20, 21, 26
2.4
V
10
µA
L3000S - L3030
DIGITAL INTERFACE ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
600
kHz
50
ns
DYNAMIC ELECTRICAL CHARACTERISTICS
fclk
Tr, Tf
Twh, Twl
Clock Frequency
1
Clock Rise and Fall Time
Clock Impulse Width
750
ns
Tis
CI to NCS Set up Time
300
ns
Tec
”0” EIA to DCKL Set up Time
300
ns
Tsc
DCKL to NCS Delay (+ edge)
300
ns
Tsd
Data in Set up Time
0
ns
Thd
Data in Hold Time
800
ns
Tcs
NCS to DCKL Hold Time
800
ns
Tca
”0” EIA to DCKL Hold Time
900
ns
Tac
”1” EIA to DCKL Set up Time
400
Tzd
Data out to ”0” NCS Delay
0
Tce
”1” EIA to DCKL Hold Time
900
Tdz
Data out to ”1” NCS Delay
500
ns
Tdd
Data out to DCKL Delay
1500
ns
Tsi
”0” CI to NCS Hold Time
OPERATION DESCRIPTION
To set SLIC in operation the following parameters
have to be defined :
- the DC feedingresistance RFS, definedas the resistance of each side of the traditional feeding system (most common values are 200, 400 or 500
ohm).
- the AC impedanceat line terminals, ZML, to which
the return loss measurement references.It can be
real (typically 600 ohm) or complex.
- the equivalent AC impedance of the line Zline,
when evaluating the trans hybrid loss (2/4 wire
300
ns
600
ns
ns
ns
conversion). It is usually a complex impedance.
- the ringing signal frequency Fr (ST SLIC allows
frequency ranging from 16 to 66Hz).
- the metering pulse frequency Ft (two values are
possible : 12kHz or 16kHz).
- the value of the two resistors RP1/RP2 in series
with the line terminals ; main purpose of the a.m.
resistors is to allow primary protection to fire. ST
suggest the minimum value of 50 ohm for each
side.
On this assumptions,the following componentlistis
defined.
15/29
L3000S - L3030
EXTERNAL COMPONENT LIST FOR THE LINE INTERFACE
Component
Pin
Ref.
Value
Involved Parameter or Function
L3000S
10
RREF
24.9kΩ ± 1%
1,15
RP
30 to 100Ω
Line Series Resistor
7
CDVB
47µF – 20V
Battery Voltage Rejection
3
CVB+
0.1µF – 100V (1)
Positive Battery Filter
8
CVB–
Negative Battery Filter
8
D1
0.1µF – 100V (2)
BAT 49X
4-3
CVSS
0.1µF – 15V
Negative Supply Voltage Filter
5-3
CVDD
0.1µF – 15V
Positive Supply Voltage Filter
7-8
RR
16KΩ (range: 10 to 50KΩ)
Capacitor Multiplier Gain (8)
15-17
RDC
2 x (RFS – RP1)
CAC1 (3)
1
6.28 x 250 x (ZAC+ RDC)
Bias Resistance
Protective Shottky Diode
L3030 (PLCC44)
7-15
14-15
CAC2
CAC1
8-9
8-9
9-14
2-3
ZAC
CCOMP
RPC
RREF
ZML – (RP1 + RP2)
1/(6.28 x 150000 x (RPC))
RP1 + RP2
36-3
36-41
ZB
ZL
DC Feeding Resistor (RDC > 270Ω)
AC Path decoupling
2 Wire AC impedance
AC loop compensation
Rp insertion loss compensation
Bias Resistance
32-3
CINT
24.9KΩ 1%
K x Zline (note 4)
K x RPC in Series with
K x ZAC // (CCOMP/K)
(note 6)
15-16
Ccon
0.15µF (note 7)
35
TTx FILT.
ZTTX = 1kΩ 1% in speech band
ZTTX ≈ 0Ω at TTX freq. (note 9)
Teletax filter.
34
R GTTX
10kΩ 1%
Teletax filter.
Line Impedance Balancing Network
SLIC Impedance Balancing Network (note 5)
Ring trip detection time constant
Interface Time Constant
Notes :
1. In case l ine cards wi th less than 7 subscri bers are i mplemented CVB – capaci tor should be equal to 680nF/N where
N i s the number of subscri ber per car d.
2. This shot tky diode or equivalent is necessar y to avoid to damage to t he devi ce dur ing hot insertion or in all t hose
cases when a proper power up sequence cannot be guaranteed.
In case the shottky di ode i s not impl emented the power sequence should guarantee that V B+ is always the last
supply appl ied at pow er on and t he fi rst removed at power off.
In case an ot her shot tky diode type i s adopted it must fulf il l the foll owing character isti cs:
VF < 450mV @ I F = n ⋅ 15mA, T amb = 25°C
VF < 350mV @ I F = n ⋅ 15mA, T amb = 50°C (T jL 30 0 0 = 90°C)
VF < 245mV @ I F = n ⋅ 15mA, T amb = 85°C (T jL 30 0 0 = 120°C )
Where n i s the number of line shari ng the same diode.
3. If the internal capacit y mul tipli er stage i s not used, pin 7 must be connect ed w ith pin 14 without mounting R R and
CAC 2. In thi s case C AC1 = 1/(6.28 x 30 x RD C).
4. The str ucture of thi s network shall copy the line impedance, in case mul tiplied by a factor K = 1....10
5. K as fixed at note 4.
6. CINT can have the f ollowi ng values :
Fr. (Hz)
16/18
18/21
21/26
26/31
31/38
38/46
46/57
57/66
CINT (nF)
560
470
390
330
270
220
180
150
7. Ccon is necessary to w ork ”w it hout on/off hook det ection- error s” during T TX-pul ses.
8. RR is used by a capaci tor multiplier ci rcuit to synthetize an hi gher AC /DC split ting capacit or st arti ng from CA C1
and CAC 2. Supposi ng CAC1 = CAC2 = CA C the synt heti zed capacitor value will be equal
9. If Teletax is not used t he T TX F ILT. can be r eplaced by a 1kΩ resi stor.
16/29
R R + ZML
ZML
⋅ CA C .
L3000S - L3030
Figure 10 : Typical Application Schematic Diagram.
L3000S
Figure 11 : Typical Application Schematic Diagram without Capacitor Multiplier.
L3000S
17/29
L3000S - L3030
ELECTRICAL CHARACTERISTICS (refer to the test circuits of the Figure 12, VDD = + 5V, VSS = 5V, VB+ = + 72V, VB– = – 48V, Tamb = + 25oC, TTX FILT = 1kΩ)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
30.0
28.2
40.0
38.5
V
V
5
8.5
mA
5
8.5
mA
.75
V
2
mA
35.0
28.8
17.5
V
V
V
+ 15%
mA
8
mA
STAND-BY
Vls
Output Voltage at L3000S
Terminals
Iline = 0mA
Iline = 5mA
Ilcc
Short Circuit Current
DATA IN (note 1) 000X00X1
Iot
On/off-hook Detection Threshold
Vls
Symmetry to Ground
Iline = 0mA
STAND BY DENIAL
Ilcc
Short Circuit Current
DATA IN 000X00X0
DC OPERATION - NORMAL BATTERY (V TTX = 2VRMS, low level)
Vlo
Output Voltage at L3000S
Terminals Ilim = 70mA Data in
1000X010
Ilim
Current Programmed Through
the Digital Inter.
Io
On-hook Detection Threshold
If
Off-hook Detection Threshold
12
Ilgk
Longitudinal Line Current with
GK Detect
10
Iline = 0mA
Iline = 20mA
Iline = 50mA
31.0
24.0
2.5
– 10%
Ilim
mA
17
26
mA
95.6
81
V
V
10
Ω
DC OPERATION - BOOST BATTERY
Vlo
Output Voltage at L3000S
Terminals
Iline = 0mA
Iline = 20mA
86
68.6
AC OPERATION
Ztx
Sending Output Impedance
4 Wire Side
Zrx
Receiving Input Impedance
4 Wire Side
THD
Signal Distorsion at 2W and 4W
Terminals
100
kΩ
0.5
%
R1
2W Return Loss
f = 300 to 3400Hz
22
dB
Thl
Trans Hybrid Loss
f = 300 to 3400Hz
24
dB
Gs
Sending Gain
Vso = 0dBm f = 1020Hz
Norm. Polarity
dB
– 0.25
+ 0.25
Gsf
Sending Gain Flatness versus
Frequency
f = 300 to 3400Hz Respect
to 1020Hz
– 0.1
+ 0.1
dB
Gsl
Sending Gain Linearity
fr = 1020Hz,
Vsoref = –10dBm
Vso = + 4 /– 40dBm
– 0.1
+ 0.1
dB
Gr
Receiving Gain
Vri = 0dBm f = 1020Hz
Norm. Polarity
Grf
Receiving Gain Flatness
f = 300 to 3400Hz Respect
to 1020
dB
– 0.25
– 0.1
0
+ 0.25
+ 0.1
No tes : 1. The data into t he digital interface of L3030 are send i n serial mode. T he f ormat of dat a is the foll ow ing :
a) DAT A IN : the bit at left side is BIT 0 of the wri ting w ord, whil e the bit at the ri ght si de i s B IT 7.
b) DAT A OUT : the bit at the left side is BI T0 of the reading wor d, whil e the bit at the ri ght i s BI T4.
When appear a symbol X, the val ue of the bit don’ t care.
18/29
dB
L3000S - L3030
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Conditions
Min.
fr = 1020Hz, Vriref = – 10dBm
Vri = + 4 /– 40dBm
– 0.1
Typ.
Max.
Unit
+ 0.1
dB
AC OPERATION (continued)
Grl
Receiving Gain Linearity
Np4W
Psophometric Noise at 4W-Tx
Terminals
– 75
– 70
dBmp
Np2W
Psophometric Noise at Line Terminals
– 75
– 70
dBmp
SVRR
Supply Voltage Rejection Ratio
Relative to VB–
f = 3400Hz
– 30
dB
SVRR
Relative to VDD
– 30
– 26
dB
SVRR
Relative to VSS
f = 3400Hz
Vs = 100mVrms
– 32
– 30
Ltc
Longitudinal to Transversal Conversion
Tlc
Transversal to Longitudinal Conversion
Td
Propagation Time
Tdd
Propag. Time Distortion
Vttx
Line Voltage of Teletaxe Signal
VTTXin = 950mVrms
THD
Teletaxe Signal Harmonic
Dist. ttx Filt = 0Ω @ 16kHz
Note 4
Teletaxe Amplif. Input Impedance
Pin 33 of L3030
Zitt
f = 300 to 3400Hz
Iline = 30mA, ZML = 600Ω
49 (1)
60
48
51
Both Direction
Note 2
Note 3
1.7
4.5
dB
dB
dB
40
µs
25
µs
2.3
5.5
V
V
5
%
100
kΩ
AC OPERATION BOOST BATTERY
Gs
Sending Gain
Vso = 0dBm f = 1020Hz
Norm. Polarity
– 0.66 – 0.16 + 0.34
dB
Gr
Receiving Gain
Vri = 0dBm f = 1020Hz
Norm. Polarity
– 0.27 + 0.08 + 0.43
dB
Np4W
Psophometric Noise at 4W-Tx
Terminals
– 73
– 68
dBmp
Np2W
Psophometric Noise at line Terminals
– 73
– 68
dB
SVRR
Relative to Vdd
– 23
dB
SVRR
Relative to Vss
– 23
dB
27
25
V
V
f = 3400Hz
Vs = 100mVrms
RINGING PHASE
Vlr
Vacr
If
Superimposed DC Voltage
Rloop > 100kΩ
Rloop = 1kΩ
19
17
Ringing Signal at Line Termin.
Rloop = 1kΩ/1µF
56
23
21
Vrms
DC Off-hook Det. Threshold
1.5
3.5
mA
Ilim
Current Limit.
85
130
mA
Vrs
Ringing Simmetry
2
Vrms
5
%
THDr
No tes : 1.
2.
3.
4.
Ringing Signal Distortion
VAC = 0.285VRMS
fRING = 30Hz
Up to 52dB using selected L3000S.
The configurat ion of data sent t o devi ce change, every 100mS, from - 1100X010 - to - 1000X010 The configurat ion of data sent t o devi ce change, every 100mS, from - 1101X010 - to - 1001X010 Error generated by t tx fil t ≠ 0 ohm, on t he output tel etax amplitude is err% = 100 x ( 1 + A) x B/ C where A = 10
Kohm/R GTT X[ Kohm], B = TT XF ILT[Kohm], C = ( TTXF ILT[Kohm] + 1 Kohm), for example 10 ohm means err% = 2 %.
19/29
L3000S - L3030
ELECTRICAL CHARACTERISTICS (continued)
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Unit
600
mV
125
(2T)
ms
125
(2T)
ms
188
(3T)
ms
RINGING PHASE
Zir
Ringing Amplif. Input Impedance
Vrr
Residual of Ringing Signal at TX
Output
Trt
Ring Trip Detection Time
Toh
Off-hook Status Delay after the
Ringing Stop
Trs
Cut off of Ringing
Pin 41 of L3030
fring = 16Hz
T = 1/fring
100
kΩ
(1T)
Ring Trip not Confirmed
SUPPLY CURRENT
IDD
Positive Supply Current CS = 1
Stand-by
Conversation (NB/BB)
Ringing
16.0
26.0
16.5
20.0
31.0
21.0
mA
mA
mA
ISS
Negative Supply Current CS = 1
Stand-by
Conversation (NB/BB)
Ringing
9
19
9
12
23
12
mA
mA
mA
IBAT–
Negative Battery Supply Current Line
Current = 0mA
Stand-by
Conversation NB
Conversation BB
Ringing
2
5
6.6
14
2.5
6.5
8.0
17
mA
mA
mA
mA
IBAT+
Positive Battery Supply Current Line
Current = 0mA
Stand by
Conversation NB
Conversation BB
Ringing
10
10
8
12
15
15
10
13.5
µA
µA
mA
mA
NB = Normal Batter y
BB = Boosted Bat tery
Figure 12 : Slic Test Circuit Schematic.
L3000S
20/29
16
8
10
9
14
13
11
BCLK
FSR
DR0
DR1
CS
CCLK
CO
17
22
Fsx
12
21
TSX1
CI
20
MCLK
19
DX1
18
TSX0
DX0
VSS
IL4
IL5
24
23
MR
IL3
6
15
IL2
IL1
IL0
VRING=
285mVrms
VFRO
7
25
26
2
28
100nF
CTL
(*)
RDC
ZB
CINT
CAC1
RPC
ZAC
CCOMP
ZA
RDC
RC
CM
ZAC
ACF
CZS
RX
ZB
CRTS
EIA
17
15
14
9
8
7
41
36
32
NCS
33
19
40
DIO
20
21
AGND
DCLK
L3030
TX
CI
3
26
TO/FROM CARD CONTROLLER
18
TTXIN
(*) The analog multiplexer can be avoided if the VRING = 285mVRMS is provided by the CODEC.
TS5070
GND
VCC
+5V
100nF 100nF
-5V
16
27
28
31
13
42
34
35
5
4
2
VDD
D94TL126
IT
IT
C2
IL
VIN
VBIM
REF
RH
AGND
VDD
4
VB+
VB+
3
13
11
12
14
6
7
10
9
2
1
8
15
L3000S
L3000N
5
BGND
C1
CCON
RGTTX
TTX
FILTER
CVDD
VSS
CVSS
CDVB
C1
C2
IL
VOUT
VBIM
RGTTX
TTXF
VDD
VSS
REF
RL
BGND
20Ω
D1
CVB-
RING 20Ω
MNT
TIP
VB-
CVB+
VB-
VB-
1
2
4
L3121
3
30Ω
22nF
22nF
BGND
30Ω
3
1
4
L3121
2
VB+
L3000S - L3030
Figure 13: Typical application schematic with 2nd generation COMBO.
21/29
22/29
FSX
FSR
BCLKR/
BCLK
MCLKR/
MCLKX
TSX
DR
DX
V SS
+5V
ETC5057
R4
VFXI+
R2
R1
VFRO
GSX
VFXI-
(**)
C
CTL
(FROM
CARD
CONTR.)
VRING=
285mVrms
(*)
R3
RDC
ZB
CINT
CAC1
RPC
ZAC
CCOMP
ZA
RDC
RC
CM
ZAC
ACF
CZS
RX
ZB
CRTS
EIA
17
15
14
9
8
7
41
36
32
NCS
33
19
40
DIO
20
21
AGND
DCLK
L3030
TX
CI
3
26
TO/FROM CARD CONTROLLER
18
TTXIN
(*) Resistors R1 to R4 program IX/RX gains ZA, ZB shold be >>than R2.
(**) The analog multiplexer can be avoided if the VRING = 285mVRMS is provided by the CODEC.
GNDA VCC
100nF 100nF
-5V
2
16
27
28
31
13
42
34
35
5
4
VDD
C1
IT
C1
IT
D94TL127A
C2
C2
VIN
VBIM
REF
RH
AGND
VDD
4
VB+
VB+
3
13
11
12
14
6
7
10
9
5
2
1
8
15
L3000S
L3000N
BGND
IL
CCON
RGTTX
TTX
FILTER
CVDD
VSS
CVSS
CDVB
IL
VOUT
VBIM
RGTTX
TTXF
VDD
VSS
REF
RL
BGND
20Ω
D1
CVB-
RING 20Ω
MNT
TIP
VB-
CVB+
VB-
VB-
1
2
L3121 4
3
30Ω
22nF
22nF
BGND
30Ω
3
1
4
L3121
2
VB+
L3000S - L3030
Figure 14: Typical application schematic with 1st generation COMBO.
L3000S - L3030
APPENDIX
SLIC TEST CIRCUITS
Referring to the test circuit reported at the end of each SLIC data sheet here below you can find the proper
configuration for each measurement.
In particular : A-B : Line terminals
C : TX sending output on 4W side
D : RX receiving input on 4W side
E : TTX teletaxe signal input
RGIN : low level ringing signal input.
TEST CIRCUITS
Figure 1 : Symmetry to Ground.
Figure 2 : 2W Return Loss.
RL = 20 log
1
WC
Figure 3 : Trans-hybrid Loss.
THL = 20 log10
|VS|
|VR|
|ZL − Z|
|2 VS |
= 20 log
|E|
|ZL + Z|
<< Z
Figure 4 : SendingGain.
GS = 20 log10
|VR|
|VSO|
23/29
L3000S - L3030
TEST CIRCUITS (continued)
Figure 5 : Receiving Gain.
GR = 20 log10
| VR |
| VS |
Figure 7 : Longitudinalto Transversal Conversion.
L
T
= 20 log
| VR |
|E|
Figure 9 : TTX Level at Line Terminals.
24/29
Figure 6 : SVRR Relative to Battery Voltage VB–.
SVRR = 20 log
| Vn |
| VR |
Figure 8 : Transversal to Longitudinal Conversion.
T
L
= 20 log10
| VR |
| VS |
Figure 10 : Ringing Simmetry.
L3000S - L3030
PLCC44 PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
TYP.
inch
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
0.101
0.004
M
1.16
0.046
M1
1.14
0.045
25/29
L3000S - L3030
FLEXIWATT 15 PACKAGE MECHANICAL DATA
DIM.
mm
TYP.
MIN.
MAX.
5.00
1.90
0.1
A
B
b1
D
MAX.
0.196
0.074
0.004
4° (typ.)
E
F
F1
G
G1
H1
H2
H3
H4
L
L1
L2
L3
N1
N3
N4
Dia1
0.30
0.90
1.77
0.012
0.035
1.9
26.77
29.00
28.00
17.00
0.80
19.05
1.10
2.60
15.35
0.57
2.03
0.070
19.95
1.40
2.90
15.65
0.75
0.043
0.102
0.604
0.022
0.080
0.075
1.054
1.142
1.102
0.669
0.031
0.785
0.055
0.114
0.616
10
6.8
3.8
13.00
0.394
0.268
0.15
0.511
H1
H2
H3
Dia.2
Dia.4
A
b1
L
Dia.3
F
G
L2
L1
N3
L3
Dia.1
H4
N4
N1
inch
TYP.
MIN.
F1
B
G1
D
FLEX15
D
26/29
E
L3000S - L3030
PowerSO-20 (slug-up) PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
inch
TYP.
MAX.
A
MIN.
TYP.
MAX.
3.70
0.145
a1
0
0.25
0
0.01
b
0.40
0.53
0.016
0.021
c
0.23
0.32
0.009
0.012
D
15.80
16.00
0.622
0.63
D1
9.4
9.80
0.37
0.385
E
13.90
14.50
0.547
0.57
e
1.27
0.05
e3
11.43
0.45
E1
10.90
11.10
E2
0.429
0.437
2.90
0.114
E3
5.80
6.20
0.228
G
0
0.10
0
h
0.244
0.004
1.10
L
0.80
0.043
1.10
0.031
N
10° (Max.)
S
8° (Max.)
N
0.043
E3 (slug width)
N
A
b
c
e
a1
DETAILA
E
e3
h x 45°
1
10
DETAILA
E2
E1
0.35
Gage Plane
- C-
S
L
SEATING PLANE
G
20
D1(slug width)
C
(COPLANARITY)
11
PSO20DME
D
27/29
L3000S - L3030
PowerSO20 (slug-down) PACKAGE MECHANICAL DATA
mm
DIM.
MIN.
inch
TYP.
MAX.
A
MIN.
TYP.
MAX.
3.60
a1
0.10
0.1417
0.30
a2
0.0039
0.0118
3.30
0.1299
a3
0
0.10
0
0.0039
b
0.40
0.53
0.0157
0.0209
c
0.23
0.32
0.009
0.0126
D (1)
15.80
16.00
0.6220
0.6299
E
13.90
14.50
0.5472
0.570
e
1.27
e3
0.050
11.43
E1 (1)
0.450
10.90
11.10
E2
0.4291
0.437
2.90
G
0
0.1141
0.10
h
0
0.0039
0.0314
0.0433
1.10
L
0.80
1.10
N
10° (max.)
S
8° (max.)
T
10.0
0.3937
(1) ”D and E1” do not include mold flash or protrusions
- Mold flash or protrusions shall not exceed 0.15mm (0.006”)
N
R
N
a2
b
DETAIL A
A
e
c
a1
DETAIL B
E
e3
D
DETAIL A
lead
20
11
slug
a3
DETAILB
E2
E1
0.35
Gage Plane
T
- C-
S
L
SEATING PLANE
G
C
(COPLANARITY)
1
10
PSO20MEC
h x 45°
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L3000S - L3030
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 rig hts 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. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. SGS-THOMSON 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
PowerSO-20 is a Trademark of the SGS-THOMSON Microelectronics
SGS-THOMSON Microelectronics GROUP OF COMPANIES
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