BOURNS TISPPBL2D

TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
PROGRAMMABLE OVERVOLTAGE PROTECTION FOR ERICSSON COMPONENTS
SUBSCRIBER LINE INTERFACE CIRCUITS, SLICS
●
Overvoltage Protectors for listed SLICs:SLIC †§
TISPPBL1
TISPPBL2
PBL 386 50/2
û
û
û
û
ü
ü
ü
ü
û
û
ü
ü
û
û
û
û
û
û
û
PBL 386 61/2
< 55 mA‡
PBL 386 65/2
< 55 mA‡
PBL 387 10/1
û
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
PBL 3762A/2
PBL 3762A/4
PBL 3764A/4
PBL 3764A/6
PBL 3766
PBL 3766/6
PBL 3767
PBL 3767/6
PBL 3860A/1
PBL 3860A/6
PBL 386 10/2
PBL 386 11/2
PBL 386 14/2
PBL 386 15/2
PBL 386 20/2
PBL 386 21/2
PBL 386 30/2
PBL 386 40/2
D PACKAGE
(TOP VIEW)
K1
K1 (Tip)
1
8
2
7
A
(Ground)
NC
3
6
A
(Ground)
(Ring) K2
4
5
K2 (Ring)
(Tip)
(Gate) G
MD6XANA
NC - No internal connection
Terminal typical application names shown in
parenthesis
P PACKAGE
(TOP VIEW)
(Tip)
K1
1
8
K1 (Tip)
2
7
A
(Ground)
NC
3
6
A
(Ground)
(Ring) K2
4
5
K2 (Ring)
(Gate) G
MD6XAV
NC - No internal connection
Terminal typical application names shown in
parenthesis
device symbol
K1
K1
A
G1,G2
A
§ See Applications Information for earlier SLIC types.
‡ Use TISPPBL2 when programmed line current is
above 55 mA
K2
●
Rated for International Surge Wave Shapes
WAVE SHAPE
2/10 µs
●
●
STANDARD
Terminals K1, K2 and A correspond to the alternative
line designators of T, R and G or A, B and C. The
negative protection voltage is controlled by the
voltage, VGG, applied to the G terminal.
SD6XAEA
ITSP
A
GR-1089-CORE
100
1.2/50 µs
ITU-T K22
100
0.5/700 µs
I3124
40
10/700 µs
ITU-T K20, K21
40
10/1000 µs
GR-1089-CORE
30
Specified Impulse Limiting Voltage
- Voltage-Time Envelope Guaranteed
- Full -40 °C to 85 °C Temperature Range
UL Recognized, E195925
K2
●
Feed-Through Package Connections
- Minimises Inductive Wiring Voltages
●
Surface Mount and Through-Hole Ordering
Options
DEVICE CODE
PACKAGE AND CARRIER TYPE
TISPPBLxD
8-pin Small-Outline in a Tube
TISPPBLxDR
8-pin Small-Outline on Tape and Reeled
TISPPBLxP
8-pin Plastic DIP in a Tube
† Customers are advised to obtain the latest version of the relevant Ericsson Components SLIC information to verify, before placing orders, that
the information being relied on is current.
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
1
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
description
The TISPPBL1 and TISPPBL2 are dual forward-conducting buffered p-gate overvoltage protectors. They are
designed to protect the Ericsson Components SLICs (Subscriber Line Interface Circuits) against overvoltages
on the telephone line caused by lightning, a.c. power contact and induction. The TISPPBLx limits voltages
that exceed the SLIC supply rail levels.
The SLIC line driver section is typically powered by a negative voltage, VBat, in the region of -10 V to -85 V.
The protector gate is connected to this negative supply. This references the protection (clipping) voltage to the
negative supply voltage. As the protection voltage will track the negative supply voltage the overvoltage stress
on the SLIC is minimised. The TISPPBLx buffered gate design reduces the loading on the SLIC supply during
overvoltages caused by power cross and induction.
Positive overvoltages are clipped to ground by diode forward conduction. Negative overvoltages are initially
clipped close to the SLIC negative supply rail value. If sufficient current is available from the overvoltage, then
the protector will crowbar into a low voltage ground referenced on-state condition. As the overvoltage
subsides the high holding current of the crowbar prevents d.c. latchup. The difference between the TISPPBL1
and TISPPBL2 is the minimum value of holding current. The 105 mA TISPPBL1 can delatch SLIC
programmed line currents up to 55 mA and the 150 mA TISPPBL2 can delatch all programmed line current
values.
These monolithic protection devices are fabricated in ion-implanted planar vertical power structures for high
reliability and in normal system operation they are virtually transparent. The TISPPBLx is available in 8-pin
plastic small-outline surface mount package and 8-pin plastic dual-in-line package.
absolute maximum ratings, -40 °C ≤ TA ≤ 85 °C (unless otherwise noted)
RATING
SYMBOL
VALUE
UNIT
Repetitive peak off-state voltage, IG = 0
VDRM
-100
V
Repetitive peak gate-cathode voltage, VKA = 0
VGKRM
-90
V
Non-repetitive peak on-state pulse current (see Notes 1 and 2)
10/1000 µs (Bellcore GR-1089-CORE, Issue 2, December 1997, Section 4)
30
0.2/310 µs (I3124, open-circuit voltage wave shape 0.5/700 µs)
ITSP
5/310 µs (ITU-T K20 & K21, open-circuit voltage wave shape 10/700 µs)
40
40
1/20 µs (ITU-T K22, open-circuit voltage wave shape 1.2/50 µs)
100
2/10 µs (Bellcore GR-1089-CORE, Issue 2, December 1997, Section 4)
100
A
Non-repetitive peak on-state current, 50/60 Hz (see Notes 1 and 2)
100 ms
11
1s
ITSM
5s
300 s
4.5
A
2.4
0.95
900 s
0.93
Non-repetitive peak gate current, 1/2 µs pulse, cathodes commoned (see Note 1)
IGSM
40
A
Operating free-air temperature range
TA
-40 to +85
°C
Junction temperature
TJ
-40 to +150
°C
Tstg
-65 to +150
°C
Storage temperature range
NOTES: 1. Initially the protector must be in thermal equilibrium with -40 °C ≤ TJ ≤ 85 °C. The surge may be repeated after the device returns to
its initial conditions.
2. These non-repetitive rated currents are peak values for either polarity. The rated current values may be applied either to the Ring to
Ground or to the Tip to Ground terminal pairs. Additionally, both terminal pairs may have their rated current values applied
simultaneously (in this case the Ground terminal current will be twice the rated current value of an individual terminal pair). Above
85 °C, derate linearly to zero at 150 °C lead temperature.
PRODUCT
2
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
recommended operating conditions
SEE Figure 18
C1
R1a
R1b
Gate decoupling capacitor
MIN
TYP
100
220
Series resistance for GR-1089-CORE first-level and second-level surge survival
40
Series resistance for GR-1089-CORE first-level surge survival
25
Series resistance for ITU-T recommendation K20/21
10
MAX
UNIT
nF
Ω
electrical characteristics, -40 °C ≤TA ≤ 85 °C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TJ = 85 °C
-50
µA
-70
V
1
µs
IF = 5 A, tw = 500 µs
3
V
IF = 20 A, 0.5/700 generator, Figure 3 test circuit (See Figure 2)
8
V
VD = VDRM, VGK = 0
V(BO)
Breakover voltage
IT = -20 A, 0.5/700 generator, Figure 3 test circuit (See Figure 2)
t(BR)
Breakdown time
VF
Forward voltage
IT = -20 A, 0.5/700 generator, Figure 3 test circuit (See Figure 2)
voltage
IF = 20 A, 0.5/700 generator, Figure 3 test
VF > 5 V
1
VF > 1 V
10000
Forward recovery time
IH
Holding current
IT = -1 A, di/dt = 1A/ms, VGG = -50 V,
IGAS
Gate reverse current
VGG = VGKRM, VAK = 0
IGAT
on state
V(BR) < -50 V
circuit (See Figure 2)
tFR
Gate reverse current,
UNIT
µA
Off-state current
Peak forward recovery
MAX
-5
ID
VFRM
TYP
TJ = -40 °C
TISPPBL1
-105
TISPPBL2
-150
µs
mA
TJ = -40 °C
-5
µA
TJ = 85 °C
-50
µA
-1
mA
IT = -0.5 A, tw = 500 µs, VGG = -50 V, TA = 25 °C
Gate reverse current,
IGAF
forward conducting
IF = 1 A, tw = 500 µs, VGG = -50 V, TA = 25 °C
-10
mA
state
IGT
Gate trigger current
IT = -5 A, tp(g) ≥ 20 µs, VGG = -50 V, TA = 25 °C
VGT
Gate trigger voltage
IT = -5 A, tp(g) ≥ 20 µs, VGG = -50 V, TA = 25 °C
CAK
NOTE
5
Anode-cathode off-
f = 1 MHz, Vd = 1 V, IG = 0, TA = 25 °C
VD = -3 V
state capacitance
(see Note 3)
VD = -50 V
mA
2.5
V
110
pF
60
pF
3: These capacitance measurements employ a three terminal capacitance bridge incorporating a guard circuit. The unmeasured
device terminals are a.c. connected to the guard terminal of the bridge.
thermal characteristics
PARAMETER
RθJA
Junction to free air thermal resistance
PRODUCT
TEST CONDITIONS
MIN
TYP
MAX
Ptot = 0.8 W, TA = 25 °C
D Package
160
5 cm2, FR4 PCB
P Package
100
UNIT
°C/W
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
3
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
PARAMETER MEASUREMENT INFORMATION
PRINCIPAL TERMINAL V-I CHARACTERISTIC
GATE TRANSFER
CHARACTERISTIC
+iK
Quadrant I
+i
IFSP (= |ITSP|)
Forward
Conduction
Characteristic
IFSM (= |ITSM|)
IF
IF
VF
VGK(BO)
IGT
VD
VGG (Circuit VB)
-v
+v
ID
I(BO)
+i G
IGAF
IH
IS
VT
VS
V(BO)
-i G
IGAT
IT
IT
ITSM
IG
Quadrant III
Switching
Characteristic
IK
ITSP
-i
-iK
PM6XAIB
Figure 1 PRINCIPAL TERMINAL AND GATE TRANSFER CHARACTERISTICS
PROTECTOR MAXIMUM LIMITING VOLTAGE
vs
TIME
10
5
MAX VFRM = 8 V
1 µs
10 ms
VOLTAGE - V
0
-50
Time
VGG = VB = -50 V
1 µs
-60
-70
MAX V(BO) = -70 V
PM6XALB
-80
Figure 2 TRANSIENT LIMITS FOR TISPPBLx LIMITING VOLTAGE
PRODUCT
4
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
PARAMETER MEASUREMENT INFORMATION
IMPULSE
R1 CURRENT
50 Ω
IT, IF
Hi
S1
15 Ω
25 Ω
±1960 V
20 µF
20 nF
Lo
Th4
LIMITING
VOLTAGE
VK, VF
ECAT WITH E502 0.5/700 SURGE NETWORK
DUT
(TISPPBLx)
Th5
R1 = ONE SECTION OF A THICK-FILM HIGH
VOLTAGE PULSE RESISTOR NETWORK
IG
220 nF
VB (VGG)
-50 V
AI6XBACB
Figure 3 TEST CIRCUIT FOR MEASUREMENT OF LIMITING VOLTAGE
80
di/dt - Rate of Rise of Wavefront Current - A/µs
i - Wavefront Current - A
20
E502 0.5/700 WAVEFRONT CURRENT
vs
TIME
AI6XAY
15
10
5
0
0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
Time - µs
Figure 4 CURRENT WAVEFRONT
PRODUCT
E502 0.5/700 WAVEFRONT di/dt
vs
TIME
AI6XAZ
70
60
50
40
30
20
10
0
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
Time - µs
Figure 5 CURRENT WAVEFRONT di/dt
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
5
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
THERMAL INFORMATION
ITSM - Peak Non-Recurrent 60 Hz Current - A
PEAK NON-RECURRING AC
vs
CURRENT DURATION
10
TI6LACB
RING AND TIP CONNECTIONS ITSM applied simultaneously to both
GROUND CONNECTION Return current is twice ITSM
VGEN = 600 Vrms
RGEN = 70 to 950 Ω
VGG = -48 V, TAMB = 85°C
1
0·1
1
10
100
1000
t - Current Duration - s
Figure 6
PRODUCT
6
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
TYPICAL CHARACTERISTICS
VK - Cathode Voltage - V
-10
-20
50 devices tested from 10 wafer lots
0.5/700 Waveform
IT = -20 A
TA = 25°C
VGG = -50 V
DISTRIBUTION LIMITS OF
DIODE FORWARD VOLTAGE
vs
TIME
6
-30
-40
-50
4
3
2
50 devices tested from 10 wafer lots
0.5/700 Waveform
IF = 20 A
TA = 25°C
VGG = -50 V
1
-60
0
0.0 0.1 0.2 0.3
-70
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
Time - µs
Figure 7
99·9
0.9 1.0
DIODE FORWARD CURRENT
vs
FORWARD VOLTAGE
TC61AD
0.7
0.4
99
IF - Forward Current - A
Cumulative Population - %
1
50 devices tested from 10 wafer lots
IF = 20 A, IT = -20 A, 0.5/700 Waveform
TA = 25°C, VGG = -50 V
99·99
0.4 0.5 0.6 0.7 0.8
Time - µs
Figure 8
CUMULATIVE POPULATION %
vs
PEAK LIMITING VOLTAGE TC6XAB
99·999
AI6XAX
5
VF - Forward Voltage - V
0
DISTRIBUTION LIMITS OF
THYRISTOR LIMITING VOLTAGE
vs
TIME
AI6XAW
90
70
50
30
10
85°C
0.2
25°C
-40°C
0.1
0.07
0.04
1
DIODE
VFRM
0·1
THYRISTOR
VGG - V(BO)
0.02
0·01
0·001
4
5
6
7
8
9 10
Peak Limiting Voltage - V
15
Figure 9
PRODUCT
0.01
0.5
0.6
0.7
0.8
0.9
1.0
VF - Forward Voltage - V
1.1
1.2
Figure 10
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
7
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
TYPICAL CHARACTERISTICS
99·99
Cumulative Population - %
99·9
50 devices tested from 10 wafer lots
IF = 20 A, IT = -20 A, 0.5/700 Waveform
TA = 25°C, VGG = -50 V
99
90
70
50
30
10
1
0·1
0·01
DIODE tFR
for VF > 5 V
Outliers
(2) @ 0 µs
THYRISTOR t(BR)
for V(BR) < VGG
0·001
0.001
1
0.004 0.01
0.04 0.1
0.4
t(BR), tFR - Breakdown and Forward Recovery Times - µs
1.10
Normalised Peak Limiting Voltages
99·999
NORMALISED PEAK LIMITING VOLTAGES
vs
JUNCTION TEMPERATURE TC6XAA
CUMULATIVE POPULATION %
vs
LIMITING TIME
TC6XAC
1.05
1.00
0.95
Normalised to 25°C values
of V(BO) and VFRM
IF = 20 A, IT = -20 A
0.5/700 Waveform
VGG = -50 V
THYRISTOR
V(BO)
DIODE
VFRM
0.90
-40 -30 -20 -10 0
10 20 30 40 50 60 70 80
TJ - Junction Temperature - °C
Figure 11
Figure 12
APPLICATIONS INFORMATION
operation of gated protectors
The following SLIC circuit definitions are used in this data sheet:
VBAT — Package pin label for the battery supply voltage.
VBat — Voltage applied to the VBAT pin.
VB — Negative power supply voltage applied to the VBAT pin via an isolation diode. This voltage is also the
gate reference voltage, VGG, of the TISPPBLx. When the isolation diode, D1, is conducting, then
VBat = VB + 0.7.
The isolation diode, D1 in Figure 13, is to prevent a damaging current flowing into the SLIC substrate (VBAT
pin) if the VBat voltage becomes more negative than the VB supply during a negative overvoltage condition.
Each SLIC needs an isolation diode from the VB voltage supply.
Figure 13 and Figure 14 show how the TISPPBLx limits overvoltages. The TISPPBLx thyristor sections limit
negative overvoltages and the diode sections limit positive overvoltages.
Negative overvoltages (Figure 13) are initially clipped close to the SLIC negative supply rail value (VB) by the
conduction of the transistor base-emitter and the thyristor gate-cathode junctions. If sufficient current is
available from the overvoltage, then the thyristor will crowbar into a low voltage ground referenced on-state
condition. As the overvoltage subsides the high holding current of the crowbar thyristor prevents d.c. latchup.
The negative protection voltage will be the sum of the gate supply (VB) and the peak gate(terminal)-cathode
voltage (VGK(BO)). Under a.c. overvoltage conditions VGK(BO) will be less than 3 V. The integrated transistor
buffer in the TISPPBLx greatly reduces the gate positive current (from about 50 mA to 1 mA) and introduces a
negative gate current. Figure 1 shows that the TISPPBLx gate current depends on the current being
PRODUCT
8
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
conducted by the principal terminals. The gate current is positive during clipping (charging the VB supply) and
negative when the thyristor is on or the diode is conducting (loading the VB supply). Without the negative gate
current and the reduced level of positive gate current the VB supply could be charged with a current of nearly
100 mA. As the VB supply is likely to be electronic it would not be designed to be charged like a battery. As a
result, the SLIC could be destroyed by the voltage of VB increasing to a level that exceeded the SLIC’s
capability on the VBAT pin. The integrated transistor buffer removes this problem.
Fast rising impulses will cause short term overshoots in gate-cathode voltage. The negative protection
voltage under impulse conditions will also be increased if there is a long connection between the gate
decoupling capacitor, C1, and the gate terminal. During the initial rise of a fast impulse, the gate current (IG) is
the same as the cathode current (IK). Rates of 60 A/µs can cause inductive voltages of 0.6 V in 2.5 cm of
printed wiring track. To minimise this inductive voltage increase of protection voltage, the length of the
capacitor to gate terminal tracking should be minimised. Inductive voltages in the protector cathode wiring
can increase the protection voltage. These voltages can be minimised by routing the SLIC connection through
the protector as shown in Figure 13 and Figure 14.
SLIC
PROTECTION
TISPPBLx
Th4
SLIC
PROTECTION
TISPPBLx
Th4
SLIC
SLIC
IT
IF
Th5
VB
VBat
C1
D1
Th5
VB
VBat
C1
D1
C2
AI6XANB
C2
AI6XAOB
Figure 13 NEGATIVE OVERVOLTAGE CONDITION
Figure 14 POSITIVE OVERVOLTAGE CONDITION
Positive overvoltages (Figure 14) are clipped to ground by forward conduction of the diode section in the
TISPPBLx. Fast rising impulses will cause short term overshoots in forward voltage (VFRM).
TISPPBLx limiting voltages
This clause details the TISPPBLx voltage limiting levels under impulse conditions.
test circuit
Figure 3 shows the basic test circuit used for the measurement of impulse limiting voltage. During the
impulse, the high levels of electrical energy and rapid rates of change cause electrical noise to be induced or
conducted into the measurement system. It is possible for the electrical noise voltage to be many times the
wanted signal voltage. Elaborate wiring and measurement techniques where used to reduce the noise
voltage to less than 2 V peak to peak.
impulse generator
A Keytek ECAT E-Class series 100 with an E502 surge network was used for testing. The E502 produces a
0.5/700 voltage impulse. This particular waveform was used as it has the fastest rate of current rise (di/dt) of
the commonly used lightning surge waveforms. This maximises the measured limiting voltage. Figure 4
shows the current wavefront through the DUT. To produce a peak test current level of ±20 A, the E502
charging voltage was set to ±1960 V. Figure 5 shows the DUT current di/dt. Initially the wavefront current rises
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
9
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
at 60 A/µs, this rate then reduces as the peak current is approached. At the TISPPBLx V(BO) condition the
di/dt is about 50 A/µs.
limiting voltage levels
Fifty devices were measured in the test circuit of Figure 3. The 50 devices were made up from groups of 5
devices taken from 10 separately processed device lots. Figure 7 shows the total waveform variation of the
thyristor limiting voltage across the 50 devices. This shows that the largest peak limiting voltage (Breakover
voltage, V(BO)) is -62 V, a 12 V overshoot beyond the -50 V gate reference supply, VB. The limiting voltage
exceeds the gate reference supply voltage level for a period (t(BR)) of about 0.4 µs.
Figure 9 and Figure 11 show these two waveform parameters in terms of device population. In Figure 9, the
limiting voltage is shown in terms of the overshoot beyond the gate reference supply (VB - V(BO)). Removing
the gate reference voltage level magnifies the thyristor limiting voltage variation and shows the data
stratification caused by the oscilloscope digitisation. Extrapolating the data trend indicates that the overshoot
is less than 14 V at the 99.997% level (equal to 30 ppm of the population exceeding 14 V, equivalent to +4
sigma point of a normal distribution). In Figure 11, extrapolating the thyristor data trend to the 99.997% level
indicates a maximum breakdown time, t(BR), of 0.5 µs. Figure 12 shows that increasing the temperature up to
85 °C increases the thyristor peak limiting voltage by 2.4%, giving a maximum 85 °C peak limiting voltage of
1.024x(-50-14) = -65.5 V. Over the -40 °C to 85 °C temperature range the TISPPBLx is specified to have a
maximum V(BO) value of -70 V and a breakdown time, t(BR), of 1 µs.
Figure 8 shows the total waveform variation of the diode limiting voltage across the 50 devices. The peak
limiting voltage (Peak Forward Recovery Voltage VFRM) is less than 6 V, and this value includes the 2 V of
magnetically induced noise in the probe. Figure 9 shows that extrapolated 99.997% level is about 5.5 V. In
Figure 11, extrapolating the diode data trend to the 99.997% level indicates a maximum forward recovery
time, tFR, of 0.1 µs. Figure 12 indicates that there is about a 10% uplift by increasing the temperature to
85 °C. This gives a maximum 85 °C peak limiting voltage of 1.1x(5.5) = 6.1 V. Over the -40 °C to 85 °C
temperature range, the TISPPBLx is specified to have a maximum VFRM value of 8 V and a maximum forward
recovery time of 1 µs.
Diodes do not switch to a much lower voltage like thyristors, so the diode limiting voltage applies for the whole
impulse duration. Forward voltages of 1 V or less are normally considered safe. Figure 10 shows that the
lowest current 1 V condition occurs at -40 °C with a current of 0.3 A. When the TISPPBLx is tested with the
rated 10/1000 impulse it would take about 8 ms for the current to decay from 30 A to 0.3 A. Over the -40 °C to
85 °C temperature range, the TISPPBLx is specified to have a VF below 1 V within 10 ms.
SLIC protection requirements
This clause discusses the voltage withstand capabilities of the various Ericsson Components SLIC groups
and compares these to the TISPPBLx protector parameters. The examples provided are intended to provide
designers information on how the TISPPBLx protector and specific SLICs work together. Designers should
always follow the circuit design recommendations contained in the latest edition of a SLIC data sheet.
temperature range
Some SLICs are rated for 0 °C to 70 °C operation, others for -40 °C to 85 °C operation. The TISPPBLx
protector is specified for -40 °C to 85 °C operation and so covers both temperature ranges.
PRODUCT
10
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
PART NUMBER
MAXIMUM VOLTAGE RATINGS
d.c. VBAT & +2 V, < 10 ms VBAT -20 V & +5 V, < 1 µs VBAT -40 V & +10 V, < 250 ns VBAT -70 V & +15 V
TIPX or RINGX Voltage - V
PBL 3762A/2
PBL 3762A/4
PBL 3764A/4
PBL 3764A/6
PBL 3860A/1
PBL 3860A/6
PBL 386 10/2
PBL 386 11/2
PBL 386 14/2
PBL 386 15/2
PBL 386 61/2
PBL 386 65/2
PBL 387 10/1
15
10
5
0
10 ms
1 µs
0.25 µs
VBat
VBat - 10
VBat - 20
VBat - 30
VBat - 40
VBat - 50
TIPX or RINGX VOLTAGE RATING vs TIME
VBat - 60
(NEGATIVE RATING RELATIVE TO VBat )
VBat - 70
AI6XDBAA
d.c. VBAT & +0.5 V, < 10 ms VBAT -20 V & +5 V, < 1 µs VBAT -40 V & +10 V, < 250 ns VBAT -70 V & +15 V
TIPX or RINGX Voltage - V
PBL 3766
PBL 3766/6
PBL 3767
PBL 3767/6
15
10
5
0
10 ms
1 µs
Time
0.25 µs
VBat
VBat - 10
VBat - 20
VBat - 30
VBat - 40
VBat - 50
TIPX or RINGX VOLTAGE RATING vs TIME
VBat - 60
(NEGATIVE RATING RELATIVE TO VBat )
VBat - 70
AI6XDBAB
d.c. -80 V & +2 V, < 10 ms VBAT -10 V & +5 V, < 1 µs VBAT -25 V & +10 V, < 250 ns VBAT -35 V & +15 V
TIPX or RINGX Voltage - V
PBL 386 20/2
PBL 386 21/2
PBL 386 30/2
PBL 386 40/2
PBL 386 50/2
Time
15
10
5
0
10 ms
1 µs
Time
0.25 µs
VBat
- 80 V
VBat - 10
VBat - 20
VBat - 30
VBat - 40
TIPX or RINGX VOLTAGE RATING vs TIME
(NEGATIVE IMPULSE RATING RELATIVE TO VBat )
AI6XDBAC
Figure 15 TIPX AND RINGX RATED VALUES
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
11
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
normal operation
Depending on the SLIC type, the maximum SLIC supply voltage rating (VBat) will be -70 V, -80 V or -85 V. The
-90 V rating of the TISPPBLx gate-cathode (VGKRM) exceeds the highest SLIC voltage rating. To restore
normal operation after the TISPPBLx has switched on, the minimum switch-off current (holding current IH)
needed is equal to the maximum SLIC short circuit current to ground (d.c. line current together with the
maximum longitudinal current). The first page of this data sheet has a list of the appropriate TISPPBLx
protectors that can be used with each SLIC.
maximum TIPX and RINGX terminal ratings
The withstand levels of a SLIC line drive amplifier TIPX and RINGX can be expressed in terms of maximum
voltage for certain time periods. The negative voltage rating can be specified in two ways; relative to ground or
relative to the SLIC negative supply voltage (VBat).
The TIPX or RINGX voltage withstand levels for the current range of Ericsson SLICs falls into three groups,
see Figure 15. The first group, headed by the PBL 3762A/2 SLIC, has a positive polarity d.c. withstand of
+2 V. For 10 ms, the output can withstand a voltage of +5 V. For 1 µs, the output can withstand a voltage of
+10 V. For 250 ns, the output is able to withstand a voltage of +15 V.
In the negative polarity, the output can withstand VBat continuously. For 10 ms, the output can withstand a
voltage of VBat - 20 V. For 1 µs, the output can withstand a voltage of VBat - 40 V. For 250 ns, the output is
able to withstand a voltage of VBat - 70 V.
The second group, headed by the PBL 3766 SLIC, has a positive polarity d.c. withstand of +0.5 V. For 10 ms,
1 µs and 250 ns the withstand voltage is the same as the PBL 3762A/2 group. In the negative polarity the
withstand voltage of the PBL 3766 group is the same as the PBL 3762A/2 group.
The third group, headed by the PBL 386 20/2 SLIC, has the same positive polarity withstand as the
PBL 3762A/2 group. In the negative polarity, the output can withstand -80 V continuously. For 10 ms, the
output can withstand a voltage of VBat - 10 V. For 1 µs, the output can withstand a voltage of VBat - 25 V. For
250 ns, the output is able to withstand a voltage of VBat - 35 V.
protection requirements to cover all SLICs
To protect all SLICs, the TISPPBLx protector must limit the voltage to the lowest withstand levels of the three
SLIC groups shown in Figure 15. Figure 16 shows that this will be the positive polarity rating of the PBL 3766
group and the negative rating of the PBL 386 20/2 group.
.
TISPPBLx voltage limiting performance
Figure 17 shows how the TISPPBLx protection voltages compare to the minimum voltage withstands of
Figure 16. The two shaded areas represent the positive and negative maximum limiting voltage levels of the
TISPPBLx from Figure 2. The isolation diode voltage drop displaces the TISPPBLx negative limiting voltage
1 µs, -20 V pulse area by -0.7 V from VBat. So the actual negative limiting voltage is -20.7 V relative to VBat.
This value does not exceed any part of the SLIC minimum negative voltage ratings. Any negative voltage
disturbance in the VB supply caused by TISPPBLx gate current will be tracked in VBat by conduction of the
isolation diode D1. So a negative going change in VB does not substantially increase the TIPX and RINGX
voltage stress relative to VBat. However, the absolute value of VBat with respect to ground must be kept within
the data sheet rating. In the positive polarity the TISPPBLx limits the maximum voltage to 8 V in a 1 µs period
and between 1 V and 5 V for a 10 ms period. These values do not exceed any of the SLIC minimum positive
voltage ratings.
application circuit
Figure 18 shows a typical TISPPBLx SLIC card protection circuit. The incoming line conductors, R and T,
connect to the relay matrix via the series over-current protection. Fusible resistors, fuses and positive
PRODUCT
12
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
40
SLIC GROUP VOLTAGE RATINGS
vs
TIME
30
20
PBL 3766 GROUP
PBL3762A/2 AND
PBL386 20/2 GROUPS
10
Voltage - V
0
Time
10 ms
1 µs
0.25 µs
VBat
VBat - 10
VBat - 20
VBat - 30
VBat - 40
PBL 386 20/2 GROUP
VBat - 50
VBat - 60
PBL3762A/2 AND
PBL3766 GROUPS
VBat - 70
AI6XBDD
Figure 16 SLIC VOLTAGE RATINGS
40
SLIC MINIMUM VOLTAGE WITHSTAND
AND TISPPBLx VOLTAGE LIMITING
vs
TIME
30
20
TISPPBLx
10
Voltage - V
0
Time
10 ms
1 µs
0.25 µs
VBAT
0.7 V ISOLATION DIODE (D1)
VOLTAGE DROP FROM VBat
TISPPBLx
VBAT - 10
VBAT - 20
VBAT - 30
AI6XBC
VBAT - 40
Figure 17 SLIC VOLTAGE RATINGS AND TISPPBLx PROTECTION LEVELS
temperature coefficient (PTC) resistors can be used for over-current protection. Resistors will reduce the
prospective current from the surge generator for both the TISPPBLx and the ring/test protector. The
TISP7xxxF3 protector has the same protection voltage for any terminal pair. This protector is used when the
ring generator configuration may be ground or battery-backed. For dedicated ground-backed ringing
generators, the TISP3xxxF3 gives better protection as its inter-conductor protection voltage is twice the
conductor to ground value.
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
13
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
SERIES
RESISTANCE
T
WIRE
R1b
TEST
RELAY
RING
RELAY
Th1
R1a
(INCLUDES
OVERCURRENT
PROTECTION)
R
WIRE
RING/TEST
PROTECTION
SLIC
PROTECTION
Th4
S3a
S2a
S1a
Th3
SLIC
RELAY
SLIC
Th2
TISP
3xxxF3
OR
7xxxF3
Th5
S3b
S1b
S2b
TISP
PBLx
VB
TEST
EQUIPMENT
RING
GENERATOR
VBat
C1
D1
C2
AI6XAPEA
Figure 18 TYPICAL APPLICATION CIRCUIT
Relay contacts 3a and 3b connect the line conductors to the SLIC via the TISPPBLx protector. Closing
contacts 3a and 3b connects the TISPPBLx protector in parallel with the ring/test protector. As the ring/test
protector requires much higher voltages than the TISPPBLx to operate, it will only operate when the contacts
3a and 3b are open. Both protectors will divert the same levels of peak surge current and their required
current ratings should be similar. The TISPPBLx protector gate reference voltage comes from the SLIC
negative supply feed (VB). A local gate capacitor, C1, sources the gate current pulses caused by fast rising
impulses.
PRODUCT
14
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
Earlier protection recommendations
The table below lists the protection recommendations from earlier versions of the TISPPBLx data sheet.
TISPPBL1
TISPPBL2
PBL 3796
SLIC
< 55 mA‡
PBL 3796/2
< 55 mA‡
PBL 3798
< 55 mA‡
PBL 3798/2
< 55 mA‡
PBL 3798/5
< 55 mA‡
PBL 3798/6
ü
û
û
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
ü
PBL 3799
PBL 3799/2
PBL 386 20/1 ¶
PBL 386 21/1 ¶
PBL 386 30/1 ¶
PBL 386 40/1 ¶
PBL 386 50/1 ¶
¶ Product Change Notification 109 21-PBL 386 xx/1-1 Uen of 06-06-1999 improved
the silicon design of the PBL 386 20/1, PBL 386 21/1, PBL 386 30/1, PBL 386 40/1
and PBL 386 50/1. These improved devices are designated by a /2 as PBL 386 20/2,
PBL 386 21/2, PBL 386 30/2, PBL 386 40/2 and PBL 386 50/2 respectively.
‡ Use TISPPBL2 when programmed line current is above 55 mA
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
15
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
MECHANICAL DATA
D008
plastic small-outline package
This small-outline package consists of a circuit mounted on a lead frame and encapsulated within a plastic
compound. The compound will withstand soldering temperature with no deformation, and circuit performance
characteristics will remain stable when operated in high humidity conditions. Leads require no additional
cleaning or processing when used in soldered assembly.
D008
8-pin Small Outline Microelectronic Standard
Package MS-012, JEDEC Publication 95
5,00 (0.197)
4,80 (0.189)
6,20 (0.244)
5,80 (0.228)
8
7
6
5
1
2
3
4
INDEX
4,00 (0.157)
3,81 (0.150)
7° NOM
3 Places
1,75 (0.069)
1,35 (0.053)
0,203 (0.008)
0,102 (0.004)
0,79 (0.031)
0,28 (0.011)
5,21 (0.205)
4,60 (0.181)
0,50 (0.020)
x 45°NOM
0,25 (0.010)
7° NOM
4 Places
0,51 (0.020)
0,36 (0.014)
8 Places
Pin Spacing
1,27 (0.050)
(see Note A)
6 Places
0,229 (0.0090)
0,190 (0.0075)
4° ± 4°
1,12 (0.044)
0,51 (0.020)
ALL LINEAR DIMENSIONS ARE IN MILLIMETERS AND PARENTHETICALLY IN INCHES
NOTES: A.
B.
C.
D.
Leads are within 0,25 (0.010) radius of true position at maximum material condition.
Body dimensions do not include mold flash or protrusion.
Mold flash or protrusion shall not exceed 0,15 (0.006).
Lead tips to be planar within ±0,051 (0.002).
PRODUCT
16
MDXXAAC
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
MECHANICAL DATA
D008
tape dimensions
D008 Package (8-pin Small Outline) Single-Sprocket Tape
4,10
3,90
8,10
7,90
1,60
1,50
2,05
1,95
0,40
0,8 MIN.
5,60
5,40
6,50
6,30
Direction of Feed
Embossment
Cover
0 MIN.
ø 1,5 MIN.
Carrier Tape
12,30
11,70
Tape
2,2
2,0
ALL LINEAR DIMENSIONS IN MILLIMETERS
NOTES: A. Taped devices are supplied on a reel of the following dimensions:Reel diameter:
Reel hub diameter:
Reel axial hole:
MDXXATB
330 +0,0/-4,0 mm
100 ±2,0 mm
13,0 ±0,2 mm
B. 2500 devices are on a reel.
PRODUCT
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.
17
TISPPBL1D, TISPPBL1P, TISPPBL2D, TISPPBL2P
DUAL FORWARD-CONDUCTING P-GATE THYRISTORS
FOR ERICSSON COMPONENTS SLICS
MECHANICAL DATA
P008
plastic dual-in-line package
This dual-in-line package consists of a circuit mounted on a lead frame and encapsulated within a plastic
compound. The compound will withstand soldering temperature with no deformation, and circuit performance
characteristics will remain stable when operated in high humidity conditions The package is intended for
insertion in mounting-hole rows on 7,62 (0.300) centres. Once the leads are compressed and inserted,
sufficient tension is provided to secure the package in the board during soldering. Leads require no additional
cleaning or processing when used in soldered assembly.
P008
Designation per JEDEC Std 30:
PDIP-T8
10,2 (0.400) MAX
8
7
6
5
Index
Dot
C
L
1
2
3
C
L
7,87 (0.310)
7,37 (0.290)
T.P.
4
6,60 (0.260)
6,10 (0.240)
1,78 (0.070) MAX
4 Places
5,08 (0.200)
MAX
Seating
Plane
105°
90°
8 Places
0,51 (0.020)
MIN
3,17 (0.125)
MIN
2,54 (0.100) T.P.
6 Places
(see Note A)
0,36 (0.014)
0,20 (0.008)
8 Places
0,533 (0.021)
0,381 (0.015)
8 Places
ALL LINEAR DIMENSIONS ARE IN MILLIMETERS AND PARENTHETICALLY IN INCHES
NOTE A: Each pin centerline is located within 0,25 (0.010) of its true longitudinal position
MDXXABA
PRODUCT
18
INFORMATION
AUGUST 1997 - REVISED AUGUST 2002
Specifications are subject to change without notice.