ERICSSON PBL386652

Preliminary
May 2000
PBL 386 65/2
Subscriber Line
Interface Circuit
Description
Key Features
The PBL 386 65/2 Subscriber Line Interface Circuit (SLIC) is a 90 V bipolar integrated
circuit for use in DLC, Central Office and other telecommunications equipment. The
PBL 386 65/2 has been optimized for low total line interface cost and a high degree
of flexibility in different applications.
The PBL 386 65/2 emulates a transformer equivalent dc-feed, programmable
between 2x25 Ω and 2x900 Ω, with short loop current limiting adjustable to max
65 mA.
A second lower battery voltage may be connected to the device to reduce short
loop power dissipation. The SLIC automatically switches between the two battery
supply voltages without need for external components or external control.
The SLIC incorporates loop current, ground key and ring trip detection functions. The
PBL 386 65/2 is compatible with loop start and ground start signalling.
Two- to four-wire and four- to two-wire voice frequency (vf) signal conversion is
accomplished by the SLIC in conjunction with either a conventional CODEC/filter or
with a programmable CODEC/filter, e.g. SLAC, SiCoFi, Combo II. The programmable
line terminating impedance could be complex or real to fit every market.
Longitudinal line voltages are suppressed by a feedback loop in the SLIC and the
longitudinal balance specifications meet the DLC requirements.
The PBL 386 65/2 package is 28-pin PLCC and 28-pin SSOP.
• Selectable overhead voltage principle
– All adaptive: The overhead voltage
follows 0.6PeakV < signals < 6.2VPeak.
– Semi adaptive: The overhead voltage
follows 3.1VPeak < signals < 6.2VPeak.
• Metering 2.2 Vrms
• High and low battery with automatic
switching
• Battery supply as low as -10 V
• Only +5 V in addition to GND
and battery (VEE optional)
• 39 mW on-hook power dissipation in
active state
• Long loop battery feed tracks VBat for
maximum line voltage
• 44V open loop voltage @ -48V
battery feed
• Constant loop voltage for line
leakage <5 mA
• On-hook transmission
• Full longitudinal current capability
during on-hook
RRLY
DT
Ring Trip
Comparator
DR
TIPX
Ground Key
Detector
RINGX
HP
TS
Two-wire
Interface
Line Feed
Controller
and
Longitudinal
Signal
Suppression
Input
Decoder and
Control
C1
• Ground key detector
C2
• Analog temperature guard
C3
• Tip open state with ring ground detector
VCC
• Silent polarity reversal
DET
• Line voltage measurement
PSG
LP
AOV
Off-hook
Detector
PLD
AGND
VBAT
VTX
BGND
• -40° C to +85° C ambient temperature
range
REF
PLC
VBAT2
• Programmable loop & ring-trip detector
threshold
38 PB
6 L
65
/2
Ring Relay
Driver
VF Signal
Transmission
RSN
PB
6
L 38
65/
2
VEE
(Optional)
Figure 1. Block diagram.
28-pin PLCC and 28-pin SSOP.
1
PBL 386 65/2
Preliminary
Maximum Ratings
Parameter
Symbol
Min
Max
Unit
Temperature, Humidity
Storage temperature range
Operating temperature range
Operating junction temperature range, Note 1
TStg
TAmb
TJ
-55
-40
-40
+150
+110
+140
°C
°C
°C
Power supply, -40°C ≤ TAmb ≤ +85°C
VCC with respect to A/BGND
VEE with respect to A/BGND
VBat with respect to A/BGND, continuous
VBat with respect to A/BGND, 10 ms
VBat2 with respect to A/BGND
VCC
VEE
VBat
VBat
VBat2
-0.4
VBat
-75
-80
VBat
6.5
0.4
0.4
0.4
0.4
V
V
V
V
V
Power dissipation
Continuous power dissipation at TAmb ≤ +85 °C
PD
1.5
W
VCC
V
BGND +13
75 mA
V
Ground
Voltage between AGND and BGND
Relay Driver
Ring relay supply voltage
Ring relay current
VG
-5
Ring trip comparator
Input voltage
Input current
VDT, VDR
IDT, IDR
VBat
-5
VCC
5
V
mA
Digital inputs, outputs (C1, C2, C3, DET)
Input voltage
VID
-0.4
VCC
V
Output voltage (DET not active)
VOD
-0.4
Output current (DET)
IOD
TIPX and RINGX terminals, -40°C < TAmb < +85°C, VBat = -50V
Maximum supplied TIPX or RINGX current
TIPX or RINGX voltage, continuous (referenced to AGND), Note 2
TIPX or RINGX, pulse < 10 ms, tRep > 10 s, Note 2
TIPX or RINGX, pulse < 1 µs, tRep > 10 s, Note 2
TIP or RING, pulse < 250 ns, tRep > 10 s, Note 3
ITIPX, IRINGX
VTA, VRA
VTA, VRA
VTA, VRA
VTA, VRA
Parameter
Ambient temperature
VCC with respect to AGND
VEE with respect to AGND
VBat with respect to BGND
VBat2 with respect to BGND
VCC
V
30
mA
-110
VBat
VBat - 20
VBat - 40
VBat - 70
+110
2
5
10
15
mA
V
V
V
V
Symbol
Min
Max
Unit
TAmb
VCC
VEE
VBat
-40
4.75
VBat
-58
VBat
+85
5.25
-4.75
-10
-10
°C
V
V
V
V
Recommended Operating Condition
Notes
2
1.
The circuit includes thermal protection. Operation above max. junction temperature may degrade device reliability.
2.
A diode in series with the VBat input increases the permitted continuous voltage and pulse < 10 ms to -85 V. A pulse
≤1µs is increased to the greater of |-70V| and |VBat -40V|.
3.
RF1, FR2 ≥20 Ω is also required. Pulse is supplied to TIP and RING outside RF1, FR2.
Preliminary
PBL 386 65/2
Electrical Characteristics
-40 °C ≤ TAmb ≤ +85 °C, VCC = +5V ±5 %, VEE = -5V ± 5%, VBat = -58V to -40V, RLC=18.7kΩ, IL = 27 mA, ZL = 600 Ω, RF1, RF2 =0 Ω,
RRef = 15kΩ, CHP = 68nF, CLP=0.33 µF, RT = 120 kΩ, RSG = 24 kΩ, RRX = 120 kΩ, AOV- and VBat2 pin not connected, unless
otherwise specified. Current definition: current is positive if flowing into a pin.
Ref
fig
Parameter
Conditions
Min
Typ
Max
Unit
Two-wire port
Overload level, VTRO ,ILDC ≥ 10 mA
On-Hook, ILDC ≤ 5 mA
Input impedance, ZTR
Longitudinal impedance, ZLoT, ZLoR
Longitudinal current limit, ILoT, ILoR
Longitudinal to metallic balance, BLM
Longitudinal to metallic balance, BLME
BLME = 20 • Log
3
VTR
3
ELO
VTX
Metallic to longitudinal balance, BMLE
BMLE = 20 • Log
3
ELO
Longitudinal to four-wire balance, BLFE
BLFE = 20 • Log
2
4
Active state
1% THD, Note 1
3.1
1.4
VPeak
VPeak
Note 2
ZT/200
0 < f < 100 Hz
20
active state
28
IEEE standard 455-1985, ZTRX=736Ω, active state
Normal polarity:
0.2 kHz < f < 1.0 kHz, Tamb 0-70°C
63
1.0 kHz < f < 3.4 kHz, Tamb 0-70°C
58
0.2 kHz < f < 1.0 kHz, Tamb -40-85°C 58
1.0 kHz < f < 3.4 kHz, Tamb -40-85°C 54
Reverse polarity:
0.2 kHz < f < 3.4 kHz, Tamb -40-85°C 54
Active state
Normal polarity:
0.2 kHz < f < 1.0 kHz, Tamb 0-70°C
63
1.0 kHz < f < 3.4 kHz, Tamb 0-70°C
58
0.2 kHz ≤ f ≤ 1.0 kHz, Tamb -40-85°C 58
1.0 kHz < f < 3.4 kHz, Tamb -40-85°C 54
Reverse polarity:
0.2 kHz < f < 3.4 kHz, Tamb -40-85°C 54
Active state
Normal polarity:
0.2 kHz < f < 1.0 kHz, Tamb 0-70°C
1.0 kHz < f < 3.4 kHz, Tamb 0-70°C
0.2 kHz ≤ f ≤ 1.0 kHz, Tamb -40-85°C
1.0 kHz < f < 3.4 kHz, Tamb -40-85°C
Reverse polarity:
0.2 kHz < f < 3.4 kHz, Tamb -40-85°C
Active state
0.2 kHz < f < 3.4kHz
Ω/wire
mArms /wire
35
dB
dB
dB
dB
dB
dB
dB
dB
dB
dB
69
64
64
60
dB
dB
dB
dB
54
dB
40
dB
VTR
VLO
Figure 2. Overload level, VTRO, two-wire
port
1
<< RL, RL= 600 Ω
ωC
C
RL
VTRO
TIPX
ILDC
PBL 386 65/2
RINGX
RT = 120 kΩ, RRX = 120 kΩ
Figure 3. Longitudinal to metallic (BLME)
and Longitudinal to four-wire (BLFE)
balance
1
<< 150 Ω, RLR = RLT = RL /2= 300Ω
ωC
RT
E RX
RSN
RRX
TIPX
ELo
C
VTX
RLT
V TR
PBL 386 65/2
RT
V TX
RLR
RINGX
RT = 120 kΩ, RRX = 120 kΩ
VTX
RSN
RRX
3
Preliminary
PBL 386 65/2
Parameter
Ref
fig
Conditions
Four-wire to longitudinal balance, BFLE
4
Active state
Min
ERX
VLo
0.2 kHz < f < 3.4 kHz
|ZTR + ZL|
r = 20 • Log
|ZTR - ZL|
Typ
Max
Unit
BFLE = 20 • Log
Two-wire return loss, r
TIPX idle voltage, VTi
RINGX idle voltage, VRi
RINGX idle voltage, VRi
VTR
Four-wire transmit port (VTX)
Overload level, VTXO, IL ≥ 10 mA
On hook IL ≤ 5 mA
Output offset voltage, ∆VTX
Output impedance, zTX
5
Frequency response
Two-wire to four-wire, g2-4
0.2 kHz < f < 0.5 kHz
0.5 kHz < f < 1.0 kHz
1.0 kHz < f < 3.4 kHz, Note 3
active, IL < 5 mA
active, IL < 5 mA
tip open, IL < 5 mA
active, IL < 5 mA
25
27
23
- 1.5
VBat + 2.7
VBat + 3.0
VBat +4.2
dB
dB
dB
V
V
V
V
Load impedance > 20 kΩ,
1% THD, Note 4
1.55
0.7
-60
5
60
20
VPeak
VPeak
mV
Ω
GND
10
+25
50
mV
Ω
IRSN = 0 mA
0.2 kHz < f < 3.4 kHz
0.3 kHz < f < 3.4 kHz
-25
400
6
TIPX
relative to 0 dBm, 1.0 kHz. ERX = 0 V
0.3 kHz < f < 3.4 kHz
f = 8.0 kHz, 12 kHz, 16 kHz
PBL 386 65/2
RT
E RX
RLR
RINGX
-0.15
-0.5
0
ratio
0.15
+0.1
dB
dB
Figure 4. Metallic to longitudinal and
four-wire to longitudinal balance
VTX
RLT
V TR
VLo
dB
0.2 kHz < f < 3.4 kHz
Four-wire receive port (RSN)
Receive summing node (RSN) dc voltage
Receive summing node (RSN) impedance
Receive summing node (RSN)
current (IRSN) to metallic loop current (IL)
gain,αRSN
C
40
1
<< 150 Ω, RLT = RLR = RL /2 =300Ω
ωC
RT = 120 kΩ, RRX = 120 kΩ
RSN
RRX
C
TIPX
Figure 5. Overload level, VTXO, four-wire
transmit port
VTX
RL
ILDC
EL
PBL 386 65/2
RINGX
RT
1
<< RL, RL = 600 Ω
ωC
RT = 120 kΩ, RRX = 120 kΩ
RSN
RRX
4
VTXO
Preliminary
Parameter
Ref
fig
Four-wire to two-wire, g4-2
6
Four-wire to four-wire, g4-4
6
Four-wire to two-wire, G4-2
6
Gain tracking
Two-wire to four-wire RLDC≤ 2kΩ
Four-wire to two-wire RLDC≤ 2kΩ
Conditions
relative to 0 dBm, 1.0 kHz. EL = 0 V
0.3 kHz < f < 3.4 kHz
f = 8 kHz, 12 kHz,
16 kHz
relative to 0 dBm, 1.0 kHz. EL = 0 V
0.3 kHz < f < 3.4 kHz
6
Insertion loss
Two-wire to four-wire, G2-4
0 dBm, 1.0 kHz, Note 5
V
G2-4 = 20 • Log TX ,ERX = 0
VTR
0 dBm, 1.0 kHz, Notes 5, 6
V
G4-2 = 20 • Log TR ,EL = 0
ERX
6
6
Min
Typ
Max
Unit
-0.15
-1.0
-1.0
-0.2
-0.3
0.15
0
0
dB
dB
dB
0.15
dB
-5.82
dB
-0.2
0.2
dB
-0.1
-0.2
0.1
0.2
dB
dB
-0.1
-0.2
0.1
0.2
dB
dB
12
-78
dBrnC
dBmp
-50
-50
dB
dB
-0.15
-6.22
Ref. -10 dBm, 1.0 kHz, Note 7
-40 dBm to +3 dBm
-55 dBm to -40 dBm
Ref. -10 dBm, 1.0 kHz, Note 7
-40 dBm to +3 dBm
-55 dBm to -40 dBm
Noise
Idle channel noise at two-wire
(TIPX-RINGX)
Harmonic distortion
Two-wire to four-wire
Four-wire to two-wire
PBL 386 65/2
C-message weighting
Psophometrical weighting
Note 8
-6.02
7
-83
6
0 dBm, 1.0 kHz test signal
0.3 kHz < f < 3.4 kHz
Constant loop current, ILconst
15
ILProg = 500
RLC
Tip open state TIPX current, ILeak
7
18 < ILProg < 65 mA
S = closed; R = 7 kΩ
Tip open state RINGX current, ILRTO
7
RLRTO = 0Ω, VBat = -48V
IL
mA
RLRTO = 2.5 kΩ, VBat = -48V
17
mA
-4
VBat+ 5.8
-2.5
-
V
V
-6
-3.1
-
V
-100
0
100
µA
Battery feed characteristics
Tip open state RINGX voltage, VRTO
Tip voltage (ground start)
7
7
Tip voltage (ground start)
7
0.92 ILProg
ILRTO < 23 mA
Active state, Tip lead open (S open),
Ring lead to ground through 150 Ω
Active state, tip lead to -48 V
through 7 kΩ (S closed), Ring
lead to ground through 150 Ω
RL = 0Ω
Open circuit state loop current, ILOC
Figure 6.
Frequency response, insertion loss,
gain tracking.
C
TIPX
ILProg
1.08 ILProg mA
-100
µA
VTX
RL
1
<< RL, RL = 600 Ω
ωC
RT = 120 kΩ, RRX = 120 kΩ
VTR
EL
ILDC
PBL 386 65/2
RINGX
RT
E RX
VTX
RSN
RRX
5
Preliminary
PBL 386 65/2
Parameter
Ref
fig
Loop current detector
Programmable threshold, IDET
Progammable threshold in
Tip Open state, IDET
Conditions
Min
Typ
Max
Unit
ILTh = 500
RLD
500
ILTh =
RLD
0.9•ILTh
ILTh
1.1•ILTh
mA
0.9•ILTh
ILTh
1.1•ILTh
mA
11
15
19
mA
Ground key detector
Ground key detector threshold
(ILTIPX and ILRINGX current differance to trigger ground key det.)
Line voltage measurement
106
|V|TR+1
Frequency
f=
Ring trip comparator
Offset voltage, ∆VDTDR
Input bias current, IB
Input common mode range, VDT, VDR
Source resistance, RS = 0 Ω
IB = (IDT + IDR)/2
Ring relay driver
Saturation voltage, VOL
Off state leakage current, ILk
Digital inputs (C1, C2, C3)
Input low voltage, VIL
Input high voltage, VIH
Input low current, IIL
Input high current, IIH
Detector output (DET)
Output low current, IOL
Internal pull-up resistor
Power dissipation (VBat = -48V; VBat2 = -32V)
P1
P2 @ VEE=-5V
P3 @ VEE=-48V
P4 @ VEE=-5V
P5 @ VEE=-5V
Power supply currents (VBat = -48V)
VCC current, ICC
VEE current, IEE
VBat current, IBat
VCC current, ICC
VEE current, IEE
VBat current, IBat
Power supply rejection ratios
VCC to 2- or 4-wire port
VEE to 2- or 4-wire port
VBat to 2- or 4-wire port
VBat2 to 2- or 4-wire port
Temperature guard
Junction threshold temperature, TJG
Thermal resistance
28-pin PLCC, θJP28PLCC
28-pin SSOP, θJP28SSOP
6
f
-20
-50
VBat+1
0
-20
IOL = 50 mA
VOH = 12 V
0
2.5
VIL = 0.5
VIH = 2.5 V
VOL < 0.6V
20
200
-1
mV
nA
V
0.5
100
V
µA
0.5
VCC
-200
200
V
V
µA
µA
1
10
mA
kΩ
Open circuit state
Active state ILo = 0 mA, IL = 0 mA
Active state ILo = 0 mA, IL = 0 mA
Active state RL = 300Ω (off-hook)
Active state RL = 800Ω (off-hook)
14
39
44
710
340
mW
mW
mW
mW
mW
Open circuit state
Open circuit state
Open circuit state
Active state ILo= 0 mA, IL = 0 mA
Active state ILo= 0 mA, IL = 0 mA
Active state ILo= 0 mA, IL = 0 mA
0.8
-0.15
-0.2
2.0
-0.15
-0.7
mA
mA
mA
mA
mA
mA
35
55
40
60
dB
dB
dB
dB
Active state, f = 1 kHz, Vn = 100mV
Active state, f = 1 kHz, Vn = 100mV
Active state, f = 1 kHz, Vn = 100mV
Active state, f = 1 kHz, Vn = 100mV
0.5
Hz
28.5
28.5
28.5
28.5
°C
140
39
55
°C/W
°C/W
Preliminary
Notes
1.
2.
3.
4.
The overload level is automatically expanded when the
signal level > 3.1 VPeak and is specified at the two-wire port
with the signal source at the four-wire receive port.
The two-wire impedance is programmable by selection of
external component values according to:
ZTR = ZT/|G2-4S α RSN| where:
ZTR = impedance between the TIPX and RINGX
terminals
ZT = programming network between the VTX and RSN
terminals
G2-4S = transmit gain, nominally = 0.5
α RSN = receive current gain, nominally = 400 (current
defined as positive flowing into the receivesumming node, RSN, and when flowing from tip to ring).
Higher return loss values can be achieved by adding a
reactive component to RT, the two-wire terminating
impedance programming resistance, e.g. by dividing RT
into two equal halves and connecting a capacitor from the
common point to ground.
R
S
-48V
PBL 386 65/2
The overload level is automatically expanded, as needed
up to 3.1 VPeak when the signal level >1.55 VPeak and is
specified at the four-wire transmit port, VTX, with the signal
source at the two-wire port. Note that the gain from the
two-wire port to the four-wire transmit port is G2-4S = 0.5.
Secondary protection resistors RF impact the insertion loss
as explained in the text, section Transmission. The
specified insertion loss is for RF = 0.
The specified insertion loss tolerance does not include
errors caused by external components.
The level is specified at the four-wire receive port and
referenced to a 600 Ω programmed two-wire impedance
level.
The two-wire idle noise is specified with the four-wire
receive port grounded (ERX = 0; see figure 6).
The four-wire idle noise at VTX is the two-wire value -6 dB
and is specified with the two-wire port terminated in 600 Ω
(RL). The noise specification is referenced to a 600 Ω
programmed two-wire impedance level at VTX. The four-wire
receive port is grounded (ERX = 0).
5.
6.
7.
8.
TIPX
PBL 386 65/2
RLRTO
RINGX
Figure 7. Tipx voltage.
7
Preliminary
PBL 386 65/2
Pin Description
Refer to figure 8.
PLCC SSOP
Symbol
Description
1
7
VBAT
Battery supply voltage. Negative with respect to BGND.
2
8
VBAT2
An optional second battery voltage, connected in series with a diode, or an external powerhandling
resistor connects to this pin.
3
9
AOV
Adaptive Overhead Voltage. If the pin is left open, then the overhead voltage is set internally to 3.1VPeak
in off-hook and 1.4 VPeak in on-hook. The overhead voltage will automatically adapt to signals > 3.1VPeak.
If the pin is connected to AGND, then no overhead voltage is set internally. The overhead voltage adapts
automatically to 0.6 VPeak < signals < 6.2 VPeak.
4
10
PSG
Programmable Saturation Guard. The resistive part of the DC feed characteristic is programmed by a
resistor connected from this pin to VBAT.
5
11
LP
Low Pass filter. Saturation guard filter capacitor connected here to filter out noise and improve PSRR.
Other end of CLP connects to VBAT.
6
12
DT
Input to the ring trip comparator. With DR more positive than DT the detector output, DET, is at logic level
low, indicating off-hook condition. The ring trip network connects to this input.
7
13
DR
Input to the ring trip comparator. With DR more positive than DT the detector output, DET, is at logic
level low, indicating off-hook condition. The ring trip network connects to this input.
8
16
VEE
-5V to VBAT power supply.
9
17
REF
A 15 kΩ resistor should be connected between this pin and AGND.
10
18
SPR
Silent Polarity Reversal. The polarity reversal time can be adjusted with a capacitor connected to AGND.
If pin is left open: Shortest polarity reversal time.
11
19
PLC
Prog. Line Current, the constant current part of the DC feed characteristic is programmed by a resistor
connected from this pin to AGND.
12
20
PLD
Programmable Loop Detector threshold. The loop detection threshold is programmed by a resistor
connected from this pin to AGND.
13
21
VCC
+5 V power supply.
14
15
16
22
23
24
C3
C2
C1
C1, C2 and C3 are digital inputs Controlling the SLIC operating states. Refer to section
Operating states for details.
17
14
NC
No Connect. Must be left open.
18
25
DET
Detector output. Active low when indicating loop or ring trip detection, active high when indicating ground
key detection
19
26
RSN
Receive Summing Node. 400 times the current flowing into this pin equals the metallic (transversal)
current flowing from RINGX to TIPX. Programming networks for two-wire impedance and receive gain
connect to the receive summing node.
20
27
AGND
Analog Ground, should be tied together with BGND.
21
28
VTX
Transmit vf output. The ac voltage difference between TIPX and RINGX, the ac metallic voltage, is
reproduced as an unbalanced GND referenced signal at VTX with a gain of -0.5. The two-wire
impedance programming network connects between VTX and RSN.
}
22
1
RRLY
Ring Relay driver output.
23
2
TS
Tip Sense should be connected to TIPX.
24
15
NC
No Connect. Must be left open.
25
3
HP
High Pass connection for ac/dc separation capacitor CHP. Other end of CHP connects to RINGX.
26
4
RINGX
The TIPX and RINGX pins connect to the tip and ring leads of the two-wire interface via overvoltage
protection components and ring relay (and optional test relay).
27
5
BGND
Battery Ground, should be tied together with AGND.
28
6
TIPX
The TIPX and RINGX pins connect to the tip and ring leads of the two-wire interface via overvoltage
protection components and ring relay (and optional test relay).
8
Preliminary
26
RSN
RINGX 4
25
DET
BGND 5
24
TIPX 6
26 RINGX
HP 3
27 BGND
AGND
28 TIPX
27
1 VBAT
TS 2
2 VBAT2
VTX
3 AOV
28
4 PSG
RRLY 1
PBL 386 65/2
LP 5
25
HP
C1
DT 6
24
NC*
23
C2
DR 7
23
TS
22
C3
VEE 8
22
RRLY
VBAT2 8
21
VCC
REF 9
21
VTX
AOV 9
20
PLD
SPR 10
20
AGND
PLC 11
19
RSN
PSG 10
19
PLC
LP 11
18
SPR
DT
12
17
REF
DR 13
16
VEE
15
NC*
*NC
14
DET 18
NC* 17
C1 16
C2 15
C3 14
28 pin PLCC
VCC 13
28-pin SSOP
PLD 12
VBAT 7
* Pins must be left open.
Figure 8. Pin configuration 28 pin SSOP and 28 pin package, top view.
SLIC Operating States
State
C3
C2
C1
SLIC operating state
Active detector
0
1
2
3
4
5
6
7
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
Open circuit
Ringing state
Active state
Active state
Tip open state
Active state
Active reverse
Active reverse
Detector is set high
Ring trip detector (active low)
Loop detector (active low)
Line voltage measurement
Loop detector (active low)
Ground key detector (active high)
Loop detector (active low)
Ground key detector (active high)
Table 1. SLIC operating states.
9
Preliminary
PBL 386 65/2
TIPX
TIP
+
IL
RF
ZL
ZTR
VTR
RHP
EL
-
+
RING
+
G2-4S
-
VTX
+
VTX
RF
IL
RINGX
-
ZT
Z RX
+
RSN
VRX
I L /α RSN
-
PBL 386 65/2
Figure 9. Simplified ac transmission circuit.
Functional Description and Applications
Information Transmission
General
A simplified ac model of the transmission
circuits is shown in figure 9. Circuit analysis
yields:
VTX
VTR =
(1)
- I • 2RF
G2-4S L
VTX VRX
I
(2)
+
= L
ZRX αRSN
ZT
VTR = IL • ZL - EL
(3)
where:
VTX is a ground referenced version
of the ac metallic voltage
between the TIPX and RINGX
terminals.
VTR is the ac metallic voltage
between tip and ring.
EL is the line open circuit ac metallic
voltage.
IL
is the ac metallic current.
RF is a fuse resistor.
G2-4S is the SLIC two-wire to fourwire gain (transmit direction) with
a nominal value of -0.5.
(Phase shift 180°)
ZL is the line impedance.
ZT determines the SLIC TIPX to
RINGX impedance for signal in
the 0 - 20kHz frequency range.
ZRX controls four- to two-wire gain.
10
VRX is the analogue ground referenced
receive signal.
αRSN is the receive summing node
current to metallic loop current
gain. The nominal value of
αRSN =400
Two-Wire Impedance
To calculate ZTR, the impedance presented
to the two-wire line by the SLIC including
the fuse resistor RF, let VRX = 0.
From (1) and (2):
ZT
ZTR =
- 2RF
αRSN • G2-4S
Thus with ZTR, G2-4S, αRSN, and RF known:
ZT = αRSN • G2-4S • (2RF - |ZTR|)
Two-Wire to Four-Wire Gain
From (1) and (2) with VRX = 0:
G2-4 =
VTX
=
VTR
ZT/αRSN
ZT
- 2RF
αRSN • G2-4S
Four-Wire to Two-Wire Gain
From (1), (2) and (3) with EL = 0:
G4-2 =
VTR ZT
ZL
•
=
VRX ZRX ZT
- G2-4S • ( ZL + 2RF)
αRSN
In applications where
2RF - ZT/(αRSN • G2-4S) is chosen to be
equal to ZL, the expression for G4-2 simplifies to:
G4-2 = -
ZT
1
•
ZRX 2 • G2-4S
Four-Wire to Four-Wire Gain
From (1), (2) and (3) with EL = 0:
G4-4 =
G2-4S • ( ZL + 2RF)
VTX ZT
•
=
VRX ZRX ZT
- G2-4S • ( ZL + 2RF)
αRSN
Preliminary
Hybrid Function
The hybrid function can easily be implemented utilizing the uncommitted amplifier
in conventional CODEC/filter combinations.
Please, refer to figure 10. Via impedance
ZB a current proportional to VRX is injected
into the summing node of the combination
CODEC/filter amplifier. As can be seen
from the expression for the four-wire to
four-wire gain a voltage proportional to VRX
is returned to VTX. This voltage is converted
by RTX to a current flowing into the same
summing node. These currents can be
made to cancel by letting:
VTX VRX
+
= 0 (EL = 0)
RTX ZB
The four-wire to four-wire gain, G4-4, includes the required phase shift and thus
the balance network ZB can be calculated
from:
V
ZB = - RTX • RX =
VTX
Z
- RTX • RX •
ZT
ZT
αRSN - G2-4S • ( ZL + 2RF)
G2-4S • ( ZL + 2RF)
PBL 386 65/2
The PBL 386 65/2 SLIC may also be
used together with programmable CODEC/
filters. The programmable CODEC/filter
allows for system controller adjustment of
hybrid balance to accommodate different
line impedances without change of hardware. In addition, the transmit and receive
gain may be adjusted. Please, refer to the
programmable CODEC/filter data sheets
for design information.
Longitudinal Impedance
A feed back loop counteracts longitudinal
voltages at the two-wire port by injecting
longitudinal currents in opposing phase.
Thus longitudinal disturbances will appear as longitudinal currents and the TIPX
and RINGX terminals will experience very
small longitudinal voltage excursions, leaving metallic voltages well within the SLIC
common mode range.
The SLIC longitudinal impedance per wire,
ZLoT and ZLoR, appears as typically 20 Ω to
longitudinal disturbances. It should be noted that longitudinal currents may exceed
the dc loop current without disturbing the vf
transmission.
Capacitors CTC and CRC
When choosing RTX, make sure the
output load of the VTX terminal is
> 20 kΩ.
If calculation of the ZB formula above
yields a balance network containing an
inductor, an alternate method is recommended.
If RFI filtering is needed, the capacitors
designated CTC and CRC in figure 13, connected between TIPX and ground as well
as between RINGX and ground, may be
mounted.
CTC and CRC work as RFI filters in conjunction with suitable series impedances
(i.e. resistances, inductances). Resistors
RF1 and RF2 may be sufficient, but series
inductances can be added to form a second order filter. Current-compensated inductors are suitable since they suppress
common-mode signals with minimum influence on return loss. Recommended values
for CTC and CRC are below 1 nF. Lower
values impose smaller degradation on return loss and longitudinal balance, but also
attenuate radio frequencies to a smaller
extent. The influence on the impedance
loop must also be taken into consideration
when programming the CODEC. CTC and
CRC contribute to a metallic impedance of
1/(π•f•CTC) = 1/(π•f•CRC), a TIPX to ground
impedance of 1/(2•π•f•CTC) and a RINGX to
ground impedance of 1/(2•π•f•CRC).
AC - DC Separation Capacitor, CHP
The high pass filter capacitor connected
between terminals HP and RINGX p r o vides the separation of the ac and dc
signals. CHP positions the low end frequency response break point of the ac loop in the
SLIC. Refer to table 1 for recommended
value of CHP.
Example: A CHP value of 68 nF will
position the low end frequency response
3dB break point of the ac loop at 13 Hz (f3dB)
according to f3dB = 1/(2•π•RHP•CHP) where
RHP = 180 kΩ.
RFB
RTX
VTX
VT
PBL
386 65/2
ZT
ZB
Z RX
Combination
CODEC/Filter
V RX
RSN
Figure 10. Hybrid function.
11
PBL 386 65/2
Preliminary
High-Pass Transmit Filter
When CODEC/filter with a singel 5 V power
supply is used, it is necessary to separate
the different signal reference voltages between the SLIC and the CODEC/filter. In
the transmit direction this can be done by
connecting a capacitor between the VTX
output of the SLIC and the CODEC/filter
input. This capacitor will also form, together with RTX and/or the input impedance of
the CODEC/filter, a high-pass RC filter. It is
recommended to position the 3 dB break
point of this filter between 30 and 80 Hz to
get a fast enough response for the dc steps
that may occur with DTMF signaling.
Capacitor CLP
The capacitor CLP, which connects between
the terminals LP and VBAT, positions the
high end frequency break point of the low
pass filter in the dc loop in the SLIC. CLP
together with CHP and ZT (see section TwoWire Impedance) forms the total two wire
output impedance of the SLIC. The choice
of these programming components influence the power supply rejection ratio
(PSRR) from VBAT to the two wire side in
the low frequency range.
RFeed
RSG
CLP
CHP
[Ω]
[kΩ] [nF] [nF]
4.02 330 68
2•25
2•50
23.7 330 68
2•200
147 100 33
2•400
301 47
33
2•800
619 22
33
Table 1. RSG, CLP and CHP values for
different feeding characteristics.
Figure 11. The AOV funktion when the AOV-pin is left open. (Observe, burst
undersampled).
tude less than 3.1VPeak11. For signal amplitudes between 3.1VPeak and 6.2VPeak, the
AOV-function will expand the overhead
voltage making it possible for the signal, Vt,
to propagate through the SLIC without distortion (see figure 11). The expansion of
the overhead voltage occurs instantaneously. When the signal amplitude decreases, the overhead voltage returns to its initial
value with a time constant of approximately
one second.
If the AOV-pin is connected to AGND, the
overhead voltage will automatically be adjusted for signal levels between 0.6 VPeak
and 6.2 VPeak.
AOV In the Constant Current Region
Table 1 suggest values of CLP and CHP for
different feeding characteristics.
Adaptive Overhead Voltage, AOV
The Adaptive Overhead Voltage feature
minimises the power dissipation and at the
same time provides a flexible solution for
differing system requirements and possible future changes concerning voice, metering and other signal levels. This is done
by using an overhead voltage which automatically adapts to the signal level (voice +
metering). With the AOV-pin left open, the
PBL 386 65/2 will behave as a SLIC with
fixed overhead voltage for signals in the 0
- 20kHz frequency range and with an ampli-
12
When the overhead voltage is automatically increased, the apparent battery (VApp,
reference F in figure 15), will be reduced by
the signal amplitude minus 3.1 VPeak(11),
(Vt - 3.1(11)).
In the constant current region this change
will not affect the line current as long as
VTR < VApp - (ILConst • RFeed) - (Vt-3.1(11)),
(references A-C in figure 15).
AOV In the Resistive Loop Feed Region
The saturation guard will be activated when
the SLIC is working in the resistive loop
feed region, i.e.
VTR > VApp - (ILConst • RFeed) - (Vt - 3.1(11))
(references D in figure 15).
If the signal amplitude is greater than
3.1VPeak11 the line current, IL, will be reduced corresponding to the formula
∆IL = | (Vt - 3.1(11))/(RL + RFeed) |.
This reduction of line current will introduce a transversal signal into the two-wire
which under some circumstances may be
audible (e g when sending metering signals > 3.1 VPeak without any speech signal
burying the transversal signal generated
from the linecurrent reduction).
The sum of all signals should not exceed
6.2 VPeak.
Line Feed
If VTR < VApp - (ILConst • RFeed), the PBL 386 65/
2 SLIC will emulate constant current feed
(references A-C in figure 15).
For VTR > VApp - (ILConst • RFeed) the PBL 386
65/2 SLIC will emulate resistive loop feed
programmable between 2•25 Ω12 and 2•900
Ω (references D in figure 15). The current
limitation region is adjustable between 0
mA and 65 mA13.
When the line current is approaching
open loop conditions, the overhead voltage is reduced. To ensure maximum open
loop voltage, even with telephone line leakage, this occurs at a line current of approximately 5 mA (references E in figure 15).
After the overhead voltage reduction, the
line voltage is kept nearly constant with a
steep slope corresponding to 2 • 25 Ω(reference G in figure 15).
The open loop voltage, VTRMax, measured
between the TIPX and RINGX terminals is
tracking the battery voltage VBat (references H in figure 15). VTRMax is programmable
by connecting the AOV-pin to AGND or by
leaving the AOV-pin open.
Preliminary
PBL 386 65/2
VTRMax is defined as the battery voltage on
the VBat terminal minus the Battery Over
Head voltage, VBOH, according to the equation
VTRMax(at IL = 0 mA) = |VBat| - VBOH
Refer to table 2 for typical VBOH values.
VBOH(typ) [V]
AOV-PIN NC
4.2
AOV-PIN to AGND
3.2
Table 2. The battery overhead voltages
at open loop conditions.
Resistive Loop Feed Region
The resistive loop feed (reference D in
figure 15) is programmed by connecting a
resistor RSG , between terminals PSG and
VBAT according to the equation
RFeed =
RSG
+ 40 + 2RF
400
Figure 12. Silent Polarity Reversal
Constant Current Region
The current limit (reference C in figure 15)
is adjusted by connecting a resistor, RLC,
between terminal PLC and ground according to the equation:
RLC =
500
ILProg
14
Battery Switch (VBAT2)
To reduce short loop power dissipation, a
second lower battery voltage may be connected to the device through an external
diode at terminal VBAT2. The SLIC automatically switches between the two battery
supply voltages without need for external
control. The silent battery switching occurs
when the line voltage passes the value
VTR = |VBat2| - 40•IL - 6 15
Connect the terminal VBAT2 to the second power supply via the diode DB2 in figure
14.
An optional diode DBB connected between
terminal VBAT and the VB2 power supply,
see figure 13, will make sure that the SLIC
continues to work on the second battery
even if the first battery voltage disappears.
If the VB2 voltage is not available, an
optional external power management resistor, RPM, may be connected between the
VBAT2-pin and the VBAT-pin to move power dissipation outside the chip.
Calculation of the external power management resistor to locate the maximum
power dissipation outside the SLIC is according to:
RPM =
|VBat| - 3
ILProg
Metering Applications, TTX
It is very easy to use PBL 386 65/2 in
metering applications; simply connect a
suitable resistor (RTTX) in series with a
capacitor (CTTX) between pin RSN and the
metering source. Capacitor CTTX decouples all DC-voltages that may be superimposed on the metering signal. Choose 1/
(2πRTTXCTTX) ≥ 5kHz to suppress low frequency disturbances from the metering
puls generator. The metering signal gain
can be calculated from the equation:
G4-2TTX =
ZT
•
RTTX
VTR
=
VTTX
ZLTTX
ZT
αRSN
- G2-4S • (ZLTTX + 2RF)
where:
VTTX is the voltage of the signal at the
metering generator,
ZLTTX is the line impedance seen by the
12 or 16 kHz metering signal,
G2-4S is the transmit gain through the SLIC,
i e -0.5. (Phase shift 180°)
In metering applications with resistive
line feeding characteristic and very strict
requirements (as mentioned earlier in chapter “AOV in resistive loop feed region“), the
metering signal level should not exceed 2.2
VRMS 16, since a reduction of the line current
will generate a transversal, and sometimes
audible, signal (which is not the case in the
constant current region).
Silent Polarity Reversal
The reversal time is set by a capacitor, Csprv,
between the pin SPR and AGND. The
reversal has a setup time and reversal time
see figure 12.
The setup time is different in Active- to
Reversal-state and Reversal- to Active state
but the silent polarity reversal time is the
same Active- to Reversal-state and Reversal- to Active state. To calculate the silent
polarity reversal time use following formula:
tr =CSPR . 9500
13
Preliminary
PBL 386 65/2
R FB
PBL 386 65/2
R TX
KR
RRLY
+12 V /+5V
TS
C GG
OVP
C RC
VB
C TC
R F2
TIP
C B2
D BB
R SG
VB
CB
R1
RSN
HP
DET
RT
RINGX
NC
out
+
RB
R RX
BGND
C1
TIPX
C2
out
CODEC/
Filter
C3
VBAT2
VCC
AOV
PLD
PSG
PLC
LP
SPR
DR
REF
DT
VEE
VCC
R RT
R2
C1
R3
R4
R LD
R LC
C LP
E RG
R RF
NC
VBAT
D B2
VB2
DB
AGND
C HP
R F1
RING
-
VTX
SYSTEM CONTROL
INTERFACE
R REF
VEE
C2
VCC
+5 V
C VCC
C VEE
VBAT<VEE<-5 V
RESISTORS: (Values according to IEC-63 E96
series)
RSG
RLD
RLC
RREF
RT
RTX
RB
RRX
RFB
R1
R2
R3
R4
RRT
RRF
RF1, RF2
= 23.7 kΩ 1% 1/10 W
= 49.9 kΩ 1% 1/10 W
= 18.7 kΩ
1% 1/10 W
= 15 kΩ
1% 1/10 W
= 105 kΩ
1% 1/10 W
= 32.4kΩ
1% 1/10 W
= 57.6kΩ
1% 1/10 W
= 105kΩ
1% 1/10 W
Depending on CODEC / filter
= 604 kΩ
1% 1/10 W
= 604 kΩ
1% 1/10 W
= 249 kΩ
1% 1/10 W
= 280 kΩ
1% 1/10 W
= 332 Ω
5% 2 W
= 332 Ω
5% 2 W
= Line resistor, 40 Ω 1%
CAPACITORS:(Values according to IEC-63 E6
series)
DIODES:
CB
CB2
CVCC
CVEE
CTC
CRC
CHP
CLP
CGG
C1
C2
DB
DB2
DBB
= 100 nF
= 150 nF
= 100 nF
= 100 nF
= 1 nF
= 1 nF
= 68 nF
= 330 nF
= 220 nF
= 330 nF
= 330 nF
100 V 20%
100 V 20%
10 V 20%
10 V* 20%
100 V 20%
100 V 20%
100 V 20%
100 V 20%
100 V 20%
63 V 10%
63 V 10%
VEE
= 1N4448
= 1N4448
= 1N4448 (optional)
OVP:
Secondary protection (eg Power Innovations TISP
PBL2). The ground terminals of the secondary
protection should be connected to the common
ground on the Printed Board Assembly with a track
as short and wide as possible, preferably a
groundplane.
*100V if VEE pin connected to VBAT, VBAT2
Figure 13. Single-channel subscriber line interface with PBL 386 65/2 and combination CODEC/filter
Active- to Reversal-state and Reversalto Active state and the setup time use
following formulas.
Active → Reversal:
tAct → Rev = CSPR . 17500
Reversal → Active:
tRev → Act = CSPR . 15500
The time is measured between 10%
and 90% of the line voltage. The reversal
time is independent of line load and line
current.
14
Analog Temperature Guard
Loop Monitoring Functions
The widely varying environmental conditions in which SLICs operate may lead to
the chip temperature limitations being exceeded. The PBL 386 65/2 SLIC reduces
the dc line current and the longitudinal
current limit when the chip temperature
reaches approximately 145°C and increases it again automatically when the temperature drops.
The detector output, DET, is forced to a
logic low level when the temperature guard
is active.
The loop current, ground key and ring trip
detectors report their status through a common output, DET. The status of the detector pin, DET, is selected via the three bit
control interface C1, C2 and C3. Please
refer to section Control Inputs for a description of the control interface.
Loop Current Detector
The loop current detector indicates that the
telephone is off hook and that DC current is
flowing in the loop by putting the output pin
Preliminary
PBL 386 65/2
ined by a software routine to determine the
duty cycle. Off-hook condition is indicated
when the DET output is at logic level low for
more than half the time.
Line Voltage Detector
The line voltage is presented on the detector output as a pulse train (see figure 15)
with a frequency inversely proportional to
the voltage according to the equation:
106
[Hz]
freq =
|VTR| + 1
The line voltage measurement will be
started when entering this state from any
other state.
Detector Output (DET)
Figure 14. Line voltage Measurement
DET, to a logic low level when selected.
The loop current detector threshold value,
ILTh, where the loop current detector changes state, is programmable with the RLD
resistor. RLD connects between pin PLD
and ground and is calculated according to:
RLD =
500
ILTh
The current detector is internally filtered
and is not influenced by the ac signal at the
two wire side.
Ground Key Detector
The ground key detector indicates when
the ground key is pressed (active) by putting
the output pin DET to a logic high level
when selected. The ground key detector
circuit senses the difference between TIPX
and RINGX currents. The detector is triggered when the difference exceeds the
current threshold.
Ring Trip Detector
Ring trip detection is accomplished by connecting an external network to a comparator in the SLIC with inputs DT and DR. The
ringing source can be balanced or unbalanced e g superimposed on the battery
voltage or ground. The unbalanced ringing
source may be applied to either the ring
lead or the tip lead with return via the other
wire. A ring relay driven by the SLIC ring
relay driver connects the ringing source to
tip and ring.
The ring trip function is based on a polarity change at the comparator input when
the line goes off-hook. In the on-hook state
no dc current flows through the loop and
the voltage at comparator input DT is more
positive than the voltage at input DR. When
the line goes off-hook, while the ring relay
is energized, dc current flows and the comparator input voltage reverses polarity.
Figure 13 gives an example of a ring trip
detection network. This network is applicable, when the ring voltage superimposed
on the battery voltage is injected on the ring
lead of the two-wire port. The dc voltage
across sense resistor RRT is monitored by
the ring trip comparator input DT and DR
via the filter network R1, R2, R3, R4, C1 and
C2. DT is more positive than DR, with the
line on-hook (no dc current). The DET
output will report logic level high, i.e. the
detector is not tripped. When the line goes
off-hook, while ringing, a dc current will flow
through the loop including sense resistor
RRT and will cause the input DT to become
more negative than input DR. This changes the output on the DET pin to logic level
low, i.e. tripped detector condition. The
system controller (or line card processor)
responds by de-energizing the ring relay
via the SLIC, i.e. ring trip.
Complete filtering of the 20 Hz ac component at terminals DT and DR is not necessary. A toggling DET output can be exam-
The PBL 386 65/2 SLIC incorporates a
detector output driver designed as open
collector (npn) with a current sinking capability of min 3 mA, and a 5 kΩ pull-up
resistor. The emitter of the drive transistor
is connected to AGND. A LED can be
connected in series with a resistor (≈1 kΩ)
at the DET output to visualize, for example
loop status.
Relay driver
The PBL 386 65/2 SLIC incorporates a ring
relay driver designed as open collector
(npn) with a current sinking capability of 50
mA.The emitter of the drive transistor is
connected to BGND. The relay driver has
an internal zener diode clamp to protect the
SLIC from inductive kick-back voltages. No
external clamp is needed.
Control Inputs
The PBL 386 65/2 SLIC has three digital
control inputs, C1, C2 and C3.
A decoder in the SLIC interprets the control input condition and sets up the commanded operating state.
C1 to C3 are internal pull-up inputs.
Open Circuit State
In the Open Circuit State the TIPX and
RINGX line drive amplifiers as well as other
circuit blocks are powered down. This causes the SLIC to present a high impedance to
the line. Power dissipation is at a minimum
and no detectors are active.
15
Preliminary
PBL 386 65/2
DC characteristics
B
A
C
C
B
D
I L [mA]
D
E
J
G
F
H
F
V T R [V]
A:
IL (@ VTR = 0) = ILConst
B, C: IL = ILConst
ILConst (typ) = ILProg =
500
RLC (14)
VTR = VBatVirt - RFeed • (ILProg - 5•10-3)
E:
F:
RSG
+ 40
400
IL ≈ 5 mA
Apparent battery VApp (@IL = 0) = VBatVirt + 5•10-3 • RFeed
G:
H:
RFeedG = 2 • 25 Ω
VTRMax = |VBat| - VBOH
J:
Virtual battery VBatVirt (@ IL = 5 mA) = |VBat| - 6.8(17)
D:
RFeed =
Figure 15. Battery feed characteristics (without the protection resistors on the line).
Ringing State
Active State
Active Line Voltage State
In the ringing state the SLIC will behave as
in the active state with the exception
that the ring relay driver and the ring trip
detector are activated. The ring trip detector will indicate off hook with a logic low
level at the detector output.
TIPX is the terminal closest to ground and
sources loop current while RINGX is the
more negative terminal and sinks loop current. The loop current or the ground key
detector is activated. The loop current detector indicates off hook with a logic low
level and the ground key detector indicates
active ground key with a logic high level
present at the detector output.
In PBL 386 65/2 a line voltage measurement feature is available in the active state.
A frequency inversely proportional to the
line voltage is presented on the detector
output (see chapter “Line Voltage Detector“). The data can be used in a variety of
ways, for example to set transmission parameters in a programmable CODEC, inline testing where short circuits on the line
can be detected and to control the metering
signal amplitude. In the active line voltage
state the SLIC will be as in the active state
except for the detector.
16
Preliminary
Active Polarity Reversal State
TIPX and RINGX polarity is reversed compared to the Active State: RINGX is the
terminal closest to ground and sources
loop current while TIPX is the more negative terminal and sinks current. The loop
current or the ground key detector is activated. The loop current detector will indicate off hook with a logic low level and the
ground key detector will indicate active
ground key with a logic high level present at
the detector output.
Tip Open State
The Tip Open State is used for ground start
signaling.
In this state the SLIC presents a high
impedance on the TIPX pin and the programmed dc characteristic on the RINGX
pin, without the longitudinal current compensation.
The loop current detector is active (refer
to the datasheet for information on the
detector threshold level).
Overvoltage Protection
PBL 386 65/2 must be protected against
overvoltages on the telephone line. The
overvoltages could be caused for instance
by lightning, ac power contact and induction. Refer to Maximum Ratings, TIPX and
RINGX terminals, for maximum continuous and transient voltages.
Secondary Protection
The circuit shown in figure 13 utilizes series
resistors together with a programmable
overvoltage protector (e g Power Innovations TISP PBL2), serving as a secondary
protection.
The TISP PBL2 is a dual forward-conducting buffered p-gate overvoltage protector. The protector gate references the
protection (clamping) voltage to negative
supply voltage (i.e. the battery voltage, VB).
As the protection voltage will track the
negative supply voltage the overvoltage
stress on the SLIC is minimized.
Positive overvoltages are clamped to
ground by a diode. Negative overvoltages
are initially clamped close to the SLIC negative supply rail voltage and the protector
will crowbar into a low voltage on-state
condition, by firing an internal thyristor.
A gate decoupling capacitor, CGG, is needed to carry enough charge to supply a high
enough current to quickly turn on the thyristor in the protector. CGG should be placed
close to the overvoltage protection device.
Without the capacitor even the low inductance in the track to the VB supply will limit
the current and delay the activation of the
thyristor clamp.
The fuse resistors RF serve the dual purposes of being non- destructive energy
dissipators, when transients are clamped
and of being fuses, when the line is exposed to a power cross. If a PTC is chosen
for RF , note that it is important to always
use the PTC´s in series with resistors not
sensitive to temperature, as the PTC will
act as a capacitance for fast transients and
therefore will not protect the TISP.
PBL 386 65/2
Notes
Note 11.
3.1 VPeak if AOV-pin is left open and 0.6 VPeak
if AOV-pin is connected to AGND.
Note 12.
RFeed lower than 2x50Ω will reduce noise
and PSRR performance in resistive loop
region (reference D in figure 15). Better
PSRR performance can be achieved by
increasing CLP and CHP.
Note 13.
If the momentary value of the current in
TIPX-pin or RINGX-pin exceeds 85mA
harmonic distortion specification can be
derated.
Power-up Sequence
No special power-up sequence is necessary except that ground has to be present
before all other power supply voltages.
The digital inputs C1 to C3 are internal
pull-up terminals.
Printed Circuit Board Layout
Care in Printed Circuit Board (PCB) layout
is essential for proper function;
The components connecting to the RSN
input should be placed in close proximity to
that pin, such that no interference is injected into the RSN pin. Ground plane surrounding the RSN pin is advisable.
Analog ground (AGND) should be connected to battery ground (BGND) on the
PCB in one point.
RLC and RREF should be connected to
AGND with short leads. Pin LP, pin PSG
and pin AOV are sensitive to leakage currents. Pin AOV should be surrounded by a
guardring connected to AGND.
RSG and CLP connections to VBAT should
be short and very close to each other.
CB and CB2 must be connected with short
wide leads.
Note 14.
The accurate equation for RLC is:
RLC =
500 10.4 • In (ILProg • 32)
ILProg
ILProg
Note 15.
6.0V when AOV-pin is not connected, 3.9V
when AOV-pin is connected to AGND.
Note 16.
2.2VRMS if AOV-pin is left open and 0.4VRMS
if AOV-pin is connected to AGND.
Note 17.
6.8V when AOV-pin is left open, 4.2V when
AOV-pin is connected to AGND.
17
Preliminary
PBL 386 65/2
Ordering Information
Package
28pin PLCC Tube
Temp. Range
Part No.
-40° - +85° C PBL 386 65/2QNS
28pin PLCC Tape & Reel -40° - +85° C PBL 386 65/2QNT
28pin SSOP Tape & Reel -40° - +85° C PBL 386 65/2SHT
Information given in this data sheet is believed to be
accurate and reliable. However no responsibility is
assumed for the consequences of its use 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 Ericsson Microelectronics AB. These products
are sold only according to Ericsson Microelectronics
general conditions of sale, unless otherwise confirmed
in writing.
Specifications subject to change without
notice.
1522-PBL 386 65/2 Uen Rev. F
© Ericsson Microelectronics AB, 2000
This product is an original Ericsson product
protected by US, European and other
patents.
Ericsson Microelectronics AB
SE-164 81 Kista, Sweden
Telephone: +46 8 757 50 00
18