MITEL MH88630

MH88630

Central Office Interface (LS/GS)
Preliminary Information
Features
ISSUE 7
•
Transformerless 2-4 Wire conversion
•
Line state detection outputs:
-
Ordering Information
MH88630
forward current
reverse current
ring ground
tip ground
ringing voltage
40-Pin DIL Package
0°C to 70°C
Description
•
Programmable audio transmit and receive gain
•
Loop start or ground start termination
•
Selectable 600Ω or AT&T compromise balance
network
Applications
•
•
•
•
April 1995
The Mitel MH88630 Central Office Trunk Interface
circuit provides a complete audio and signalling link
between an audio switching equipment and a central
office. The loop seize circuitry is controlled by an
external input to provide either a loop start or ground
start termination. The device is fabricated using thick
film hybrid technology to achieve high density circuit
design.
PBX Interface to Central Office
Channel bank
Intercom
Key system
RG FC
T
R
RV RC TG
LPGND RINGND
VCC+ VCC- AGND
Ring
Ground
Relay
Driver 1
Signal Detection
Circuitry
Relay
Driver 2
VTR+
VTRRXINRXIN+
Network
Balance
Active
Termination
QB QE XA XB
GSX
VX
VR
GSR
Audio Section
Circuitry
(2 - 4 Wire)
XC
VDD
VEE
RXOUT
TXIN+
RC1
RD1
RGND
CD
RD2
RC2
NETBAL
TXIN-
Figure 1 - Functional Block Diagram
2-215
MH88630
Preliminary Information
IC
T
R
IC
IC
LPGND
RINGND
VTR+
QE
QB
VTRXA
XB
XC
RGND
RC1
RD1
CD
RD2
RC2
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
RG
FC
RV
RC
TG
VDD
VEE
AGND
RXINRXIN+
NETBAL
VX
GSX
TXIN+
TXINVCCVCC+
RXOUT
GSR
VR
Figure 2 - Pin Connections
Pin Description
Pin #
Name
1
IC
Internal Connection. Pin cut short. Leave open circuit.
2
T
Tip (Input). Normally connects to the “Tip” lead of the C.O.
3
R
Ring (Input). Normally connects to the “Ring” lead of the C.O.
4
IC
Internal Connection. Leave open circuit.
5
IC
Internal Connection. Leave open circuit.
6
LPGND
Loop Ground is the system ground reference with respect to -48 volts.
7
RINGND
Ring Ground (Input). For Ground Start Trunk only, a logic low input will enable the trunk
circuit to ground the Ring lead through a low resistance (390Ω). This is a signal to the
C.O. that the interface is seizing the line.
8
VTR+
9
QE
Connects to the emitter of an external transistor (Q1).
10
QB
Connects to the base of an external transistor (Q1).
11
VTR-
12
XA
External relay contact (K1) connection from VTR+ (pin 8), activated by loop seize control
input (RC1).
13
XB
External relay contact (K1) connection from XC (pin 14), activated by loop seize control
input (RC1).
14
XC
External relay contact (K1) connection from XB (pin 13), activated by loop seize control
input (RC1).
15
RGND
16
RC1
Relay Control 1 (Input). A logic high will activate the relay (K1) to provide loop seize
across Tip and Ring.
17
RD1
Relay Driver 1 (Output): Open collector sinks current when RC1 is high. Diode clamp
protected.
18
CD
Clamping Diode: Normally connects to the positive supply voltage.
2-216
Description
Connects to the collector of an external transistor (Q1) and TXIN - (pin 26) via an
external capacitor.
Connects to the TXIN+ (pin 27), via an external capacitor (C1).
Relay Ground.
MH88630
Preliminary Information
Pin Description (Continued)
Pin #
Name
Description
19
RD2
Relay Driver 2 (Output): Open collector sinks current when RC2 is high. Diode clamp
protected.
20
RC2
Relay Control 2 (Input): A logic high will activate the relay (K2) to provide proper
biasing to the tip and ring. This input control is used for Ground Start Trunk only.
21
VR
22
GSR
23
RXOUT
24
VCC+
Positive analog Power Supply Voltage (+12V).
25
VCC-
Negative analog Power Supply Voltage (-12V).
26
TXIN-
Transmit (Input). Different audio signal from VTR+ (pin 8), via an external capacitor
(C4).
27
TXIN+
Transmit (Input). Different audio signal from VTR- (pin 11), via an external decoupling
capacitor (C1).
28
GSX
Gain Setting Transmit (Input). Normally used to set the transmit gain with an external
resistor connected to VX (pin 29).
29
VX
30
NETBAL
Network Balance (Input). When there is no connection (open), the network is balanced
at 600Ω. When this pin is grounded, the network is balanced at AT&T compromise.
31
RXIN+
Differential Receive (Input). Connects to analog ground via an external capacitor (C2).
32
RXIN-
Differential Receive (Input). Connects to RXOUT (pin 23) via an external capacitor
(C3).
33
AGND
Analog Ground.
34
VEE
Negative Power Supply (-5V).
35
VDD
Positive Power Supply (+5V).
36
TG
Tip Lead Ground Detect (Output). Active low.
37
RC
Reverse Loop current Detect (Output). Active low.
38
RV
Ringing Voltage Detect (Output). Active low.
39
FC
Forward Loop Current Detect (Output). Active low
40
RG
Ring Lead Ground Detect (Output). Active low.
Audio Receive (Input). The 4-wire audio signal input to the interface.
Gain Setting Receive (Input). Normally used to set the receive gain with an external
resistor connected to RXOUT (pin 23).
Audio receive signal (output) to the RXIN- (pin 32), via an external decoupling capacitor
(C3).
Audio Transmit (Output). The 4-wire audio signal output from the interface.
2-217
MH88630
Functional Description
The MH88630 is a Central Office Loop Start and/or
Ground Start Analog Trunk interface circuit providing
a complete audio and signalling link to the Central
Office.
The trunk interface circuit performs transformerless
2 to 4 wire conversion, between the 2-wire telephone
loop and the 4-wire transmit and receive pairs of a
voice switching system. The 4-wire connection can
be interfaced to a filter/codec, such as the MT896X,
for use in a digital voice switched system.
Voiceband analog signals, coming from the C.O.,
applied differentially across Tip and Ring, pass
through a bridge rectifier and appear at VTR+ and
VTR- where they are actively terminated. Refer to
Fig 3 - Application Circuit. External capacitors C1
and C4 couple the incoming signals into the
balanced input of the receive audio circuit via TXIN+
and TXIN-. The receive gain is adjusted by feedback
resistor R4. For best performance R4 should be
physically located as close as possible to the GSX
pin. The gain adjusted receive signal appears at the
Vx output pin.
Relay K1 is the loop seize relay which applies active
line termination and also provides biasing of the
current modulator circuit. Activating and deactivating
K1 provides dial pulsing. Q1 is the current modulator
output transistor, referred to as the loop drive
transistor.
Outgoing analog signal from the system are provided
to the interface at the VR input where they enter an
amplifier section with the gain controlled by the
selection of the Tx gain feedback resistor R3. For
best performance, R3 should be physically located
as close as possible to the GSR pin. The output of
the amplifier, RXOUT is coupled to RXIN- the current
modulator circuitry, via C3. The balanced input to the
current modulator is completed with the connection
of C2 from RXIN+ to ground. Transmission to the
C.O. is accomplished by modulating the loop with the
outgoing analog signals. To ensure that the
transmitted signals are not coupled to the receive
circuitry, transhybrid loss is maximised. The
impedance matching, performed by the balanced
network reduces power loss and signal reflections.
The network balance input, NETBAL, of the
interface’s 2-wire to 4-wire converter circuitry
provides selection of a 600Ω balance, used when
feeding channel banks or when performing external
2-218
Preliminary Information
tests on the trunk circuit, or the AT&T compromise.
With the NETBAL input pin left the interface is
balanced to match to 600Ω. If the NETBAL input pin
is grounded, the interface is balanced against the
AT&T compromise network consisting of 350Ω plus
1kΩ shunted by a 0.21µF capacitor. This is intended
for typical North American C.O. connections.
The Tip and Ring also enter the balanced input of the
signal detection circuitry which provides the
signalling status outputs TG, RC, RV, FC and RG.
For Ground Start signalling, relay K2 and resistor R1
and R2, are required. Activation of K2 is controlled
by the relay control logic input signal RC2. In the idle
state, K2 is closed connecting the -48Vdc supply to
Tip and Ring through biasing resistors R1 and R2.
Upon detection of TG or RG, the system them pulls
RC1+ low closing K1, then pulls RC2 low which
opens K2 to remove the -48V volts supply from Tip
and Ring.
In the Ground Start signalling environment, initiating
a call to the C.O. is preformed by the following
sequence of events. The system provides a logic low
on the ring ground input pin of the interface. This
activates the circuit which grounds the ring lead
through a current limiting resistance. The C.O.
recognises the ground condition and connects the tip
lead to ground. The interface senses this condition
and the tip lead ground detect output switches to a
logic low. The system then applies active line
termination by closing K1 using RC1 and opens K2
using RC2. A call from the C.O. can be performed
similarly. The C.O. can signal to the interface by
pulling either Tip or Ring to ground potential, or by
applying ringing voltage to the ring lead.
Signal Detection Circuitry
The signal detection circuit provides the signalling
status output. The system, controlling the interface,
monitors these active low logic outputs. RV is the
Ringing Voltage detect output. When the C.O.
applies ringing voltage to the termination, the trunk
interface provides a 50ms debounced outputs at RV
during the ringing burst period. This output will
remain low for approximately 50ms after the C.O.
removes the ringing voltage. Ringing voltage above
40 VRMS at 20 Hz will be detected.
TG is the Tip lead Ground detect output and RG is
the Ring lead Ground detect output. The TG and RG
outputs provide a means of determining call
origination or other handshaking functions. The high
MH88630
Preliminary Information
impedance detection circuitry of the interface will
detect both Tip and Ground and Ring Ground
voltages above approximately -15.3V of true ground.
RC is the Reverse loop current detect output and FC
if the Forward loop Current detect output. The RC
and FC outputs of the interface are used to
determine the polarity of the Tip and Ring pair which
the C.O. uses for signalling during the active (off-hook)
state of the interface. When the loop is closed by the
interface, the trunk is in the normal or unreversed
state. Some C.O.’s may reverse the polarity of Tip and
Ring, to indicate the talking state. The interface will
detect this condition and RC will output a low level.
is provided on the hybrid. R1 and R2 provide the
-48V biasing the signalling (on-hook) state.
R6 and C6 constitute the Dummy Ringer required for
the LS/GS trunk. These components are also part of
the 600Ω input impedance.
A protection circuit on the Tip and Ring inputs may
be required depending upon the trunk interface
application. For maximum protection it is
recommended to place fuses in series with the Tip
and Ring inputs of the interface, following by metal
oxide varistors from Tip and Ground, Ring to Ground
and Tip to Ring.
External Circuitry Requirements
Components List (for Figure 3)
The loop seize circuit is completed with the addition
of external components Q1, C5, R5 and K1.
R1*, R2
K1, a DPST reed relay, is activated by relay control
signal RC1. When the loop seizure is required, K1 is
closed and the interface applies active termination
across Tip and Ring. The relay should have a 0.5
amp contact capability and 12 VDC operation with a
typical 500Ω coil resistance. To prevent back EMF
from damaging the relay drive transistor, (caused by
the collapsing field of the inductive coil of the relay) a
snubbing diode is provided on the hybrid and
therefore not required externally. C5 and R5 provide
relay contact noise filtering and transient noise
suppression necessary for clamping inductive spikes
created when the loop is closed during line seizure
or dial pulsing.
Q1 provides current drive for the active termination,
controlling the loop current flow of the current
modulator circuitry. Selection of a suitable transistor
for Q1 is made based on worst case conditions
which include fault conditions. A 350 volt, or higher,
rating for Q1 is necessary to meet high voltage
requirements. The Tip and Ring input protection
varistors limit any high voltage spikes to
approximately 300 volts. Under worst case
conditions Q1 must be able to handle close to
100mA of collector current and dissipate two watts
continuously. During pulse dialling, current spikes
are generated due to the inductive nature of the loop.
A 0.5 amp continuous connector current rating is
therefore recommended to provide a safe margin.
= 30.9kΩ, ± 1%, ¼ W
= Receive Gain Adjust Resistor
= 523.2 E3 x Gain VTR/VR
Typical Value = 505kΩ, ±1%, ¼ W
R3
= Transmit Gain Adjust Resistor
= 301.5 E3 x Gain VX/VTR-100 E3
Typical Value = 200kΩ, ± 1%, ¼ W
R5
= 510Ω, ± 5%, ¼ W
R6
= 10kΩ, ± 5%, ¼ W
C1, C2, C3, C4 = 0.22µF, ± 10%, 200V
C5
= 0.1µF, ± 5%, 250V
C6
= 1.0µF, ± 5%, 250V
Q
= 2N5657, NPN 350V, 0.5A, 20W
K1, K2
= 2A Reed relay, E/M 12V
2 Form C Dip
*Note: required for Ground Start applications, not
required for Loop Start applications.
K2, R1 and R2 are required only for Ground Start
applications. K2 is the same type of relay as K1 and
is activated by RC2. Once again the snubbing diode
2-219
MH88630
Preliminary Information
Absolute Maximum Ratings* - Voltages are with respect to AGND.
Parameters
1
DC Supply Voltages
Sym
Min.
Max
Units
VDD -GNDA
-0.3
+6.0
V
VEE -GNDA
-6.0
+0.3
V
+18.0
V
VCC+ -GNDA
2
VCC- -GNDA
-18.0
TSTG
-55
Storage Temperature
V
+125
* Exceeding these values may cause damage. Functional operation under these conditions is not implied.
Recommended Operating Conditions
Parameters
1
2
Operating Supply Voltage
Operating Current
Sym
Min.
Typ‡
Max
Units
VDD
4.75
5.0
5.25
V
VEE
-5.25
-5.0
-4.75
V
VCC+
11.4
12.0
12.6
V
VCC-
-11.4
12.0
-12.6
V
VBat
-48
V
IDD
7.0
mA
IEE
-7.0
mA
ICC+
8.0
mA
ICC-
-8.0
mA
265
mW
70
°C
3
Power Consumption
PC
4
Operating Temperature
TOP
0
Comments
RINGND High
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
Control Inputs State Table
Parameter
Active
Idle
1
RC1
Logic High
Logic Low
2
RC2
Logic High
Logic Low
3
RINGND
Logic Low
Logic High
4
NETBAL
AT&T compromise network
(350Ω + 1kΩ // 0.21µF)
6000Ω network
2-220
AGND
Open (no connection)
°C
MH88630
Preliminary Information
AC Electrical Characteristics†
Characteristics
Sym
Min
Typ‡
Max
Units
VR
40
90
130
Vrms
1
Ringing Voltage
2
Ringing Frequency
3
Operating Loop Current
IL
4
Off-Hook DC Resistance
5
Operating Loop Resistance
6
On-Hook Leakage Current
7
Ring Ground Sink Current
8
Tip and Ring AC Impedance
9
Longitudinal Balance
metallic to longitudinal
20
Ringing Type A, RS-464
70
mA
RT
300
Ω
@18mA
RL
2300
Ω
@18mA
µA
RINGND = 5.0Vdc
mA
-48VDC with 200Ω in
series on Ring lead
Ω
with 10kΩ + 1.0µF
inparallel with Tip and
Ring
60
40
58
53
dB
dB
dB
dB
200-1000Hz
1000-4000Hz
200-1020Hz
1020-3020Hz
20
26
30
dB
dB
dB
200-500Hz
500-1000Hz
1000-3400Hz
3
100
IRG
600
longitudinal to metallic
10
18
Hz
Test Conditions
Return Loss
Trunk to Line
11
Transhybrid Loss (single
frequency) into 600Ω
THL
16
18.5
34
30
dB
dB
dB
200Hz
1000Hz
3000Hz
12
Transhybrid Loss (single
frequency) into AT&T
Compromise
THL
16
18
18
21
dB
dB
200-1000Hz
1000-4000Hz
13
Frequency response (Output
relative to 1kHz,
VTR/VR and VX/VTR)
0.05
0.05
0.05
0.05
dB
dB
dB
dB
200Hz
300Hz
3000Hz
3400Hz
See Note 1
14
Idle Channel Noise
13
dBrncO
C-Message
15
Power Supply rejection ratio
16
Analog signal overload level
(adjustable gain)
-0.15
-0.10
-0.10
-0.15
8
PSRR
40
dB
6
dBm
1kHz, 0dBm=0.775Vrms
into 600Ω.
† AC Electrical Characteristics are over recommended operating conditions unless otherwise stated.
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
Note 1: Input 0dBm at VTR, or input 0.775Vrms at VR. TR-600Ω termination
2-221
MH88630
Preliminary Information
DC Electrical Characteristics - Control Inputs
Characteristics
Sym
Min
1
Input High Voltage
RC1, RC2
RINGND
VIH
2.7
4.5
2
Input High Current
RC1, RC2
RINGND
IIH
2.5
RC1, RC2
RINGND
VIL
RC1, RC2
RINGND
IIL
3
4
Input Low Voltage
Input Low Current
Typ
Max
Units
Test Conditions
V
V
5.0
-100
mA
µA
0.7
V
1.0
1.1
µA
mA
Max
Units
DC Electrical Characteristics*
Characteristics
1
2
3
4
Sym
Min
Typ
Output High Voltage
(TG, RC, RV, FC, RG)
4.75
V
Output High Current
(TG, RC, RV, FC, RG)
0.17
mA
Output Low Voltage
(TG, RC, RV, FC, RG)
-0.3
V
Output Low Sink Current
(TG, RC, RV, FC, RG)
-0.40
mA
* DC Electrical Characteristics are over recommended operating conditions unless otherwise stated.
2-222
Test Conditions
No Load on output
VOH= -2.7Vdc
No Load on output
VOL= -0.4Vdc
MH88630
Preliminary Information
MH88630
C1
DUMMY RINGER
VTR-
2
T
TIP
11
27
TXIN+
LIGHTNING
31
R6
C2
RXIN+
PROTECTION
C6
3
R
RING
32
R1
K2A
C3
RXIN-
R2
33
K2B
RXOUT
AGND
GSR
-48V RETURN 6
XB
23
22
R3
K1A
13
LPGND
-48V BATTERY
14
15
XC
RGND
20
RC2
19
+12V
K2
18
17
K1
16
TXIN-
RD2
VTR+
CD
K1B
26
C4
8
C5
10
R5
QB
Q1
9
RD1
QE
RC1
NETBAL
37
38
12
XA
30
7
RC
RINGND
RV
VR
FC
VX
21
39
29
40
GSX
RG
28
R4
36
TG
VDD VEE
35
+5V
34
-5V
VCC+ VCC24
25
+12V -12V
Figure 3 - Application Circuit
2-223
MH88630
Preliminary Information
2
(50.8)
2
(50.8)
0.015
(0.381)
Components
0.16 ± 0.05
(4.06 ± 1.27)
AAAAAAAA
AAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
0.04
(1.02)
0.030 ± 0.015
(1.91 ± 0.381)
Pin 1
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAA
AAAAAAAA
AAAA
AAAA
AAAAAAAA
AAAA
0.01
(2.54)
0.18 ± 0.015
(4.57 ± 0.381)
Pin 2
Figure 4 - Physical Dimensions of 40 Pin Dual in Line Hybrid Package
2-224