MITEL MH88435AS-PI

MH88435-P
Data Access Arrangement
Preliminary Information
Features
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DS5132
FAX and Modem interface V.34(33k6)
Externally programmable line and network
balance impedances
Programmable DC termination characteristics
IEC950 recognised component
Transformerless 2-4 Wire conversion
Integral Loop Switch
Dial Pulse and DTMF operation
Accommodates parallel phone detection
Line state detection outputs:loop current/ringing voltage/line voltage
Single +5V operation, low on-hook power
(35mW)
Full duplex voice and data transmission
On-Hook reception from the line
Approvable to UL1950
Industrial temperature range available
Applications
Interface to Central Office or PABX line for:
• FAX/Modem (including software modems)
• Electronic Point of Sale
• Security System
• Telemetry
• Set Top Boxes
ISSUE 8
July 1999
Package Information
MH88435AD-P
28 Pin DIL Package
MH88435AS-P
28 Pin SM Package
0°C to +70°C
MH88435AS-PI
28 Pin SM Package
MH88435AD-PI
28 Pin DIL Package
-40°C to +85°C
Description
The Mitel MH88435 Data Access Arrangement
(D.A.A.) provides a complete interface between
audio or data transmission equipment and a
telephone line. All functions are integrated into a
single thick film hybrid module which provides high
voltage isolation, very high reliability and optimum
circuit design, needing a minimum of external
components.
The impedance and network balance are externally
programmable, as are the DC termination
characteristics, making the device suitable for most
countries worldwide.
Isolation Barrier
OptoIsolation
VCC
VBIAS
AGND
Logic Input
Buffer
LC
TIP
RING
Input Buffer
&
Line Termination
Isolation
VR+
Analog
Buffer
VRNB1
NB2
Isolation
THL cancellation
and line
impedance
matching circuit
Analog
Buffer
VLOOP1
VLOOP2
Isolation
Ring & Loop
Buffer
VX
ZA
RV
LCD
LOOP
RS
Network Connections
User Connections
Figure 1 - Functional Block Diagram
2-39
MH88435-P
Preliminary Information
NB1
NB2
VR+
VRVX
LC
ZA
AGND
VCC
VBIAS
LOOP
IC
RS
IC
1
2
3
4
5
6
7
8
9
10
11
12
13
14
28
27
26
25
24
23
22
21
20
19
18
17
16
15
TIP
RING
IC
VLOOP1
VLOOP2
IC
SC
SC
IC
NP
NP
IC
RV
LCD
Figure 2 - Pin Connections
Pin Description
Pin #
Name
1
NB1
Network Balance 1. External passive components must be connected between this pin
and NB2.
2
NB2
Network Balance 2. External passive components must be connected between this pin
and NB1.
3
VR+
Differential Receive (Input). Analog input from modem/fax chip set.
4
VR-
Differential Receive (Input). Analog input from modem/fax chip set.
5
VX
Transmit (Output). Ground referenced (AGND) output to modem/fax chip set, biased at
+2.0V.
6
LC
Loop Control (Input). A logic 1 applied to this pin activates internal circuitry which
provides a DC termination across Tip and Ring. This pin is also used for dial pulse
application.
7
ZA
Line Impedance. Connect impedance matching components from this pin to Ground
(AGND).
8
AGND
9
VCC
10
VBIAS
Internal Reference Voltage. +2.0V reference voltage. This pin should be decoupled
externally to AGND, typically with a 10µF 6.3V capacitor.
11
LOOP
Loop (Output). The output voltage on this pin is proportional to the line voltage across Tip
- Ring, scaled down by a factor of 50.
12,
14,
17,
20,
23,
26
Description
Analog Ground. 4-Wire ground. Connect to earth.
Positive Supply Voltage. +5V.
IC
Internal Connection. No connection should be made to this pin externally.
13
RS
Ringing Sensitivity. Connecting a link or resistor between this pin and LOOP (pin 11) will
vary the ringing detection sensitivity of the module.
15
LCD
16
RV
2-40
Loop Condition Detect (Output). Indicates the status of loop current.
Ringing Voltage Detect (Output). The RV output indicates the presence of a ringing
voltage applied across the Tip and Ring leads.
MH88435-P
Preliminary Information
Pin Description (continued)
18,
19
NP
No Pin. Isolation barrier, no pin fitted in this position.
21,
22
SC
Short Circuit. These two pins should be connected to each other via a 0Ω
link.
24
VLOOP2
Loop Voltage Control Node 2. Used to set DC termination characteristics.
25
VLOOP1
Loop Voltage Control Node 1. Used to set DC termination characteristics.
27
RING
28
TIP
Ring Lead. Connects to the “Ring” lead of the telephone line.
Tip Lead. Connects to the “Tip” lead of the telephone line.
Functional Description
The device is a Data Access Arrangement (D.A.A.). It
is used to correctly terminate a 2-Wire telephone
line. It provides a signalling link and a 2-4 Wire line
interface between an analog loop and subscriber
data transmission equipment, such as Modems,
Facsimiles (Fax’s), Remote Meters, Electronic Point
of Sale equipment and Set Top Boxes.
France’s current limit specification and Germany’s
dial pulse requirements are met by the MH88437.
This device is pin for pin compatible with the
MH88435.
Approval specifications are regularly changing and
the relevant specification should always be consulted
before commencing design.
Line Termination
Isolation Barrier
The device provides an isolation barrier capable of
meeting the supplementary barrier requirements of
the international standard IEC 950 and the national
variants of this scheme such as EN 60950 for
European applications and UL 1950 for North
American applications and is classified as a Telecom
Network Voltage (TNV) circuit.
External Protection Circuit
An External Protection Circuit assists in preventing
damage to the device and the subscriber equipment,
due to over-voltage conditions. See Application Note,
MSAN-154 for recommendations.
Suitable Markets
The MH88435 has features such as programmable
input
and
network
balance
impedance,
programmable DC termination and a supplementary
isolation barrier that makes it ideal for use
throughout the world.
There are a small number of countries with a 100MΩ
leakage requirement that this device does not meet.
These are Belgium, Greece, Italy, Luxembourg and
Spain.
When Loop Control (LC) is at a logic 1, a line
termination is applied across Tip and Ring. The
device is off-hook and DC loop current will flow. The
line termination consists of both a DC line
termination and an AC input impedance. It is used to
terminate an incoming call, seize the line for an
outgoing call, or if it is applied and disconnected at
the required rate, can be used to generate dial
pulses.
The DC termination is approximately 300Ω
resistance, which is loop current dependent. It can
be programmed to meet different national
requirements. For normal operation Pin 22 and Pin
21 should be linked, and a resistor (R2) should be
fitted between VLOOP1 and VLOOP2 as shown in
Figure 5.
The approval specification will give a DC mask
characteristic that the equipment will need to comply
to. The DC mask specifies the amount of current the
DAA can source for a given voltage across tip and
ring. Figure 3 shows how the voltage across tip and
ring varies with different resistors (R2) for a given
loop current.
The AC input impedance should be set by the user to
match the line impedance.
2-41
MH88435-P
Preliminary Information
30
25
20
Iloop=26mA
(V(t-r)
Iloop=20mA
15
Iloop=15mA
10
5
0
200
600
1000
1400
1800
2200
2600
3000
3400
3800
R2(kOhms)
Figure 3 - DC Programming Capabilities
Input Impedance
Where the input impedance (Z) = 600R the equation
can be simplified to:
The MH88435 has a programmable input impedance
set by fitting external components between the ZA
pin and AGND.
Zext = (10 x Z) - 1k3Ω
Zext = 4k7Ω
For complex impedances the configuration shown in
Figure 4 is most commonly found.
Note: A table of commonly used impedances can be
found in the DAA Application’s document MSAN-154.
ZA
R1
Zext = external network connected between ZA and
AGND, Zint = 1.3kΩ (internal resistance).
R2
C1
Network Balance
Figure 4 - Complex Impedances
To find the external programming components for
configuration 4, the following formula should be
used:
The network balance impedance of the device can
be programmed by adding external components
between NB1 and NB2. For countries where the
balance impedance matches the line impedance, a
15kΩ resistor should be added between NB1 and
NB2.
Zext = [(10 x R1)-1k3]+ [10 x R2)//(C1/10)]
Ringing Voltage Detection
e.g. If the required input impedance = 220Ω +
(820Ω//115nF), the external network to be connected
to ZA will be:
Zext = 900Ω + (8k2Ω//12nF)
2-42
The sensitivity of the ringing voltage detection
circuitry can be adjusted by applying an external
resistor between the RS and LOOP pins. With a
short circuit, the threshold sensitivity is ~10Vrms R7
can be calculated using the equation:
MH88435-P
Preliminary Information
R7 = 30 kΩ x (Desired Threshold Voltage - 10Vrms)
Therefore, 300k kΩ gives ~ 20Vrms and 600k kΩ
gives ~ 30Vrms
An AC ringing voltage across Tip and Ring will cause
RV to output TTL pulses at the ringing frequency,
with an envelope determined by the ringing cadence.
Parallel Phone and Dummy Ringer
An external parallel phone or dummy ringer circuit
can be connected across Tip and Ring as shown in
Figure 5. A dummy ringer is an AC load which
represents a telephone’s mechanical ringer.
In normal circumstances when a telephone is onhook and connected to the PSTN, its AC (Ringer)
load is permanently presented to the network. This
condition is used by many PTT’s to test line
continuity by placing a small AC current onto the line
and measuring the voltage across tip (A) and ring
(B).
Today’s telecom equipment may not have an AC load
present across tip and ring (e.g. modems), therefore
any testing carried out by the PTT will see an open
circuit across tip and ring. In this instance the PTT
assumes that the line continuity has been damaged.
To overcome this problem many PTT’s specify that a
"Dummy Ringer" is presented to the network at all
times. Ideally its impedance should be neglible in
the audio band, and high at the ringing frequencies
(e.g. 25Hz). Note that the requirement for the
"Dummy Ringer" is country specific.
Parallel phone detection is used mostly in set-top
box applications. This is when a modem call will
need to be disconnected from the central office by
the equipment when the parallel phone is in the offhook state. This is so that a call can be made to the
emergency services.
To detect this state, additional circuitry will be
required and can be found in the application note,
MSAN-154.
2-4 Wire Conversion
The device converts the balanced 2-Wire input,
presented by the line at Tip and Ring, to a ground
referenced signal at VX, biased at 2.0V. This
simplifies the interface to a modem chip set.
Conversely, the device converts the differential signal
input at VR+ and VR- to a balanced 2-Wire signal
across Tip and Ring. The device can also be used in
a single ended mode at the receive input, by leaving
VR+ open circuit and connecting the input signal to
VR- only. Both inputs are biased at 2.0V.
During full duplex transmission, the signal at Tip and
Ring consists of both the signal from the device to
the line and the signal from the line to the device.
The signal input at VR+ and VR- being sent to the
line, must not appear at the output VX. In order to
prevent this, the device has an internal cancellation
circuit. The measure of this attenuation is
Transhybrid Loss (THL).
The MH88435 has the ability to transmit analog
signals from Tip and Ring through to VX when onhook. This can be used when receiving caller line
identification information.
Transmit Gain
The Transmit Gain of the MH88435 is the gain from the
differential signal across Tip and Ring to the ground
referenced signal at VX. The internal Transmit Gain of
the device is fixed as shown in the AC Electrical
Characteristics table. For the correct gain, the Input
Impedance of the MH88435, must match the specified
line impedance.
By adding an external potential divider to VX, it is
possible to reduce the overall gain in the application.
The output impedance of VX is approximately 10Ω and
the minimum resistance from VX to ground should be
2kΩ.
Example: If R3 = R4 = 2kΩ, in Figure 5, the overall
gain would reduce by 6.0dB.
2-43
MH88435-P
Preliminary Information
Receive Gain
Mechanical Data
The Receive Gain of the MH88435 is the gain from
the differential signal at VR+ and VR- to the
differential signal across Tip and Ring. The internal
Receive Gain of the device is fixed as shown in the
AC Electrical Characteristics table. For the correct
gain, the Input Impedance of the MH88435 must
match the specified line impedance.
See Figure 12, 13 and 14 for details of the
mechanical specification.
With an internal series input resistance of 47kΩ at
the VR+ and VR- pins, external series resistors can
be used to reduce the overall gain.
Overall Receive Gain = 0dB + 20log (47kΩ /
(47kΩ+R5)).
For differential applications R6 must be equal to R5
in Figure 5.
Example: If R5 = R6 = 47k in Figure 5, the overall
gain would reduce by 6.0dB.
Supervisory Features
The device is capable of monitoring the line
conditions across Tip and Ring, this is shown in
Figure 5. The Loop Condition Detect pin (LCD),
indicates the status of the line. The LCD output is at
logic 1 when loop current flows, indicating that the
MH88435 is in an off-hook state. LCD will also go
high if a parallel phone goes off-hook while the DAA
is on-hook. Therefore, line conditions can be
determined with the LC and the LCD pins.
The LOOP pin output voltage, VLoop, is proportional
to the line voltage across Tip and Ring, V (t-r),
scaled down by a factor of 50 and offset by VBias
which is approximately 2V. With the aid of a simple
external detector the LC, LCD and LOOP pins can
be used to generate the signals necessary for
parallel phone operation with a Set Top Box. Refer to
MSAN-154.
If Tip is more positive than ring VLoop < VBias
If Tip is more negative than ring VLoop > VBias
V (t-r) ≈ (VLoop - VBias) * 50
When the device is generating dial pulses, the LCD
pin outputs TTL pulses at the same rate. The LCD
output will also pulse if a parallel phone is used to
pulse dial and also when ringing voltage is present at
Tip and Ring.
2-44
MH88435-P
Preliminary Information
+5V
VLOOP2
VLOOP1
VCC
28
TIP
VX
VR-
L2
R1
MH88435
D2
LOOP
22 21 13 11
9 25 24
TIP
R7
R2
+
RS
C2
VR+
D1
C1
C8
L1
RING
C7
AGND VBIAS
10
8
C6 +
= Ground (Earth)
ZA
7
R3
C3
Analog
Output
4
R5
C4
Analog
Input
3
R6
C5
16
LCD
15
NB1
RING
5
RV
LC
27
R4
NB2
Zext
Ringing Voltage Detect Output
Loop Current Detect Output
6
Loop Control Input
1
2
Analog
Input
ZB
Notes:
1) R1 & C1: Dummy Ringer, country specific
typically 0.39µF, 250V & 3kΩ
2) R2: DC Mask Resistor typical 360kΩ
3) R3 & R4: Transmit Gain Resistors ≥ 2k2
4) R5 = R6: Receive Gain Resistors typically 100k
5) ZB: Network Balance Impedance
6) C2, C6 = 10µF 6V
7) C7 & C8 = 39nF for 12kHz filter and 22nF for
16KHz filter. These can be left off if meter pulse
filtering not required.
8) Zext: External Impedance
9) D1 Zener Diode 6V2
10) L1, L2 = 4m7H 80mA. These can be left off if
meter pulse filtering not required.
11) C3, C4 & C5 = 1µF coupling capacitors
12) R7 = 620kΩ (30V RMS ringing sensitivity)
13) D2 = Teccor P3100SB
Figure 5 - Typical Application Circuit
2-45
MH88435-P
Preliminary Information
.
Absolute Maximum Ratings* - All voltages are with respect to AGND unless otherwise specified.
Parameter
Sym
Min
Max
Units
Comments
1
DC Supply Voltage
VCC
-0.3
6
V
2
Storage Temperature
TS
-55
+125
˚C
3
DC Loop Voltage
VBAT
-110
+110
V
4
Ringing Voltage
VR
150
Vrms
5
Loop Current
ILoop
90
mA
6
Ring Trip Current
ITRIP
180
mArms
VBAT = -56V
250ms 10% duty cycle or
500ms single shot
*Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied.
Recommended Operating Conditions
Parameter
Sym
Min
Typ‡
Max
Units
1
DC Supply Voltages
VCC
4.75
5.0
5.25
V
2
Operating Temperatures
Industrial Temperature
TOP
0
-40
25
70
+85
˚C
90
Vrms
3 Ringing Voltage
VR
75
‡ Typical figures are at 25˚C with nominal +5V supply and are for design aid only
Test Conditions
Loop Electrical Characteristics † Characteristics
1
Sym
Ringing Voltage threshold
Min
Typ‡
Max
Units
7
10
14
Vrms
VR
Test Conditions
Externally Adjustable
2
Ringing Frequency
15
68
Hz
3
Operating Loop Current
15
80
mA
4
Off-Hook DC Voltage
Tip/Ring
6.0
6.0
7.8
V
V
V
10
7
µA
mA
rms
100V DC Note 2.
1000V AC
9
10
µA
VBAT = -50V
+2
+2
+4
+4
ms
ms
5
Leakage Current
(Tip or Ring to AGND)
6
Leakage Current on-hook
(Tip to Ring)
7
Dial Pulse Delay
8
Loop Condition Detect Threshold
Off-Hook
ON
OFF
0
0
5
16
V
Note 3
Test circuit as Fig. 4
ILoop=15mA )Note 1
ILoop=20mA )where R2
=ILoop=26mA ) 360kΩ
Voltage across tip and
ring
†Electrical Characteristics are over Recommended Operating Conditions unless otherwise stated.
‡Typical figures are at 25°C with nominal + 5V supplies and are for design aid only.
Note 1: Refer to EIA/TIA 464 section 4.1.1.4.4.
Note 2: This is equivalent to 10MΩ leakage Tip/Ring to Ground. For countries requiring 100MΩ leakage use the MH88436 with an
enhanced leakage specification.
Note 3: Operation at low loop currents depends on the DC programming resistor between VLoop1/2. The recommended 360K value
will support V34 operation down to 20mA. Voice operation is supported down to 15mA.
2-46
MH88435-P
Preliminary Information
Variations from Standard Loop Electrical Characteristics (MH88435AD-PI/MH88435AS-PI)
Characteristics
1
2
Ringing Voltage Threshold
Sym
Min
VR
17
Operating Loop Current
Typ
Max
22
80
Units
Test Conditions
Vrms
-40˚C to 0˚C
mA
-40˚C to 0˚C
+70˚C to +85˚C
DC Electrical Characteristics †
Characteristics
1
2
3
Sym
Supply Current
ICC
RV,
LCD
Low Level Output Voltage
High Level Output Voltage
VOL
VOH
LC
Low Level Input Voltage
High Level Input Voltage
Low Level Input Current
High Level Input Current
VIL
VIH
IIL
IIH
Min
Typ‡
Max
Units
7
mA
VCC = 5.0V, On-hook
0.4
V
V
IOL = 4mA
IOH = 0.4mA
0.8
V
V
µA
µA
VIL = 0.0V
VIH = 5.0V
2.4
2.0
0
350
Test Conditions
10
400
† Electrical Characteristics are over Recommended Operating Conditions unless otherwise stated.
‡Typical figures are at 25°C with nominal + 5V supplies and are for design aid only.
AC Electrical Characteristics †
Characteristics
Sym
1
Input Impedance
2
Output Impedance at VX
3
Receive Gain (VR to 2-Wire)
4
Frequency Response Gain
(relative to Gain @ 1kHz)
5
Signal Output Overload Level
at 2-Wire
at VX
6
Min
VRVR+
Signal/Noise & Distortion
Max
Units
47k
94k
Ω
Ω
10
Ω
0
1
dB
Test circuit as Fig. 8
Input 0.5V at 1kHz
-0.5
-0.5
+0.4
0
+0.5
+0.5
dB
dB
300Hz
3400Hz
THD < 5% @ 1kHz
dBm
dBm
70
70
dB
dB
25
25
40
40
dB
dB
16
25
dB
Test circuit as Fig.8
300-3400Hz at VR
Note 3
Ω
@1kHz
20
24
24
dB
dB
dB
Test circuit as Fig. 9
200-500Hz
500-2500Hz
2500-3400Hz
Input 0.5V at 1kHz
PSRR
8
Transhybrid Loss
THL
9
2-Wire Input Impedance
Zin
10
Return Loss at 2-Wire
(Reference 600Ω)
RL
ILOOP = 25-75mA
0
0
SINAD
Power Supply Rejection Ratio
at 2-Wire
at VX
Test Conditions
-1
at 2-Wire
at VX
7
Typ‡
14
20
18
ILOOP = 25-75mA
300-3400Hz
Ripple 0.1Vrms 1kHz
on VCC
2-47
MH88435-P
Preliminary Information
AC Electrical Characteristics †
Characteristics
11
Sym
Min
Typ‡
46
46
65
65
dB
dB
60
40
68
62
dB
dB
Max
Units
Longitudinal to Metallic Balance
Metallic to Longitudinal Balance
12
Idle Channel Noise
Test circuit as Fig. 10
300-1000Hz
1000-3400Hz
Test circuit as Fig.11
200-1000Hz
1000-4000Hz
Nc
at 2-Wire
at VX
at 2-Wire
at VX
13
Test Conditions
Transmit Gain (2-Wire to VX)
(Terminated gain)
Off-Hook
(Voltage gain)
-1
On-Hook
10
10
-80
-80
20
20
0
+1
Cmess filter
300-3400Hz filter
dB
Test circuit as Fig. 7
Input 0.5V @ 1kHz
dB
LC = 0V
dB
dB
300Hz
3400Hz
60
dB
ILOOP = 25-75mA
F1 = 1kHz at -6dBm
F2 = 800Hz at -6dBm
Total signal power =
-3dBm
75
dB
ILOOP = 25-75mA
F1 = 1kHz at -6dBm
F2 = 800Hz at -6dBm
Total signal power =
-3dBm
0
-1
-1
dBrnC
dBrnC
dBm
dBm
14
Frequency Response Gain
(relative to Gain @ 1kHz)
15
Intermodulation Distortion
products at VX and 2W
16
Distortion at VX due to near end
echo
(300Hz - 3400Hz bandwidth)
17
Common Mode Rejection on 2 wire
at VX
CMRR
56
dB
Test circuit as Fig. 10
1-100Hz. Note 4
18
Common Mode overload level
CMOL
7
Vrms
Test circuit as Fig. 10.
Note 4
IMD
+0.3
+0.2
+1
+1
†Electrical Characteristics are over Recommended Operating Conditions unless otherwise stated.
‡Typical figures are at 25°C with nominal +5V and are for design aid only.
Note 1: All of the above test conditions use a test source impedance which matches the device’s impedance.
Note 2: dBm is referenced to 600Ω unless otherwise stated.
Note 3: These parameters need to be taken into consideration when designing or specifying the power supply.
Variations from Standard AC Electrical Characteristics
(MH88437AD-PI/MH88437AS-PI) (-40˚C to 0˚C)
Characteristics
1
2-48
Frequency Response Gain
Sym
Min
Typ
-0.6
-0.65
Max
Units
Test Conditions
dB
300Hz (-40˚C to 0˚C)
MH88435-P
Preliminary Information
3
4
15
13
11
RS
LOOP
VR+
LCD
28
TIP
VR-
5
21
22
MH88435
NB1
24
25
1K
5V
= Ground (Earth)
1
VX
15K
NB2
SC
2
SC
RING
360K
ILOOP
27
VLOOP2
10
VBIAS
VLOOP1
LC RV AGND VCC ZA
9
7
6
16 8
4.7K
10uF
5V
Figure 6 - Test Circuit 1
-V
11
= Ground (Earth)
3
4
5
21
22
LOOP
VR+
RS
24
25
1K
5V
100uF
LCD
28
TIP
VR-
NB1
I=20mA
+
1
MH88435
VX
15K
NB2
SC
Vs
Impedance = Zin
2
SC
RING
360K
10H 500Ω
15
13
100uF
27
10H 500Ω
VLOOP2
10
VBIAS
VLOOP1
LC RV AGND VCC ZA
7
9
6
16 8
4.7K
+
10uF
5V
Gain = [20 * Log (VX / Vs)] + 6.02 dB
Figure 7 - Test Circuit 2
2-49
MH88435-P
Preliminary Information
-V
10H 500Ω
= Ground (Earth)
Vs
4
5
21
22
15
13
11
LOOP
3
VR+
RS
LCD
28
TIP
VR-
NB1
24
25
1K
5V
+
1
MH88435
VX
15K
NB2
SC
Zin
2
SC
RING
360K
100uF
I=20mA
100uF
27
+
VLOOP2
10
VBIAS
VLOOP1
LC RV AGND VCC ZA
9
6
16 8
7
4.7K
10H 500Ω
10uF
5V
Gain = 20 * Log (V(Zin) / Vs)
Figure 8 - Test Circuit 3
-V
10H 500Ω
= Ground (Earth)
11
LOOP
3
VR+
4
5
21
22
15
13
RS
VR-
NB1
24
25
1K
5V
100uF
+
V1
MH88435
300Ω
15K
NB2
SC
2
300Ω
SC
100uF
27
10H 500Ω
VLOOP2
10
VBIAS
VLOOP1
LC RV AGND VCC ZA
9
6
16 8
7
4.7K
10uF
5V
Return Loss = 20 * Log (2V1 / Vs)
Figure 9 - Test Circuit 4
2-50
Zin
1
VX
RING
360K
I=20mA
LCD
28
TIP
+
Vs = 0.5V
MH88435-P
Preliminary Information
-V
10H 500Ω
= Ground (Earth)
3
4
5
21
22
15
13
11
RS
LOOP
VR+
VR-
NB1
24
25
1K
5V
+
1
300Ω
MH88435
VX
15K
NB2
SC
V1
2
300Ω
SC
RING
360K
100uF
I=20mA
LCD
28
TIP
100uF
27
VLOOP2
10H 500Ω
V2
VBIAS
Vs = 0.5V
+
10
VLOOP1
LC RV AGND VCC ZA
9
7
6
16 8
4.7K
10uF
5V
Long. to Met. Balance = 20 * Log (V1 / Vs)
CMR = 20 * Log (VX / Vs)
CMOL = V2
Figure 10 - Test Circuit 5
-V
= Ground (Earth)
10H 500Ω
11
3
4
5
LOOP
VR+
15
13
RS
VR-
NB1
24
25
1K
5V
+
300Ω
MH88435
15K
NB2
Vs
2
300Ω
SC
510Ω
V1
100uF
RING
360K
100uF
1
VX
21 SC
22
I=20mA
LCD
28
TIP
27
+
10H 500Ω
VLOOP2
10
VBIAS
VLOOP1
LC RV AGND VCC ZA
9
7
6
16 8
4.7K
10uF
5V
Met. to Long. Balance = 20 * Log (V1 / Vs)
Figure 11 - Test Circuit 6
2-51
MH88435-P
Preliminary Information
0.162 Max (4.12 Max)
0.27 Max
(6.9 Max)
0.063 Max
(1.6 Max)
0.08 Typ (2 Typ)
1.00 Typ *
(25.4 Typ)
* 0.100+0.010
(2.54+0.25)
1.05 Max
(26.7 Max)
0.020 + 0.005
(0.5 + 0.13)
* 0.05 Typ
(1.27 Typ)
0.260+0.015
(6.6+0.38)
* 0.300+0.010
(7.62+0.25)
Notes:
1) Not to scale
2) Dimensions in inches.
(Dimensions in millimetres)
1
3) Pin tolerances are non-accumulative.
4) Recommended soldering conditions:
Wave Soldering - Max temp at pins 260˚C for 10 secs.
1.42 Max
(36.1 Max)
* Dimensions to centre of pin.
Figure 12 - Mechanical Data for 28 Pin DIL Hybrid
0.162 Max (4.11 Max)
0.287 Max
(7.29 Max)
0.063 Max
(1.6 Max)
0.110+0.015
(2.80+0.38)
0.99 Typ
(25.15 Typ)
0.020 + 0.005
(0.5 + 0.13)
* 0.05 Typ
(1.27 Typ)
* 0.100+0.010
(2.54+0.25)
0.060 Typ
(1.52 Typ)
*0.300+0.010
(7.62+0.25)
Notes:
1.15 Max
(29.2 Max)
1) Not to scale
2) Dimensions in inches.
(Dimensions in millimetres)
3) Pin tolerances are non-accumulative.
1
4) Recommended soldering conditions:
Max reflow temp: 220˚C for 10 secs.
* Dimensions to centre of pin.
1.42 Max
(36.1 Max)
Figure 13 - Mechanical Data for 28 Pin Surface Mount Hybrid
2-52
MH88435-P
Preliminary Information
0.10
(2.54)
* 0.26
(6.60)
0.10
(2.54)
0.99
(25.15)
0.04
(1.02)
0.06
(1.52)
Notes:
1) Not to scale
2) Dimensions in inches.
(Dimensions in millimetres)
3) All dimensions are Typical except
where marked with an .This gap is
associated with the isolation barrier.
Figure 14 - Recommended Footprint for 28 Pin Surface Mount Hybrid
2-53
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