NSC TP5700AN

TP5700A
Telephone Speech Circuit
General Description
Features
The TP5700A is a linear bipolar device which includes all
the functions required to build the speech circuit of a telephone. It replaces the hybrid transformer, compensation circuit and sidetone network used in traditional designs. When
used with an electret microphone (with integral FET buffer)
and dynamic receiver, superior audio linearity, distortion and
noise performance are obtained. Loop attenuation compensation is also included.
The low voltage design enables the circuit to work over a
wide range of operating conditions, including long loops, extension telephones and subscriber carrier applications.
Operating power is derived from the telephone line.
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
5 mA – 120 mA loop operation
Voltage swing down to 1.0V
Electret microphone amplifier
Receive amplifier with push-pull outputs
Automatic gain compensation for loop length
Sidetone impedance independent of input impedance
DTMF interface with muting
Voltage regulator outputs for DTMF generator etc.
Works in parallel with a standard phone on 20 mA loop
Available in small outline surface mount package
Simplified Block Diagram
TL/H/5201 – 1
C1995 National Semiconductor Corporation
TL/H/5201
RRD-B30M115/Printed in U. S. A.
TP5700A Telephone Speech Circuit
December 1989
Absolute Maximum Ratings
Operating Temperature, TA
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
V a with Respect to Vb
Voltage at Any Other Pin
b 25§ C to a 70§ C
Power Dissipation (Note 3)
1W
b 65§ C to a 150§ C
Storage Temperature, TS
Junction Temperature
150§ C
Lead Temperature (Soldering, 10 seconds)
300§ C
20V
V a a 0.3V to Vb b 0.3V
DC Electrical Characteristics
Unless otherwise specified, all tests based on the test circuits shown in Figure 1 , all limits printed in bold characters are
guaranteed at TA e 0§ C to a 60§ C by correlation with 100% testing at TA e 25§ C. All other limits are assured by by correlation
with other production tests, and/or product design and characterization.
Symbol
VT-R
VI
Parameter
Conditions
Tip-Ring Voltage including
nominal 1.4V polarity guard
(See Figure 1 )
ILOOP e 5 mA
e 20 mA
e 50 mA
e 80 mA
e 120 mA
Minimum Instantaneous
Voltage Swing
V a to Vb
ILOOP e 5mA
Min
Typ
Max
2.8
Units
7
10.5
15
V
V
V
V
V
1.0
V
4.5
TRANSMIT AMPLIFIER
RXIN
Input Resistance
From Pin 7 to Vb
15
30
50
kX
GXA
Gain at 1 kHz
RAGC e 0X to Vb
ILOOP e 20 mA, TA e 25§ C only
33
35
37
dB
g1
dB
GXT
Gain Variation v. TA
GXI
Gain Variation v. ILOOP
ILOOP e 20 to 100 mA
b6
NX
Transmit Noise
MIC IN1 e 0V
12
18
S/DX
Signal/Total Harmonic
Distortion
ILOOP t 20 mA
VL e 800 mVrms
2
10
GXM
Gain Change when MUTED
MUTE IN t VMON
b 55
dB
dBrnC
%
dB
DTMF AMPLIFIER
RDIN
Input Resistance
From Pin 8 to Vb
GXD
Gain at 1 kHz
RAGC e 0X to Vb
ILOOP e 20 mA, TA e 25§ C only
10
20
55
kX
S/DXD
Signal/Total
Harmonic Distortion
ILOOP e 20 mA
VL e 1.06 Vrms, TA e 25§ C only
3.5
5.5
7.5
dB
3
10
%
GXDT
Gain Variation v. TA
g1
dB
GXDI
Gain Variation v. ILOOP
ILOOP e 20 to 100 mA
b6
dB
IMIN
Input Current
Pin 9 e 1.5V
40
VMOFF
MUTE OFF Input Voltage
VMON
MUTE ON Input Voltage
MUTE INPUT
mA
0.5
1.5
2
V
V
DC Electrical Characteristics (Continued)
Unless otherwise specified, all tests based on the test circuits shown in Figure 1 , all limits printed in bold characters are
guaranteed at TA e 0§ C to a 60§ C by correlation with 100% testing at TA e 25§ C. All other limits are assured by by correlation
with other production tests, and/or product design and characterization.
Symbol
Parameter
Conditions
Min
Typ
Max
Units
20
35
55
kX
b4
b 2.5
dB
RECEIVE AMPLIFIER
RRIN
Input Resistance
From Pin 12 to Vb
GRA
Gain at 1 kHz
RAGC e 0X, MUTE IN s VMOFF
ILOOP e 20 mA, TA e 25§ C only
GRT
Gain Variation v. TA
GRI
Gain Variation v. ILOOP
ILOOP e 20 to 100 mA
GRM
Gain Change when MUTED
MUTE IN t VMON
NR
Receive Noise
S/DR
Signal/Total Harmonic
Distortion
VRC
Output Clipping Level
ILOOP t 20 mA
1
VROS
Output Offset Voltage
b 5.5
g 0.5
dB
b6
b 15
dB
b 20
b 23
dB
VRCVIN e 0V
0
10
dBrnC
VR e 200 mVrms
ILOOP t 20 mA
2
10
%
Vp-p
g 100
mV
SIDETONE CHARACTERISTICS
STC
Sidetone Cancellation at 1kHz
20 mA s ILOOP s 100 mA, (Note 2)
11
15
dB
2
3
3.2
V
V
200
2.7
mA
mA
VOLTAGE REGULATOR OUTPUTS
VREG1
Output Voltage, Pin 10
ILOOP t 20 mA
MUTE IN s VMOFF
MUTE IN t VMON
IREG1
Maximum Output Current,
Pin 10
MUTE IN s VMOFF
MUTE IN t VMON
VREG2
Output Voltage, Pin 11
ILOOP t 20 mA
1.1
1.2
V
IREG2
Maximum Output Current, Pin 11
ILOOP t 20 mA
300
500
mA
TL/H/5201 – 3
TL/H/5201 – 2
1b. Test Circuit for Receive
1a. Test Circuit for Transmit and Sidetone
FIGURE 1. Test Circuits for Electrical Characteristics
Note 1. Adjust VDC to set specified ILOOP current.
Note 2. To measure Sidetone Cancellation, set oscillator in Fig. 1a for VL e 100 mVrms; measure VS. Then in Fig. 1b set oscillator e 100 mVrms; measure VR.
STC e 20log VR/VS.
Note 3. For operation above 25§ C, the device must be derated based on a 150§ C maximum junction temperature and a thermal resistance of 70§ C/W junction to
ambiant.
MICROPHONE AMPLIFIER
A single-ended input amplifier on the TP5700A enables a
low cost electret microphone to be used. This provides superior distortion, linearity and noise performance compared
to a traditional carbon microphone. The electret should be
capacitively coupled to the amplifier input. The acoustic
sensitivity of the microphone is intended to be in the range
of b60 to b70 dBV/mBar.
Loss can be inserted if required by adding a resistive potentiometer either at MIC IN1 or the connection between the
pre-amp output and driver stage input. The driver stage pro-
Functional Description
The TP5700A Telephone Speech Circuits are powered from
the telephone Tip and Ring terminals via a full-wave rectifier
bridge to protect against loop polarity reversals. The devices provide the following functions:
LINE REGULATOR
A DC regulator sinks current from the loop in order to maintain a DC slope resistance similar to that of a standard phone.
RDC provides an adjustment for the slope resistance.
3
DTMF AMPLIFIER
Functional Description (Continued)
An additional transmit amplifier is included to enable the
open-emitter output of a conventional DTMF generator to
be connected to the line via the transmit output stage. This
path includes the transmit AGC section. When the MUTE
input is pulled high, the DTMF input is enabled and the MIC
input disabled. When MUTE IN is open-circuit or pulled to
Vb the DTMF input is switched off and the MIC input is
enabled.
vides automatic gain compensation to reduce the gain as
loop length decreases. The AGC range can be adjusted by
means of RAGC to limit the maximum loss on a short loop
from 0 to 6 dB.
RECEIVE AMPLIFIER
This buffer amplifier provides the necessary gain or loss for
the receive signal. RCV IN should be AC coupled to SIDETONE (pin 4). Automatic gain control is built into the amplifier to reduce the gain as loop length decreases. The AGC
range is adjusted in common with the transmit AGC range
with a range of adjustment for maximum loss from 0 to 6 dB.
Push-pull complementary outputs provide balanced direct
drive to a dynamic transducer, which may have an impedance as low as 100X. The effective receive gain can be
reduced by adding a resistor in series with the transducer.
The receive gain is automatically reduced by 20 dB when
the MUTE input is pulled high.
VOLTAGE REGULATOR OUTPUTS
A precision band-gap voltage reference controls a regulator
to provide bias for internal circuits. Two auxiliary outputs are
also available. VREG1 is provided specifically for powering a
low voltage pulse dialer or DTMF generator. In order to protect this output in low voltage situations where the instantaneous voltage across the Speech Circuit may swing below
the VREG1 output voltage, an internal switch controls the
maximum available output current. In speech mode, MUTE
IN is low, VREG1 output will track approximately (/2 the TipRing voltage and the available output current is limited to
200 mA. This is adequate to power a DTMF generator in
standby mode. When MUTE IN is pulled high to switch the
Speech Circuit to the DTMF dialing mode, VREG1 is
switched to a 3V regulated output and up to 2 mA may be
drawn from it to power the active DTMF generator.
A 1.2V regulated output is also provided at VREG2 to power
a low voltage 2-wire electret microphone such as the Primo
EM80-PMI2.
SIDETONE CIRCUIT
The level of Sidetone cancellation may be adjusted by connecting an external balance impedance to SIDETONE (pin
4) and coupling this point to V a . For good sidetone cancellation the balance impedance should be approximately 10
times the subscriber line input impedance. Some typical
component values to match a precise 600X termination for
test purposes are shown in Figure 2. Use the component
values shown in the Applications Section for better results
over a wide range of telephone line impedances.
TL/H/5201 – 4
* See Figure 3
Note: ZBAL circuit shown is for test purposes with a resistive line termination. See Applications Information for suggested component values for normal reactive line
applications.
FIGURE 2. TP5700A Telephone Speech Circuits
4
Connection Diagram
Dual-In-Line Package
TL/H/5201 – 5
Top View
Order Number TP5700AM or TP5700AN
See NS Package M16B or N16A
Pin Descriptions
Pin 12 RCV IN
The receive AGC amplifier input.
Pin 13 V a
Pins 1, 2 RCV0 a and RCV0b
The push-pull complementary outputs of the receive amplifier. Dynamic transducers with a minimum impedance of 100
X can be directly driven by these outputs.
Pin 3 Vb
This is the positive supply input to the device and should be
connected to the positive output of the polarity guard. The
current through this pin is modulated by the transmit signal.
Pin 14 RDC
This is the negative supply input to the device and should be
connected to the negative output of the polarity guard. All
other voltages on the device are referred to this pin.
Pin 4 S/T
This is the output of the Sidetone cancellation signal, which
requires a balance impedance of approximately 10 times
the subscriber’s line impedance to be connected from this
pin to V a (pin 13).
Pin 5 XDI
The input to the line output driver amplifier. Transmit AGC is
applied in this stage.
Pin 6 XPO
This is the transmit pre-amp output which is normally capacitively coupled to pin 5.
Pin 7 MIC IN1
An external 1W resistor is required from this pin to Vb to
control the DC input impedance of the circuit. The nominal
value is 56X for low voltage operation. Values up to 82X
may be used to increase the available transmit output voltage swing at the expense of low voltage operation.
Pin 15 VBIAS
This internal voltage bias line must be connected to V a via
an external resistor, Ro, and decoupled to Vb with a 22 mF
capacitor. Ro dominates the AC input impedance of the circuit and should be 620X for a 600X input impedance or
910X for a 900X input impedance.
Pin 16 RAGC
The range of transmit and receive gain variations between
short and long loops may be adjusted by connecting a resistor from this pin to Vb (pin 3). Figure 3 shows the relationship between the resistor value and the AGC range. This pin
may be left open-circuit to defeat AGC action.
This is the inverting input to the transmit pre-amplifier and is
intended to be capacitively coupled to an FET-buffered
electret microphone.
Pin 8 DTMF IN
The DTMF input which has an internal resistor to Vb to
provide the emitter load resistor for a CMOS DTMF generator. This input is only active when MUTE IN (pin 9) is pulled
high.
Pin 9 MUTE IN
The MUTE Input, which must be pulled at least 1.5V higher
than Vb to mute MIC IN and enable DTMF IN.
Pin 10 VREG1
The regulated output for biasing a pulse dialer or DTMF
generator. A 4.7 mF decoupling capacitor to Vb should be
fitted if this output is used.
Pin 11 VREG2
TL/H/5201 – 7
A 1.2V regulated output suitable for powering a low-voltage
electret microphone. A 1mF decoupling capacitor to Vb
should be fitted if this output is used.
FIGURE 3
5
Applications Information
erating voltage ranges. There are four methods of powering
the microphone.
The TP5700A and TP5700 are flexible circuits designed
with several user adjustments to enable the performance to
be optimized for different applications. The choice of transducer types and the cavities in which they are mounted will
also greatly influence the acoustic performance of the telephone. Some of the consequences of circuit adjustments
are as follows:
1. The 1.2V VREG2 output provides the lowest voltage method for microphones rated down to 1V. VREG2 must be
decoupled with a 1 mF capacitor to ground. (See Figure
5 .)
2. If VREG1 is not required for DTMF generator operation, it
may be used to provide up to 200 mA for microphone
power.
3. VBIAS (pin 15) may be used as a decoupled, but unregulated, supply for electrets requiring a higher operating
voltage than VREG1 or VREG2. The additional current
drawn through Ro will, however, raise the minimum operating voltage of the Speech Circuit. If this method is used
the decoupling capacitor must be increased to at least
100 mF to maintain good low frequency return loss. (See
Figure 4 .)
4. An electret type with a good power supply rejection ratio
can be powered from V a , or a regulated and decoupled
supply dropped from V a .
RDC ADJUSTMENT
56X is the recommended value for RDC if it is required to
meet a maximum Tip-Ring voltage of 4.5V on a 20 mA loop
(assuming no more than 1.4V is dropped across the polarity
guard). If a higher Tip-Ring voltage is acceptable, RDC may
be increased, which will provide a small increase in the
available transmit output voltage swing before clipping occurs. RDC should be less than 82X to avoid exceeding the
maximum rated voltage on a short loop.
RAGC ADJUSTMENT
The available AGC range is more than adequate to compensate for the loss of most loops. RAGC should be chosen
only to partly compensate for the anticipated maximum loop
loss, as over-compensation may tend to exaggerate the variations of sidetone with loop length.
TONE DIALING TELEPHONE
Figure 4 shows the TP5700 directly interfacing to a low voltage DTMF generator. VREG1 supplies the necessary 2V
minimum bias to enable the low voltage tone dialer to sense
key closures and pull its MUTE output high. VREG1 then
switches to a 3V regulated output to sustain the Tone Dialer
during tone generation. The TP5700A DTMF input incorporates the necessary load resistor to Vb and provides gain
plus AGC action to compensate for loop length. A muted
tone level is heard in the receiver. For DTMF generators
with a higher output level, a resistive potentiometer should
SIDETONE ADJUSTMENT
The component values used for ZBAL should be selected to
provide a clear sidetone sound without excessive ‘‘hollowness.’’ The capacitor value and ratio of the two resistors will
fix the pole location. To avoid reducing the low voltage performance of the circuit the sum of the two resistors should
not exceed 10 kX.
POWERING ELECTRET MICROPHONES
Electret microphones with integral FET buffers are available
in both two-wire and three-wire versions and a range of op-
TL/H/5201 – 8
FIGURE 4. Typical Tone Dialing Telephone
6
Applications Information (Continued)
VREG1 is used in its non-regulated mode and its output voltage may fall to 2V on a 20 mA loop. A 100 mF decoupling
capacitor is required to hold up the pulse dialer supply voltage during dialing. This capacitor will take about one second
to charge up when the telephone is first connected to the
line, but thereafter the 20 MX resistor required to retain the
last-number dialed memory will keep this capacitor charged.
Partial muting is obtained by directly connecting the N-channel open-drain MUTE output of the pulse dialer to the RCV
IN pin on the Speech Circuit.
A fully muted pulse dialer design requires the use of a shuntmode dialer.
be added to reduce the level at the speech circuit DTMF
Input. For application requiring higher DTMF level, the signal
swing across the device can be raised by using 620X in
series with 270X for RO. The 270X has to be bypassed by a
10 mf capacitor in order to maintain same AC off hook impedance.
PULSE DIALING TELEPHONE
The TP5700A can reduce the number of components required to build a pulse dialing telephone, as shown in Figure
5 . The usual current source can be eliminated by using the
VREG1 output to power a low-voltage (1.7V) series mode
pulse dialer via a blocking diode. A low forward-voltage drop
diode such as a Schottky type is necessary because
TL/H/5201 – 9
*Low voltage drop diode (e.g. Schottky)
² Low leakage type
Ý Indicates National Semiconductor discrete transistor process number
FIGURE 5. Typical Pulse Dialing Telephone
7
TP5700A Telephone Speech Circuit
Physical Dimensions inches (millimeters)
Lit. Ý113984
Order Number TP5700AM
NS Package Number M16B
Molded Dual-in-Line Package (N)
Order Number TP5700AN
NS Package Number N16A
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