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UTC L6726
DESCRIPTION
LINEAR INTEGRATED CIRCUIT
UNIVERSAL SPEECH CIRCUIT
The UTC L6726 is a mask-programmable, monolithic integrated telephones. It is designed for using with a low impedance microphone. Transmitting and receiving gain are regulated with line length. Different regulation for various current feeds can be set by external resistors. Typical current feeds as 48V,2 * 200, 48V,2 * 400,and 36V,2*500, can be handled. Application dependent parameters such as line balance, side tone level, amplification and frequency response are set by external components. Parameters are set independently which means easy adaptation for various market needs. The UTC L6726 is developed for using with CMOS-type dialer ICs. A separate DTMF input is switched when the circuit is muted, and an adjustable DC supply is provided for feeding an external CMOS device. speech circuits for using in electronic
DIP-18
FEATURES
*Minimum number of inexpensive external components, 5 capacitors and 11 resistors. *Mute function for operation with DTMF-generator. *Transmit and receive gain regulation for automatic loop loss compensation. *Extended current and voltage range 5~130mA,down to 2V. *Differential microphone input for good balance to ground. *Balanced receiver output stage. *Short start-up time. *Stabilized DC-supply for low current CMOS dialers and/or electret microphones. *DTMF-input controlled by mute.
UTC
UNISONIC TECHNOLOGIES CO., LTD.
1
QW-R108-015,A
UTC L6726
PIN CONFIGURATION
LINEAR INTEGRATED CIRCUIT
+L TO TI +C Mute GR DCS DCO DCC
1 2 3 4 5 6 7 8 9
18 17 16 15 14 13 12 11 10
RE 2 RE 1 DR RI -L MI 2 MI 1 MO DI
PIN DESCRIPTIONS
Pin No.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18
Pin Name
+L TO TI +C Mute GR DCS DCO DCC DI MO MI 1 MI 2 -L RI DR RE 1 RE 2
Description
Output of the DC-regulator and transmit amplifier. This pin is connected to the line through a polarity guard and diode bridge. Output of the transmit amplifier. This pin is connected through a resistor of 47 to 100 to -L, which sets the DC-resistance of the circuit. The output has a low AC output impedance and the signal is used to drive a side tone balancing network. Input of transmit amplifier. Input impedance 17k20% The positive power supply terminal for most of the circuitry inside the UTC L6726 (about 1mA current consumption).The +C-PIN shall be connected to a decoupling capacitor of 47F to 150F When low, speech circuit is muted and the DTMF input is enabled. Maximum voltage (at mute) is 0.3V,current sink requirement of external driver is 50A Control input for the gain regulation circuitry. The sense input to the DC-supply. The output from the DC-supply. The control output from the DC-supply The input for the DTMF-signal. Input impedance is 25k20% Output of the microphone amplifier or DTMF-amplifier Input to the microphone amplifier. Input impedance 1.7 k20% The negative power terminal, connected to the line though a polarity guard diode bridge Input of receiver amplifier. Input impedance is approximately 38 k20% The control input for the receiver amplifier driving capability. Receiver amplifier outputs. Output impedance is approximately 3.
UTC
UNISONIC TECHNOLOGIES CO., LTD.
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UTC L6726
PARAMETER
Line voltage, tp=2s Line current, continuous Ambient Operating temperature Storage temperature
LINEAR INTEGRATED CIRCUIT
SYMBOL
VL IL Ta Tstg
ABSOLUTE MAXIMUM RATINGS
RATINGS
0~22 0~130 -40~+70 -55~+125
UNIT
V mA C C
ELECTRICAL CHARACTERISTICS (Ta=25
PARAMETER
Line voltage Transmitting gain, note 1 1 Transmitting range of regulation Transmitting frequency response Receiving gain, note 1 1 1 1 Receiving range of regulation Receiving frequency response Microphone input impedance pin12,13 Transmitter input impedance pin 3 Transmitter dynamic output Transmitter max output Receiver output impedance Receiver dynamic output Receiver max output Transmitter output noise Receiver output noise Mute input voltage at mute (active low) DC-supply voltage note 2 1 1 1 1 1 1 1 1 2 1 1 1 1
unless otherwise specified)
FIG.
1
TEST CONDITIONS
IL=15mA IL=100mA 20*10 log(V2/V3), 1kHz RL=0 RL=400 RL=900 ~2.2 k 1kHz, RL=0 ~ 900 200Hz ~ 3.4kHz 20*10 log (V4/V1), 1kHz RL=0 RL=400 RL=900 ~2.2 k 1kHz, RL=0 ~ 900 200Hz ~ 3.4kHz 1kHz, note 3 1kHz 200Hz~3.4kHz 2% distortion, IL=20~100mA 200 Hz~3.4kHz IL=0-100mA,V3=0.1V 1kHz, note 3 200Hz~3.4kHz 2% distortion, IL=20~100mA Measured with line rectifier 200 Hz~3.4kHz, IL=0~100mA, V1=0~50V Psof-weighting, Rel1 Vrms, RL=0 A-weighting, Rel 1Vrms, with cable 0~5km, =0.5mm,0~3km, =0.3mm
MIN
3.3 11 41 43.5 46 3 -1 -18.5 -16 -13.5 3 -1
TYP
3.7 13 43 45.5 48 5
MAX UNIT
4.1 15 45 47.5 50 7 1 -14.5 -12 -9.5 7 1 V dB dB dB dB dB dB dB dB dB dB k k Vp Vp Vp Vp dBpsof dBA 0.3 V V mA
-16.5 -14 -11.5 5 1.7(//2.7) 17 1.5 3 3(+310) 0.5 0.9 -75 -85
IL=10~100mA, IDC=0mA IL=10~100mA, IDC=2mA 2
2.35 2.2 0.1 24.5 26.5 28.5
DC-supply current, pin8 1 DC-output pin8 input leakage VDC=2.35V 3 current (no supply) DTMF transmitting gain 1 VM=0.3V Notes: 1.Adjustable to both higher and lower values with external components. 2.The dynamic output can be doubled, see applications information.
A dB
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UTC L6726
FUNCTIONAL DIAGRAM
LINEAR INTEGRATED CIRCUIT
3.External resistor in the test set up.
1 DTMF input 10
UTC L6726
AD AT AM DC 89 AR
17
12 13
18
Telephone Line
7
5
11
3
2
15
16 6
14
4
DC output for external CMOS device Mute (active low) 3 1 5 2 4
1.Impedance to line and radio interference suppression. 2.Transmit gain and frequency response network. 3.Receive gain and frequency response network. 4.Side tone balance network. 5.DC-supply components.
RL=0~4K 0 when artificail line is used 5H+5H RLoad =400+400
+
MUTE VM IL DTMF +LINE ZMIC=350 V3
C1 1F V2 V1
+
ARTIFICAIAL LINE
MIC
UTC 6726
with external component see fig 3
600
VL
IDC
E=48.5V
REC VDC -LINE
V4
ZRec=350
C1= 1F when artificial line is used 470F when not used Figure 1. Test setup without rectifier bridge
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UTC L6726
RL=0~4K 5H+5H RLoad =400+400
+
LINEAR INTEGRATED CIRCUIT
MUTE VM Uz=(15 ~16)V + DTMF 600 VL IDC IL +LINE ZMIC=350 V3
C1 1F V2 V1
MIC
UTC 6726
with external component see fig 3
E=50V VDC -LINE
REC
V4
ZRec=350
Figure 2. Test setup with rectifier bridge
+Line
1 DTMF input C8 220nF 12 MIC R16 350 27k 13 DC 897 DC supply OUT CMOS device MUTE + 47F C7 R5 22k R6 75 Sense input Control output AM 10 AD AT
UTC 6726
AR
17 R14 310 18 REC 350
5 R4 18k
11
3 C3 100nF
2 R7 910 C4 47nF R11
15 14 6
14 4 R10 82k 910 R3 R1 * + C1 C2 15nF -Line
3k 560 R8 R9 11k R13 C5 11k
47F
R15 R2 * 10
Note : * Not used in test setup
100nF
Figure 3. Circuit with external components for test setup.
FUNCTIONAL DESCRIPTION
The gain of the transmitting and receiving amplifiers are continuously and euqually changed with the line length. The starting point for the gain regulation is externally set .The gain regulation can be cut-off externally, see table under gain regulation below. The outputs of the transmitting and receiving amplifiers have internals limitations of the output amplitudes.
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UTC L6726
LINEAR INTEGRATED CIRCUIT
The circuit includes a temperature independent voltage reference used for regulation of the DC line voltage and for the transmitting and receiving gain regulation. The DC voltage is very fast settled to its final value with a minimum of overshoot. The circuit uses a minimum of external components. In a normal practical case only 5 external capacitors of which only one is an electrolytic/tantalum filter capacitor .The other capacitor are needed as radio interference suppression capacitor over the line, one capacitor in the side-tone balancing network and one capacitor for low frequency cut-off in each of the transmitting and receiving amplifiers. The frequency response is except for that, flat for both amplifiers. The circuit will with external components get a very good return loss behavior both against purely resistive lines as for instance 600 and against complex networks as 900 in parallel with 30nF. To get a good CMRR the microphone input is balanced. It is possible to add a push-button controlled cut-off of the transmitting amplifier to the circuit without any disturbance of the other circuit functions A mute input is included in the circuit. It gives: 1.Cut-off the microphone amplifier. 2.Reduced gain in the receiving amplifier. 3.Connection of the DTMF input. The receiver amplifier is equipped with a high impedance input stage. This gives a less expensive RC-network on the input. Only resistive elements are used to set the receiving gain. A push-pull power stage in the receiving amplifier gives a high output swing. To get the extended low current and voltage range two resistors have to be connected from microphone input to ground. The side-tone balanced can be set by a RC-network without influence on other parameters. An inexpensive solution requires only one capacitor while more capacitors can give better performance. In fig.4 and are RC-links with the following functions: 1.For radio interference suppression and to give the correct return loss behavior. 2.To set the gain and frequency response for transmitting. 3.To set the gain and frequency response for receiving. 4.To set the side-tone level A stabilized DC output, with a pre-set output voltage of 2.35 Volts, is provided to facilitate interfacing to external COMS dialer ICs. The voltage is adjustable with two resistors, as indicated in figure 5. The output requires some filtering to avoid distortion on the telephone line. Note that a high current consumption of the external device will alters the DC characteristics of the speech circuit.
+Line
1 AM 2 AT 4
3
AR
-Line Mute
Transmitting cut-off
Figure 4. Block interconnections
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UTC L6726
LINEAR INTEGRATED CIRCUIT
1 +Line
1.2V
+
-
8 9 15k 15k 7 14
0~470
VDC1 0~470 VDC2
RDC1 RDC2
+ 4.7~47F
+
Figure 5. DC regulator for external CMOS devices
APPLICATIONS INFORMATION
Refer to figure 6.
Gain regulation (R1, R2):
These resistors set the starting point for the gain-and side tone regulation. Input impedance pin 6 is about 5.5 k20%. Below are some typical values for R1 and R2, for some different supplies from telephone stations. Battery feed R1 R2 R6 47~100 22k No regulation Set for short line gain. All feedings Regulation: 48V, 2*200 47 48V, 2*400 75 36V, 2*500 180k 100
Impedance to line (R3, C1, C2):
C1 in series with R3 and those in parallel with C2 give the impedance to the line from the set. C2 must normally be there for the interference too. The network is optimized with regard to the return loss. The time constant R3, C1 cannot be allowed to be too small. If the time constant is to small, distortion at low frequencies may be generated. If R3 is changed this will change the DC-characteristic too, which set by the voltage at pin 4. The input current at pin 4 is about 1mA
Microphone selection (M1, R16):
The microphone can be either dynamic, magnetic or electrets. See figures 12,14 and 15. The input impedance between pin 12 and 13 is about 1.7k with typical variation 20% Transmitting gain and frequency response (R4, R5, C3, C4): The network gives the amplification and frequency response for the transmitter. R5 is used when a greater reduction of the gain is wanted. Input impedance at pin 3 is about 17 k with typical variation 20%.The sum of the
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UTC L6726
DC-characteristics (R6):
LINEAR INTEGRATED CIRCUIT
resistors R4 and R5 must not be less than 35 k because of DC-current to ground. Below is some simple variations of this network. (See figure 7).
Sets the DC-characteristic and take care of some of the supplied power. The resistor have also function with the protection of the circuit, the transmitter, the gain regulation and side tone. Common values are 47 to 100 . Side tone level, receiving gain and frequency response.(R7,R8,R9,R10,R11,C5): The network sets the side tone balance. The network in the application is one of many possibilities. R10 and R11 balance together the signals that go two different ways from the transmitter output stage one from pin1 and the other from pin2. The balance network consist of R8, R9 and C5. The example is not optimized to any specified line, it is only given to show the principle. Fig8, 9 and 10 are examples of balance networks. Fig.10 is especially suited for lines with high current supply.
R12, R13, C6, (R10, R11):
The networks gives the gain and frequency response for the receiver. Input impedance at pin 15 is about 38 k with a typical variation of 20%.For different possibilities for the design of the network, see the network for the transmitter (R4, R5, C3)
REC, R14:
R14 generates the output impedance to the magnetic earphone (fig.11). If a dynamic earphone is used it should be placed between pin 17 and 18.See figure 16.
R15:
This resistor is used to set the driving capability of the receiver output amplifier. Common values are 0 to 50 . Setting it for low driving capability results in function at lower line current. Breaking up pin 16 will give lower power consumption and total mute of the receiver when muting the circuit. Disconnecting pin 15 will of cause also give total receiver mute.
D1, D2, D3, D4, D5:
Rectifier bridge and over voltage protector. The zener voltage at D5 should be as low as possible. Common values are between 12V~16V.
RDC1, RDC2:
Refer to figure 5. The pre-set output voltage of 2.35V can easily, if needed, be changed to another value by applying one or two resistor(RDC1,RDC2) in parallel with the internal resistors (each 15k+/-20%).It is possible to get a rather high voltage and current from the DC-supply as long as the high current and voltage is available from the line. The DC voltage has to be filtered by a capacitor and this can, at high DC-voltage and low line current, interfere with the signal on the line and cause distortion. You can minimize the interference, with a resistor in series with the filter capacitor. The DC voltage will, of course, be more dependent of the DC-supply current. The DC-output pin has a very low input leak current, to allow stand-by feeding of the dialer. It is also possible to use pin 9 to feed microphones etc. that do not need stand-by feeding, without interfering with the stand-by feeding on pin 8. Note that a high current consumption by the external device will alter the DC characteristics of the speech circuit
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UNISONIC TECHNOLOGIES CO., LTD.
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UTC
2 3 6 9 #
1
KEYPAD
UTC L6726
1 5 8 0 10 AD AT 12 13 18 DC 897 5 15 16 6 14 18k 910 6.2k 100nF 560 MUTE out 47F 22k 75 11k 100 nF 11k 10 GND * 910 15nF * 47F 11 3 2 Sense input Control output DC 4 82k 10 AM AR 220nF
4
7
*
UTC L6726
17 UZ=12V
DTMF Output
DTMF dialler (CMOS type)
Telephone Line
Note : * Not used in test setup
UNISONIC TECHNOLOGIES CO., LTD.
Figure 6. Typical tong dialling telephone
LINEAR INTEGRATED CIRCUIT
9
QW-R108-015,A
UTC L6726
DESIGN PROCEDURE:
LINEAR INTEGRATED CIRCUIT
1. Circuit impedance to the line. 2. DC-characteristic 3. Gain regulation. 4. Transmitter gain and frequency response. 5. Receiver gain and frequency response. 6. Side-tone. 7. Components to suppress radio interference, specially the wires up to the handset.
Others:
The circuit can be placed either in the telephone or in the handset. Cut off the transmitter can be done at F1 without interference of other functions of the circuit. When using the extended low current and low voltage range (5mA, 2V), two resistors have to be connected from the microphone inputs to ground as shown in figure 13.
11 RA
3 CA
11
3
2 RA R11 CA
15 R10 +Line
RA RB CB
R6 3
RB
11 RA
3
11 RA CA CB RB
2 RA RB CB R6 RB RC R11
15 R10 +Line
CA
CA
11 RA RB 11
3 CA CA RA
11
3 2 RA RB R6 RC CA R11 CB 3 15 R10 +Line
CA
RB 3 11 RA
RA RB
CA CB RB
CA CB
Figure 8. Examples of network "4"
Figure 7. Examples of network "2"
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UTC L6726
+Line R10 2 R11 RA R12 C6
LINEAR INTEGRATED CIRCUIT
+Line 2 15
Zbal C6 15
RB Rc Low impedance network.
R6
C
* To get flat response for receiving
R12
R6
Figure 9. Typical sidetone network
Figure 10. Sidetone network especially suited for applicatons with a high line current,when R6 has a low value
4 R14 200 200 1F 1F 18 12 13
17
14
Figure11. Magnetic reciever connection
Figure 12. Electret microphone with FET buffer
12
12 MIC 50k 13 50k AM -Line 11
13
Figure 13. Additional components for extended low current/voltage oeration
12
Figure 14. Connection of a magnetic microphone
17
13
18
Figure 15. Connection of a dynamic microphone
Figure 16. Dynamic reviever connection
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UNISONIC TECHNOLOGIES CO., LTD.
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QW-R108-015,A
UTC L6726
LINEAR INTEGRATED CIRCUIT
UTC assumes no responsibility for equipment failures that result from using products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other parameters) listed in products specifications of any and all UTC products described or contained herein. UTC products are not designed for use in life support appliances, devices or systems where malfunction of these products can be reasonably expected to result in personal injury. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice.
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