BT1062A Kodenshi Korea Corp., BT1062A Datasheet - Page 3

BT1062A

Manufacturer Part Number

BT1062A

Description

Telephone Speech Network With Dialer Int`erface

Manufacturer

Kodenshi Korea Corp.

Datasheet

1.BT1062A.pdf (9 pages)

Current page: 3 of 9
Download datasheet (174Kb)

FUNCTIONAL DESCRIPTION

Supplies V

Power for the IC and its peripheral circuits is usually obtained from

the telephone line. The supply voltage is delivered from the line via a

dropping resistor and regulated by the IC. The supply voltage V

may also be used to supply external circuits e.g. dialing and control

circuits.

Decoupling of the supply voltage is performed by a capacitor

between V

a capacitor between REG and V

The DC current flowing into the set is determined by the exchange

supply voltage V

resistance of the telephone

line R

The circuit has internal current stabilizer operating at a level

determined by a 3.6 k : resistor connected between STAB and V

(see Fig.6). When the line current (I

than the sum of the IC supply current (I

the peripheral circuitry connected to V

shunted to V

The regulated voltage on the line terminal (V

voltage of 3.7V and R9 is an external resistor connected between

SLPE and V

In normal use the value of R9 would be 20 " .

Changing the value of R9 will also affect microphone gain, DTMF

gain, gain control characteristics, sidetone level, maximum output

swing on LN and the DC characteristics (especially at the lower

voltages).

Under normal conditions, when I

behaviour of the circuit is that of a 3.7V regulator diode with an

internal resistance equal to that of R9. In the audio frequency range

the dynamic impedance is largely determined by R1. Fig.2 show the

equivalent impedance of the circuit.

ref

is an internally generated temperature compensated reference

line

Fig.2 Equivalent impedance circuit

= V

ref

EE.

and V

+ I

+ {(I

via LN.

SLPE

exch

, LN, SLPE, REG and STAB

line

, the feeding bridge resistance R

x R9

- I

. The internal voltage regulator is decoupled by

- 0.5 x 10

EE.

SLPE

line

-3

A) - I

>>I

) is more than 0.5mA greater

) and the current drawn by

} x R9

+ 0.5mA + I

) the excess current is

) can be calculated as:

exch

and the DC

, the static

At line currents below 9mA the internal reference voltage is

automatically adjusted to a lower value (typically 1.6V at 1mA). This

means that more sets can be operated in parallel with DC line voltage

(excluding the polarity guard) down to an absolute minimum voltage

of 1.6V. At line currents below 9mA the circuit has limited sending

and receiving levels. The internal reference voltage can be adjusted

by means of an external resistor (R

between LN and REG will decrease the internal reference voltage

and when connected between REG and SLPE will increase the

internal reference voltage.

Microphone inputs MIC+ and MIC- and gain pins

GAS1 and GAS2

The circuit has symmetrical microphone inputs. Its input impedance

is 64 k : (2 x 32k : ) and its voltage gain is typically 52 dB (when R7

= 68k " ; see Fig.6).

Dynamic, magnetic, piezo-electric or electret (with built-in FET

source followers) can be used.

The gain of the microphone amplifier can be adjusted between 44 dB

and 52 dB to suit the sensitivity of the transducer in use. The gain is

proportional to the value of R7 which is connected between GAS1

and GAS2.

Stability is ensured by two external capacitors, C6 connected

between GAS1 and SLPE and C8 connected between GAS1 and

VEE. The value of C6 is 100pF but this may be increased to obtain a

first-order low-pass filter. The value of C8 is 10 times the value of

C6. The cut-off frequency corresponds to the time constant R7 x C6.

Input MUTE (KKA1062A)

When MUTE is LOW or open-circuit, the DTMF input is enable and

the microphone and receiving amplifier inputs are inhibited. The

reverse is true when MUTE is HIGH.

MUTE switching causes only negligible clicking on the line and

earpiece output. If the number of parallel sets in use causes a drop in

line current to below 6 mA the DTMF amplifier becomes active

independent to the DC level applied to the MUTE input.

Dual-tone multi-frequency input DTMF

When the DTMF input is enable dialing tones may be sent on to the

line. The voltage gain from DTMF to LN is typically 25.5 dB (when

R7=68k : ) and varies with R7 in the same way as the microphone

gain. The signalling tones can be heard in the earpiece at a low level

(confidence tone).

Receiving amplifier IR, QR and GAR

The receiving amplifier has one input (IR) and a non-inverting output

(QR). The IR to QR gain is typically 31dB (when R4 = 100k : ). It

can be adjusted between 20 and 31dB to match the sensitivity of the

transducer in use. The gain is set with the value of R4 which is

connected between GAR and QR. The overall receive gain, between

LN and QR, is calculated by subtracting the anti-sidetone network

attenuation (32dB) from the amplifier gain. Two external capacitors,

C4 and C7, ensure stability. C4 is normally 100pF and C7 is 10 times

the value of C4. The value of C4 may be increased to obtain a first-

order low-pass filter. The cut-off frequency will depend on the time

constant R4 x C4.

The output voltage of the receiving amplifier is specified for

continuous-wave drive. The maximum output voltage will be higher

under speech conditions where the peak to RMS ratio is higher.

Automatic gain control input AGC

). This resistor when connected

KKA1062/1062A

BT1062A Kodenshi Korea Corp., BT1062A Datasheet - Page 3

BT1062A

Related parts for BT1062A