HC5515 Datasheet, PDF(10/17 Page) Intersil Corporation – ITU CO/PABX SLIC with Low Power Standby

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HC5515 Datasheet, PDF (10/17 Pages) Intersil Corporation – ITU CO/PABX SLIC with Low Power Standby

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HC5515

TIP

VTR

ZTR

VTX

RING RF

HC5515

A = 250

A=4

VTX

RSN

1000

ZRX

VRX

FIGURE 15. SIMPLIFIED AC TRANSMISSION CIRCUIT

For applications where the 2-wire impedance (ZTR,

Equation 15) is chosen to equal the line impedance (ZL), the

expression for A4-2 simpliï¬es to:

A4 â 2 = âZ---Z-R---T--X- â¢ 12--

(EQ. 19)

(AC) 4-Wire to 4-Wire Gain

The 4-wire to 4-wire gain is equal to VTX/VRX.

From Equations 9, 10 and 11 with EG = 0:

A4 â 4 = V-V----RT----XX-- = âZ---Z-R---T--X-- â¢ -1-------Z0------0--T-----Z-0----L--+---+--2---2R----R-F---F--+-----Z---L--

(EQ. 20)

Transhybrid Circuit

The purpose of the transhybrid circuit is to remove the

receive signal (VRX) from the transmit signal (VTX), thereby

preventing an echo on the transmit side. This is

accomplished by using an external op amp (usually part of

the CODEC) and by the inversion of the signal from the

4-wire receive port (RSN) to the 4-wire transmit port (VTX).

Figure 16 shows the transhybrid circuit. The input signal will

be subtracted from the output signal if I1 equals I2. Node

analysis yields the following equation:

R-V----TT----XX-- + -V--Z--R--B--X-- = 0

(EQ. 21)

The value of ZB is then:

âRTX

â¢

V-----R----X--

VTX

(EQ. 22)

Where VRX/VTX equals 1/ A4-4.

Therefore:

ZB = RTX â¢ Z---Z-R---T--X- â¢ -1-------Z0------0--T-----Z-0----L--+---+--2---2R----R-F---F--+-----Z---L--

(EQ. 23)

Example:

Given: RTX = 20kâ¦, ZRX = 280kâ¦, ZT = 562kâ¦ (standard

value), RF = 20â¦ and Z = 600â¦,

The value of ZB = 18.7kâ¦

RFB

VTX

RTX

HC5515

VTX

VRX

RSN

ZRX

CODEC/

FILTER

FIGURE 16. TRANSHYBRID CIRCUIT

Supervisory Functions

The loop current and the ring trip detector outputs are

multiplexed to a single logic output pin called DET. See Table

1 to determine the active detector for a given logic input. For

further discussion of the logic circuitry see section titled

âDigital Logic Inputsâ.

Before proceeding with an explanation of the loop current

detector and the longitudinal impedance, it is important to

understand the difference between a âmetallicâ and

âlongitudinalâ loop currents. Figure 17 illustrates 3 different

types of loop current encountered.

Case 1 illustrates the metallic loop current. The deï¬nition of

a metallic loop current is when equal currents ï¬ow out of tip

and into ring. Loop current is a metallic current.

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