HC5513_03 Datasheet, PDF(9/20 Page) Intersil Corporation – TR909 DLC/FLC SLIC with Low Power Standby

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HC5513_03 Datasheet, PDF (9/20 Pages) Intersil Corporation – TR909 DLC/FLC SLIC with Low Power Standby

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HC5513

gives the relationship between the RSG resistor value and the

programmable saturation guard reference voltage:

VSGREF

12.5 + -5----â¢-----1---0----5-

RSG

(EQ. 3)

where:

VSGREF = Saturation Guard reference voltage.

RSG = Saturation Guard programming resistor.

When the Saturation guard reference voltage is exceeded,

the tip to ring voltage is calculated using Equation 4:

VTR

--------1---6---.--6---6-----+-----5-----â¢----1---0----5----â---R----S----G----------

RL + (RDC1 + RDC2) â 600

where:

(EQ. 4)

VTR = Voltage differential between tip and ring.

RL = Loop resistance.

For on-hook transmission RL = â, Equation 4 reduces to:

VTR

16.66 + -5----â¢-----1---0----5-

RSG

(EQ. 5)

The value of RSG should be calculated to allow maximum

loop length operation. This requires that the saturation guard

reference voltage be set as high as possible without clipping

the incoming or outgoing VF signal. A voltage margin of -4V

on tip and -4V on ring, for a total of -8V margin, is

recommended as a general guideline. The value of RSG is

calculated using Equation 6:

RSG=

----------------------------------------------------------------5-----â¢----1----0---5-----------------------------------------------------------------

(

VBAT

ï£«

VMARGIN

)

ï£¬

ï£

(---R-----D----C----1----+-----R-----D----C----2----)ï£·ï£¶

600RL ï£¸

â 16.66V

(EQ.

where:

VBAT = Battery voltage.

VMARGIN = Recommended value of -8V to allow a maximum

overload level of 3.1VPEAK.

For on-hook transmission, RL = â, Equation 6 reduces to:

RSG

------------------------------5----â¢-----1---0----5------------------------------

VBAT â VMARGIN â 16.66V

(EQ. 7)

SLIC in the Standby Mode

Overall system power is saved by configuring the SLIC in the

standby state when not in use. In the standby state the tip and

ring amplifiers are disabled and internal resistors are connected

between tip to ground and ring to VBAT. This connection

enables a loop current to flow when the phone goes off-hook.

The loop current detector then detects this current and the SLIC

is configured in the active mode for voice transmission. The

loop current in standby state is calculated as follows:

--V----B----A----T------â-----3----V--

RL + 1800â¦

(EQ. 8)

where:

IL = Loop current in the standby state.

RL = Loop resistance.

VBAT = Battery voltage.

(AC) Transmission Path

SLIC in the Active Mode

Figure 16 shows a simplified AC transmission model. Circuit

analysis yields the following design equations:

VTR = VTX + IM â¢ 2RF

(EQ. 9)

-V----T---X-- + -V----R----X-- = ----I--M------

ZT ZRX 1000

VTR = EG â IM â¢ ZL

(EQ. 10)

(EQ. 11)

where:

VTR = Is the AC metallic voltage between tip and ring,

including the voltage drop across the fuse resistors RF.

VTX = Is the AC metallic voltage. Either at the ground

referenced 4-wire side or the SLIC tip and ring terminals.

IM = Is the AC metallic current.

RF = Is a fuse resistor.

ZT = Is used to set the SLICâs 2-wire impedance.

VRX = Is the analog ground referenced receive signal.

ZRX = Is used to set the 4-wire to 2-wire gain.

EG = Is the AC open circuit voltage.

ZL = Is the line impedance.

(AC) 2-Wire Impedance

The AC 2-wire impedance (ZTR) is the impedance looking

into the SLIC, including the fuse resistors, and is calculated

as follows:

Let VRX = 0. Then from Equation 10

VTX

â¢

----I--M------

1000

(EQ. 12)

ZTR is defined as:

V-----T---R---

(EQ. 13

Substituting in Equation 9 for VTR

ZTR

V-----T---X-- + 2----R-----F-----â¢----I--M---

(EQ. 14)

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