SI3225-G-GQ Silicon Laboratories Inc, SI3225-G-GQ Datasheet - Page 52

SI3225-G-GQ

Manufacturer Part Number

SI3225-G-GQ

Description

IC PROSLIC/CODEC DUAL 64TQFP

Manufacturer

Silicon Laboratories Inc

Series

ProSLIC®r

Datasheet

1.SI3200-G-FSR.pdf (112 pages)

Specifications of SI3225-G-GQ

Function

Subscriber Line Interface Concept (SLIC), CODEC

Interface

GCI, PCM, SPI

Number Of Circuits

Voltage - Supply

3.3V, 5V

Current - Supply

65mA

Power (watts)

941mW

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

64-TQFP, 64-VQFP

Includes

Battery Switching, BORSCHT Functions, DTMF Generation and Decoding, FSK Tone Generation, Modem and Fax Tone Detection

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Part Number:

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Manufacturer:

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BOSTOCK HK LIMITED

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Si3220/25 Si3200/02

3.12.1. Internal Sinusoidal Ringing

A sinusoidal ringing waveform is generated by the on-

chip digital tone generator. The tone generator used to

generate ringing tones is a two-pole resonator with a

programmable frequency and amplitude. Since ringing

frequencies are low compared to the audio band

signaling frequencies, the sinusoid is generated at a

1 kHz rate. The ringing generator is programmed via the

RINGFREQ, RINGAMP, and RINGPHAS registers. The

equations are as follows:

For example, to generate a 60 V

ringing signal, the equations are as follows:

In addition to the variable frequency and amplitude, a

selectable dc offset (V

waveform, is included. The dc offset is defined in the

RINGOF RAM location.

As with the tone generators, the ringing generator has

two timers which function as described above. They

allow on/off cadence settings up to 8 s on/8 s off. In

addition to controlling ringing cadence, these timers

control the transition into and out of the ringing state.

To initiate ringing, the user must program the

RINGFREQ,

addresses as well as the RINGTA and RINGTI registers

and select the ringing waveshape and dc offset. After

this is done, TAEN and TIEN bits are set as desired.

The ringing state is invoked by a write to the linefeed

ProSLIC

the on-hook transmission state. At the expiration of

RINGTI, ringing is initiated again. This process

continues as long as the two timers are enabled and the

linefeed register remains in the ringing state.

RINGAMP

RINGFREQ

0x7EFD9D

turns off the ringing waveform and goes to

coeff

-- -

coeff

RINGFREQ = coeff

RINGAMP,

-------------------- -

1.99211

00789

-- - 1 coeff

RINGPHAS

0.9921

cos

----------------------- -

OFF

cos

–

⎛

⎝

coeff

-------------------- -

1000Hz

), which can be added to the

⎛

⎝

(

2π20

-------------------- -

1000Hz

(

and

2πf

)

(

⎞

⎠

)

-------------------- -

160.173

⎞

⎠

rms

)

RINGPHAS

0.9921

8322461

DesiredV

---------------------------------

(87 V

160.173V

273

), 20 Hz

0x111

RAM

Rev. 1.3

3.12.2. Internal Trapezoidal Ringing

waveform, the Dual ProSLIC can generate a trapezoidal

ringing waveform similar to the one illustrated in

Figure 26.

RINGPHAS RAM addresses are used for programming

the ringing wave shape as follows:

RINGPHAS = 4 x Period x 8000

RINGAMP = (Desired V/160.8 V) x (2

RINGFREQ = (2 x RINGAMP)/(t

RINGFREQ is a value that is added or subtracted from

the waveform to ramp the signal up or down in a linear

fashion. This value is a function of rise time, period, and

amplitude, where rise time and period are related

through the following equation for the crest factor of a

trapezoidal waveform.

where

So, for a 90 V

crest factor of 1.3, the period is 0.05 s, and the rise time

requirement is 0.015 s.

RINGPHAS = 4 x 0.05 x 8000 = 1600 (0x0640)

RINGAMP = 90/160.8 x (2

RINGFREQ = (2 x RINGAMP)/(0.0153 x 8000) = 300

(0x012C)

The time registers and interrupts described in the

sinusoidal ring description also apply to the trapezoidal

ring waveform:

3.13. Internal Unbalanced Ringing

The Si3220 also provides the ability to generate a

traditional battery-backed unbalanced ringing waveform

for ringing terminating devices that require a high dc

content or for use in ground-start systems that cannot

tolerate a ringing waveform on both the TIP and RING

leads. The unbalanced ringing scheme applies the

ringing signal to the RING lead; the TIP lead remains at

the programmed VCM voltage that is very close to

ground. A programmable dc offset can be preset to

provide dc current for ring trip detection. Figure 25

illustrates the internal unbalanced ringing waveform.

addition

The

, 20 Hz trapezoidal waveform with a

RISE

the

Period

desired crest factor

RINGFREQ,

traditional

-- - T 1

) = 18340 (0x47A5)

⎛

⎝

------------- -

RING

–

RISE

---------- -

sinusoidal

⎞

⎠

x 8000)

RINGAMP,

)

ringing

and

SI3225-G-GQ Silicon Laboratories Inc, SI3225-G-GQ Datasheet - Page 52

SI3225-G-GQ

Specifications of SI3225-G-GQ

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