SI3010-KS Datasheet, PDF(32/94 Page) List of Unclassifed Manufacturers – GLOBAL SERIAL INTERFACE DIRECT ACCESS ARRANGEMENT

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SI3010-KS Datasheet, PDF (32/94 Pages) List of Unclassifed Manufacturers – GLOBAL SERIAL INTERFACE DIRECT ACCESS ARRANGEMENT

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Si3056

Si3018/19/10

TIP

From

Line

RING

L2 To

DAA

Figure 22. Billing Tone Filter

L1 must carry the entire loop current. The series

resistance of the inductors is important to achieve a

narrow and deep notch. This design has more than

25 dB of attenuation at both 12 kHz and 16 kHz.

Table 19. Component ValuesâOptional Billing

Tone Filters

Symbol

C1,C2

Value

0.027 ÂµF, 50 V, Â±10%

0.01 ÂµF, 250 V, Â±10%

3.3 mH, >120 mA, <10 â¦, Â±10%

10 mH, >40 mA, <10 â¦, Â±10%

The billing tone filter affects the ac termination and

return loss. The global complex ac termination

(ACIM = 1111) passes global return loss specifications

with and without the billing tone filter by at least 3 dB.

5.20. On-Hook Line Monitor

The on-hook line monitor mode allows the Si3056 to

receive line activity when in an on-hook state. A low-

power ADC located on the line-side device digitizes the

signal passed across the RNG1/2 pins and then sends

the signal digitally across the communications link to the

host. This mode is typically used to detect caller ID data

and is enabled by setting the ONHM bit (Register 5,

bit 3). Caller ID data can be gained up or attenuated

using the receive gain control bits in registers 39 and

41.

5.21. Caller ID

The Si3056 can pass caller ID data from the phone line

to a caller ID decoder connected to the serial port.

5.21.1. Type I Caller ID

Type I Caller ID sends the CID data while the phone is

on-hook.

In systems where the caller ID data is passed on the

phone line between the first and second rings, utilize the

following method to capture the caller ID data:

1. After identifying a ring signal using one of the

methods described in "5.14.Ring Detection" on page

29, determine when the first ring is complete.

2. Assert the ONHM bit (Register 5, bit 3) to enable

caller ID data detection. The caller ID data passed

across the RNG 1/2 pins is presented to the host via

the SDO pin.

3. Clear the ONHM bit after the caller ID data is

received.

In systems where the caller ID data is preceded by a

line polarity (battery) reversal, use the following method

to capture the caller ID data:

1. Enable full wave rectified ring detection (RFWE,

2. Monitor the RDTP and RDTN register bits (or the

POLI bit) to identify whether a polarity reversal or

ring signal has occurred. A polarity reversal trips

either the RDTP or RDTN ring detection bits, and

thus the full-wave ring detector must be used to

distinguish a polarity reversal from a ring. The lowest

specified ring frequency is 15 Hz; therefore, if a

battery reversal occurs, the DSP should wait a

minimum of 40 ms to verify that the event observed

is a battery reversal and not a ring signal. This time

is greater than half the period of the longest ring

signal. If another edge is detected during this 40 ms

pause, this event is characterized as a ring signal

and not a battery reversal.

3. Assert the ONHM bit (Register 5, bit 3) to enable the

caller ID data detection. The caller ID data passed

across the RNG 1/2 pins is presented to the host via

the SDO pin.

4. Clear the ONHM bit after the caller ID data is

received.

5.21.2. Type II Caller ID

Type II Caller ID sends the CID data while the phone is

off-hook and is often referred to as caller ID/call waiting

(CID/CW). To receive the CID data while off-hook, use

the following procedure (see Figure 23):

1. The Caller Alert Signal (CAS) tone is sent from the

Central Office (CO) and is digitized along with the

Rev. 1.05

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