SI3056SSI1-EVB Silicon Laboratories Inc, SI3056SSI1-EVB Datasheet - Page 36

SI3056SSI1-EVB

Manufacturer Part Number

SI3056SSI1-EVB

Description

BOARD EVAL SI3056/SI3019 SSI

Manufacturer

Silicon Laboratories Inc

Datasheets

1.SI3056-D-FS.pdf (94 pages)

2.SI3056SSI1-EVB.pdf (110 pages)

Specifications of SI3056SSI1-EVB

Main Purpose

Telecom, Data Acquisition Arrangement (DAA)

Utilized Ic / Part

Si3056

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Secondary Attributes

Embedded

Primary Attributes

Lead Free Status / Rohs Status

Supplier Unconfirmed

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Si3018/19/10

5.24. Filter Selection

The Si3056 supports additional filter selections for the

receive and transmit signals as defined in Table 11 and

Table 12 on page 15. The IIRE bit (Register 16, bit 4)

selects between the IIR and FIR filters. The IIR filter

provides a shorter, but non-linear, group delay

alternative to the default FIR filter and only operates

with an 8 kHz sample rate. Also, on the Si3019 line-side

device, the FILT bit (Register 31, bit 1) selects a –3 dB

low frequency pole of 5 Hz when cleared and 200 Hz

when set. The FILT bit affects the receive path only.

5.25. Clock Generation

The Si3056 has an on-chip clock generator. Using a

single MCLK input frequency, the Si3056 generates all

the desired standard modem sample rates.

The clock generator consists of two phase-locked loops

(PLL1 and PLL2) that achieve the desired sample

frequencies. Figure 26 illustrates the clock generator.

The architecture of the dual PLL scheme provides fast

lock time on initial start-up, fast lock time when

changing modem sample rates, high noise immunity,

and can change modem sample rates with a single

1 and 60 MHz are supported. MCLK should be from a

clean source, preferably directly from a crystal with a

constant frequency and no dropped pulses.

In serial mode 2 (refer to the “5.26.Digital Interface”

section), the Si3056 operates as a slave device. The

clock generator is configured based on the SRC register

to generate the required internal clock frequencies. In

this mode, PLL2 is powered-down. For further details of

slave mode operation, see "5.27.Multiple Device

Support" on page 38.

5.25.1. Programming the Clock Generator

As shown in Figure 26, PLL1 must output a clock equal

to 98.304 MHz (F

programming the following registers:

The main design consideration is the generation of a

base frequency, defined as follows:

F BASE

BASE

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

MCLK

). The F

BASE

98.304 MHz

is determined by

Rev. 1.05

N (Register 8) and M (Register 9) are 8-bit unsigned

values. F

the MCLK pin.

Table 20 lists several standard crystal oscillator rates

that can be supplied to MCLK. This list represents a

sample of MCLK frequency choices. Many others are

possible.

After PLL1 is programmed, the SRC[3:0] bits can

achieve the standard modem sampling rates with a

single write to Register 7. See "Register 7.Sample Rate

Control" on page 54.

When programming the registers of the clock generator,

the order of register writes is important. For PLL1

updates, N (Register 8, bits 7:0) must be written first,

then immediately followed by a write to M (Register 9,

bits 7:0).

The values shown in Table 20 satisfy the preceding

equation. However, when programming the registers for

N and M, the value placed in these registers must be

one less than the value calculated from the equations.

For example, with an MCLK of 46.08 MHz, the values

placed in the N and M registers are 0x0Dh and 0x1Fh,

respectively.

MCLK

MCLK (MHz)

10.3680

11.0592

14.7456

18.4320

24.5760

25.8048

44.2368

46.0800

47.9232

56.0000

Table 20. MCLK Examples

1.8432

4.0960

6.1440

8.1920

9.2160

12.288

is the frequency of the clock provided to

160

256

SI3056SSI1-EVB Silicon Laboratories Inc, SI3056SSI1-EVB Datasheet - Page 36

SI3056SSI1-EVB

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