SI3210DCQ1-EVB Silicon Laboratories Inc, SI3210DCQ1-EVB Datasheet - Page 41

SI3210DCQ1-EVB

Manufacturer Part Number

SI3210DCQ1-EVB

Description

DAUGHTERCARD W/SI3201 INTERFACE

Manufacturer

Silicon Laboratories Inc

Series

ProSLIC®r

Type

SLIC/CODECr

Datasheets

1.SI3210DCQX-EVB.pdf (130 pages)

2.SI3210MPPQX-EVB.pdf (146 pages)

Specifications of SI3210DCQ1-EVB

Contents

Evaluation Board and CD-ROM

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

For Use With/related Products

Si3210

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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The pulse metering oscillator has a volume envelope

(linear ramp) on the on/off transitions of the oscillator.

The volume value is incremented by the value in the

PLSD register (indirect Register 23) at an 8 kHz rate.

The sinusoidal generator output is multiplied by this

volume before being sent to the DAC. The volume will

ramp from 0 to 7FFF in increments of PLSD so the

value of PLSD will set the slope of the ramp. When the

pulse metering signal is turned off, the volume will ramp

to 0 by decrementing according to the value of PLSD.

Pulse Metering Inactive Timer

Note: The ProSLIC uses registers that are both directly and indirectly mapped. A “direct” register is one that is mapped

Pulse Metering Attack/Decay

Pulse Metering Active Timer

Pulse Metering Frequency

Pulse Metering Amplitude

Figure 24. Pulse Metering Volume Envelope

Pulse Metering Control

Pulse Metering Oscillator

8 Khz

directly. An “indirect” register is one that is accessed using the indirect access registers (direct registers 28

through 31).

Ramp Rate

Parameter

Coefficient

Volum e

Clip to 7FFF or 0

Table 33. Associated Pulse Metering Generator Registers

+/–

Status and control registers

0 to PLSX (full amplitude)

Sets oscillator frequency

Sets oscillator amplitude

Description / Range

0 to 8 seconds

To DAC

PLSD

Rev. 1.42

2.6. DTMF Detection

The dual-tone multi-frequency (DTMF) tone signaling

standard is also known as touch tone. It is an in-band

signaling system used to replace the pulse-dial

signaling standard. In DTMF, two tones are used to

generate a DTMF digit. One tone is chosen from four

possible row tones, and one tone is chosen from four

possible column tones. The sum of these tones

constitutes one of 16 possible DTMF digits.

2.6.1. DTMF Detection Architecture

DTMF detection is performed using a modified Goertzel

algorithm to compute the dual frequency tone (DFT) for

each of the eight DTMF frequencies as well as their

second harmonics. At the end of the DFT computation,

the squared magnitudes of the DFT results for the eight

DTMF fundamental tones are computed. The row

results are sorted to determine the strongest row

frequency; the column frequencies are sorted as well.

At the completion of this process, a number of checks

are made to determine whether the strongest row and

column tones constitute a DTMF digit.

The detection process is performed twice within the

45 ms minimum tone time. A digit must be detected on

two consecutive tests following a pause to be

recognized as a new digit. If all tests pass, an interrupt

is generated, and the DTMF digit value is loaded into

the DTMF register. If tones are occurring at the

maximum rate of 100 ms per digit, the interrupt must be

serviced within 85 ms so that the current digit is not

PSTAT, PMAE,

PLSCO[15:0]

PMIE, PMOE

PLSX[15:0]

PLSD[15:0]

PAT[15:0]

PIT[15:0]

Si3210/Si3211

Direct Registers 44 & 45

Direct Register 46 & 47

Indirect Register 25

Indirect Register 24

Indirect Register 23

Direct Register 35

Location

SI3210DCQ1-EVB Silicon Laboratories Inc, SI3210DCQ1-EVB Datasheet - Page 41

SI3210DCQ1-EVB

Specifications of SI3210DCQ1-EVB

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