SI3220-FQ Silicon Laboratories Inc, SI3220-FQ Datasheet - Page 37

SI3220-FQ

Manufacturer Part Number

SI3220-FQ

Description

IC SLIC/CODEC DUAL-CH 64TQFP

Manufacturer

Silicon Laboratories Inc

Series

ProSLIC®r

Datasheets

1.SI3200-GS.pdf (108 pages)

2.SI3220PPT0-EVB.pdf (112 pages)

Specifications of SI3220-FQ

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

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

Includes

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

Product

Telecom

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Transistor Power Equations

(Using Discrete Transistors)

When using the Si3220 or Si3225 along with discrete

bipolar transistors, it is possible to control the total

power of the solution by individually regulating the

power in each discrete transistor. Figure 18 illustrates

the basic transistor-based linefeed circuit for one

channel. The power dissipation of each external

transistor is estimated based on the A/D sample values.

The approximate power equations for each external

BJT are as follows:

The maximum power threshold for each device is

software-programmable and should be set based on the

characteristics of the transistor package, PCB design,

and available airflow. If the peak power exceeds the

programmed threshold for any device, the power-alarm

bit is set for that device. Each external bipolar has its

own register bit (PQ1S–PQ6S bits of the IRQVEC3

comparator output and remains high until the user

clears it. Each transistor power alarm bit is also

maskable by setting the PQ1E–PQ6E bits in the

IRQEN3 register.

Si3200 Power Calculation

When using the Si3200, it is also possible to detect the

thermal conditions of the linefeed circuit by calculating

the total power dissipated within the Si3200. This case

is similar to the transistor power equations case, with

the exception that the total power from all transistor

devices is dissipated within the same package

enclosure, and the total power result is placed in the

PSUM RAM location. The power calculation is derived

using the following set of equations:

PSUM = total dissipated power = P

Note: The Si3200 THERM pin must be connected to the

≅ V

≅ (|V

+ P

THERM a/b pin of the Si3220/Si3225 in order for the

Si3200 power calculation method to work correctly.

CE1

CE2

CE3

CE4

CE5

CE6

TIP

RING

BAT

+ P

x I

| + 0.75 V) x I

| – |V

|+ 0.75 V) x I

| + 0.75 V) x I

≅ (|V

RING

TIP

|) x I

TIP

RING

BAT

|) x I

| + 0.75 V) x (I

| – R7 x I

| – R6 x I

| – |V

| + 0.75 V) x (I

RING

TIP

| – R6 x I

| – R7 x I

) x (I

+ P

)

) x (I

+ P

)

Rev. 1.0

)

Power Filter and Alarms

The power calculated during each A/D sample period

must be filtered before being compared to a user-

programmable maximum power threshold. A simple

digital low-pass filter is used to approximate the

transient thermal behavior of the package, with the

output of the filter representing the effective peak power

within the package or, equivalently, the peak junction

temperature.

For Q1, Q2, Q3, and Q4 in SOT23 and Q5 and Q6 in

SOT223 packages, the settings for thermal low-pass

filter poles and power threshold settings are (for an

ambient temperature of 70 °C) calculated as follows: If

the thermal time constant of the package is τ

decimal values of RAM locations PLPF12, PLPF34, and

PLPF56 are given by rounding to the next integer the

value given by the following equation:

Where 4096 is the maximum value of the 12-bit plus

sign RAM locations PLPF12, PLPF34, and PLPF56,

and 800 is the power calculation clock rate in Hz. The

equation is an excellent approximation of the exact

equation for τ

above equations in mind, example values of the RAM

locations, PTH12, PTH34, PTH56, PLPF12, PLPF34,

and PLPF56 are as follows:

PTH12 = power threshold for Q1, Q2 = 0.3 W (0x25A)

PTH34 = power

(0x1B5E)

PTH56 = power threshold for Q5, Q6 = 1 W (0x7D8)

PLPF12 = Q1/Q2 thermal LPF pole = 0x0012

(for SOT–89 package)

PLPF34 = Q3/Q4 thermal LPF pole = 0x008C

(for SOT–23 package)

PLPF56 = Q5/Q6 thermal LPF pole = 0x000E

(for SOT–223 package)

In the case where the Si3200 is used, thermal filtering

needs to be performed only on the total power reflected

in the PSUM RAM location. When the filter output

exceeds the total power threshold, an interrupt is

issued. The PTH12 RAM location is used to preset the

total power threshold for the Si3200, and the PLPF12

RAM location is used to preset the thermal low-pass

filter pole.

PLPFxx (decimal value)

thermal

threshold

= 1.25 ms … 5.12 s. With the

Si3220/Si3225

for

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

800

4096

Q3,

thermal

Q4 = 0.22 W

thermal

, the

SI3220-FQ Silicon Laboratories Inc, SI3220-FQ Datasheet - Page 37

SI3220-FQ

Specifications of SI3220-FQ

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