PCM4201PWT [TI]

IC 1-CH 24-BIT DELTA-SIGMA ADC, SERIAL ACCESS, PDSO16, PLASTIC, TSSOP-16, Analog to Digital Converter;


型号：	PCM4201PWT
厂家：	TEXAS INSTRUMENTS
描述：	IC 1-CH 24-BIT DELTA-SIGMA ADC, SERIAL ACCESS, PDSO16, PLASTIC, TSSOP-16, Analog to Digital Converter 光电二极管转换器
文件：	总25页 (文件大小：620K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

Low Power, 24-Bit, Single Channel Audio

Analog-to-Digital Converter

FEATURES

APPLICATIONS

High Performance Delta-Sigma

Analog-to-Digital Converter

Differential Voltage Inputs

Dynamic Performance:

− Dynamic Range (A-Weighted): Up to

112dB

Digital Wireless Microphones

Battery-Powered Audio Recording and

Processing Equipment

DESCRIPTION

The PCM4201 is designed for digital audio applications

that require a combination of high dynamic range, low

distortion, and low power consumption. The primary

applications for the PCM4201 include digital wireless

microphones and battery-operated audio recording or

processing equipment. The PCM4201 outputs 24-bit

linear PCM audio data at sampling rates up to 108kHz.

Three sampling modes allow the user to trade off power for

performance, dependent upon the intended system

requirements. An on-chip voltage reference reduces the

number of external components needed for operation.

− THD+N: As low as −105dB

Three Sampling Modes:

− Supports Output Sampling Rates Up to

108kHz

− Choose from Low Power, High

Performance, or Double Speed Modes

Audio Serial Port Interface:

− Master or Slave Mode Operation

− 24-Bit Linear PCM Output Data

− Left-Justified/DSP-Compatible Data

Format

Digital High-Pass Filter for DC Removal:

− Includes a High-Pass Filter Disable Pin

Power Supplies:

The PCM4201 includes dedicated control pins for

configuration of all programmable functions. The device

requires a +5.0V analog power supply, in addition to a

digital supply operating from +1.8V to +3.3V. The

PCM4201 is available in a small TSSOP-16 package.

− Requires a +5V Analog Power Supply

− Supports a +1.8V to +3.3V Digital Power

Supply Range

Low Power Dissipation

− 49mW Typical (Low Power Mode with

= +3.3V)

− 39mW Typical (Low Power Mode with

= +1.8V)

Power Down Mode

− Less than 50µW total power dissipation

Available in a small TSSOP-16 Package

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments

semiconductor products and disclaimers thereto appears at the end of this data sheet.

I S is a registered trademark of Royal Philips Electronics B.V., The Netherlands. All other trademarks are the property of their respective owners.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate

precautions. Failure to observe proper handling and installation procedures can cause damage.

ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to

damage because very small parametric changes could cause the device not to meet its published specifications.

ABSOLUTE MAXIMUM RATINGS

over operating free-air temperature range unless otherwise noted

(1)

PCM4201

+6.0

UNIT

Supply voltage

+3.6

Ground voltage differences

Digital input voltage

AGND to DGND

RATE, S/M, RST, HPFD SCKI, BCK, FSYNC

+, V

0.1

−0.3 to (V

+ 0.3)

Analog input voltage

−

−0.3 to (V

+ 0.3)

IN IN

Input current (any pin except supplies)

Operating temperature range

10mA

°C

−10 to +70

Storage temperature range, T

STG

−65 to +150

(1)

Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. Exposure to absolute maximum

conditions for extended periods may degrade device reliability. These are stress ratings only, and functional operation of the device at these or

any other conditions beyond those specified is not implied.

PACKAGE/ORDERING INFORMATION

For the most current package and ordering information, see the Package Option Addendum located at the end of this

datasheet, or see the TI website at www.ti.com.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

ELECTRICAL CHARACTERISTICS

Unless otherwise specified, all characteristics are measured with T = +25°C, V

= +5V, and V

CC DD

= +3.3V. System clock frequency is set to

24.576 MHz. Device is operated in Slave mode.

PCM4201

PARAMETER

CONDITIONS

MIN

TYP

MAX

UNITS

RESOLUTION

Bits

AUDIO DATA FORMAT

Format

Two’s complement, MSB first data

Left-Justified / DSP Compatible

Word length

Bits

DIGITAL I/O

0.7 x V

Input logic level

Output logic level

Input current

0.3 x V

= −2mA

= +2mA

0.8 x V

0.2 x V

+10

= V

µA

= 0V

−10

= V

+25

(1)

Input current

= 0V

−25

DIGITAL SWITCHING

Normal speed, low power

Normal speed, high performance

Double speed

kHz

Output sampling frequency

108

System clock duty cycle

System clock frequency

AUDIO SERIAL-PORT TIMING

Delay from FSYNC rising to BCK rising

Delay from BCK rising to FSYNC rising

BCK high pulse width

BCK low pulse width

2.048

27.65

MHz

DBK

DLK

BCKH

BCKL

Data setup time

Data hold time

ANALOG INPUTS

Input voltage, full-scale range (FSR)

Input impedance

Differential input

5.0

Per analog input pin

kΩ

Common-mode rejection

DC PERFORMANCE

Output offset error

100

High-pass filter disabled

% of FSR

Gain error

(1)

(2)

Applies to RATE (pin 5) and S/M (pin 6) inputs.

All typical dynamic performance specifications were measured using an Audio Precision System Two Cascade or Cascade Plus test system and a PCM4201EVM

evaluation module. For Normal Speed operation, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and 20kHz low-pass filter.

For Double Speed mode, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and a user-defined 40kHz low-pass filter (the

f /2 low pass filter may be utilized with similar results). All A-weighted measurements are made using the Audio Precision A-weighting filter in combination with

the filters previously noted here. Minimum and maximum dynamic performance limits are based upon the capability of the production test solution.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

ELECTRICAL CHARACTERISTICS (continued)

Unless otherwise specified, all characteristics are measured with T = +25°C, V

= +5V, and V

CC DD

= +3.3V. System clock frequency is set to

24.576 MHz. Device is operated in Slave mode.

PCM4201

PARAMETER

(2)

CONDITIONS

MIN

104

105

TYP

MAX

UNITS

DYNAMIC PERFORMANCE

with V

= +5V and V = +1.8V

Normal Speed, Low Power, f = 48kHz, BW = 22Hz to 20kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−103

109

−100

= −60dB, f = 1kHz, A-weighted

Dynamic range, no weighting

= −60dB, f = 1kHz

106

Normal Speed, High Performance, f = 48kHz, BW = 22Hz to 20kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−105

112

−100

= −60dB, f = 1kHz, A-weighted

Dynamic range, no weighting

= −60dB, f = 1kHz

110

Double Speed, f = 96kHz, BW = 22Hz to 40kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−103

112

= −60dB, f = 1kHz, A-weighted

Dynamic range, no weighting

= −60dB, f = 1kHz

106

= +3.3V

(2)

DYNAMIC PERFORMANCE

with V

= +5V and V

Normal Speed, Low Power, f = 48kHz, BW = 22Hz to 20kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−102

106

−100

= −60dB, f = 1kHz, A-weighted

104

105

Dynamic range, no weighting

= −60dB, f = 1kHz

104

Normal Speed, High Performance, f = 48kHz, BW = 22Hz to 20kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−105

112

= −60dB, f = 1kHz, A-weighted

Dynamic range, no weighting

= −60dB, f = 1kHz

109

Double Speed, f = 96kHz, BW = 22Hz to 40kHz

Total harmonic distortion + noise

Dynamic range

THD+N

= −0.5dB, f = 1kHz

−103

111

= −60dB, f = 1kHz, A-weighted

Dynamic range, no weighting

DIGITAL DECIMATION FILTER

Passband edge

= −60dB, f = 1kHz

106

0.453f

sec

Passband ripple

0.005

Stop band edge

0.547f

Stop band attenuation

Group delay

−100

37/f

(1)

(2)

Applies to RATE (pin 5) and S/M (pin 6) inputs.

All typical dynamic performance specifications were measured using an Audio Precision System Two Cascade or Cascade Plus test system and a PCM4201EVM

evaluation module. For Normal Speed operation, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and 20kHz low-pass filter.

For Double Speed mode, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and a user-defined 40kHz low-pass filter (the

f /2 low pass filter may be utilized with similar results). All A-weighted measurements are made using the Audio Precision A-weighting filter in combination with

the filters previously noted here. Minimum and maximum dynamic performance limits are based upon the capability of the production test solution.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

ELECTRICAL CHARACTERISTICS (continued)

Unless otherwise specified, all characteristics are measured with T = +25°C, V

= +5V, and V

CC DD

= +3.3V. System clock frequency is set to

24.576 MHz. Device is operated in Slave mode.

PCM4201

PARAMETER

DIGITAL HIGH PASS FILTER

Frequency response (−3dB)

POWER SUPPLY

CONDITIONS

MIN

TYP

MAX

UNITS

f /48000

+4.75

+1.65

+5.0

+3.3

+5.25

+3.6

8.2

Supply voltage range

Normal speed, low power

Normal speed, high performance

Double speed

µA

Operating supply current

with V

= +5V, V = +1.8V

Normal speed, low power

Normal speed, high performance

Double speed

3.2

4.5

6.0

8.2

2.5

3.5

Normal speed, low power

Normal speed, high performance

Double speed

Operating supply current

with V = +5V, V = +3.3V

Normal speed, low power

Normal speed, high performance

Double speed

6.0

8.5

10.5

CC DD

7.5

Power-Down mode current

with V = +5V, V = +1.8V or +3.3V

µA

CC DD

Normal speed, low power

Normal speed, high performance

Double speed

Total power dissipation

with V = +5V, V = +3.3V

103

115

CC DD

Normal speed, low power

Normal speed, high performance

Double speed

Total power dissipation

with V = +5V, V = +1.8V

CC DD

(1)

(2)

Applies to RATE (pin 5) and S/M (pin 6) inputs.

All typical dynamic performance specifications were measured using an Audio Precision System Two Cascade or Cascade Plus test system and a PCM4201EVM

evaluation module. For Normal Speed operation, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and 20kHz low-pass filter.

For Double Speed mode, the measurement bandwidth is limited using the Audio Precision 22Hz high-pass filter and a user-defined 40kHz low-pass filter (the

f /2 low pass filter may be utilized with similar results). All A-weighted measurements are made using the Audio Precision A-weighting filter in combination with

the filters previously noted here. Minimum and maximum dynamic performance limits are based upon the capability of the production test solution.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

PIN ASSIGNMENT

PW PACKAGE

TSSOP-16

(TOP VIEW)

V_IN

16 V_REF

−

V_IN

V_REF

AGND

V_CC

DGND

V_DD

PCM4201

RATE

S/M

12 SCKI

BCK

RST

FSYNC

DATA

HPFD

Terminal Functions

TERMINAL

NAME

PIN NO.

I/O

DESCRIPTION

Input

Noninverting Analog Input

Inverting Analog Input

Analog Ground

−

AGND

Ground

Power

Input

Analog Supply, +5V

RATE

Sampling Mode Configuration (Tri-Level Input): 0 = Double Speed;

1 = Normal Speed, Low Power; Z = Normal Speed, High Performance.

Maximum external capacitive load is 100pF.

S/M

RST

Input

Audio Serial Port Slave/Master Mode (0 = Master, 1 = Slave)

Reset/Power Down (Active Low)

High Pass Filter Disable (Active High)

Audio Serial Port Data

HPFD

DATA

FSYNC

BCK

Input

Output

I/O

Audio Serial Port Frame Synchronization Clock

Audio Serial Port Bit (or Data) Clock

System Clock

I/O

SCKI

Input

(1)

Power

Ground

Output

Digital Supply, +3.3V Typical

DGND

Digital Ground

−

Voltage Reference Low Output, Connect to AGND

Voltage Reference High Output, De-Coupling Only

REF

(2)

REF

(1)

(2)

The V

supply may be operated from +1.8V to +3.6V.

Unbuffered output. Do not use to drive external circuitry.

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

TYPICAL CHARACTERISTICS

At T = 25°C, V

= 1.8V, V = 5.0V, Master Mode, SCKI = 24.576MHz, unless otherwise noted.

HIGH−PERFORMANCE FFT PLOT

−

(f_S= 48kHz, f_IN= 997Hz at 20dB)

(f_S= 48kHz, f_IN= 997Hz at 1dB)

−

100

120

140

160

−

100

120

140

160

100

10k

24k

100

10k

24k

Frequency (Hz)

HIGH−PERFORMANCE FFT PLOT

(f_S= 48kHz, f_IN= 997Hz at 60dB)

LOW−POWER FFT PLOT

−

(f_S= 48kHz, f_IN= 997Hz at 1dB)

−

100

120

140

160

100

120

140

160

100

Frequency (Hz)

LOW−POWER FFT PLOT

−

(f_S= 48kHz, f_IN= 997Hz at 60dB)

(f_S= 48kHz, f_IN= 997Hz at 20dB)

−

100

120

140

160

100

120

140

160

100

Frequency (Hz)

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

TYPICAL CHARACTERISTICS (continued)

At T = 25°C, V

= 1.8V, V = 5.0V, Master Mode, SCKI = 24.576MHz, unless otherwise noted.

DOUBLE−SPEED FFT PLOT

−

(f_S= 96kHz, f_IN= 997Hz at 20dB)

(f_S= 96kHz, f_IN= 997Hz at 1dB)

−

100

120

140

160

100

120

140

160

100

10k

48k

100

10k

48k

Frequency (Hz)

DOUBLE−SPEED FFT PLOT

THD+N vs AMPLITUDE, HIGH PERFORMANCE

(f_S= 48kHz, f_IN= 997Hz, BW = 20Hz to 20kHz)

−

(f_S= 96kHz, f_IN= 997Hz at 60dB)

−

100

102

104

106

108

−

V_DD= 3.3V

−

110

112

114

116

118

120

−

100

120

140

160

V_DD= 1.8V

−

100

10k

120

100

Frequency (Hz)

Amplitude (dB)

THD+N vs AMPLITUDE, LOW POWER

(f_S= 48kHz, f_IN= 997Hz, BW = 20Hz to 20kHz)

THD+N vs AMPLITUDE, DOUBLE SPEED

(f_S= 96kHz, f_IN= 997Hz, BW = 20Hz to 40kHz)

−

100

102

104

106

108

100

102

104

106

108

V_DD= 3.3V

−

V_DD= 3.3V

V_DD= 1.8V

−

V_DD= 1.8V

−

110

112

114

116

118

120

110

112

114

116

118

120

−

120

100

120

100

Amplitude (dB)

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TYPICAL CHARACTERISTICS (continued)

At T = 25°C, V

= 1.8V, V = 5.0V, Master Mode, SCKI = 24.576MHz, unless otherwise noted.

THD+N vs FREQUENCY, HIGH PERFORMANCE

THD+N vs FREQUENCY, LOW POWER

−

(f_S= 48kHz, Input Level = 1dB, BW = 20Hz to 20kHz)

−

90.0

92.5

95.0

97.5

90.0

92.5

95.0

97.5

V_DD= 3.3V

−

100.0

102.5

105.0

107.5

100.0

102.5

105.0

107.5

V_DD= 1.8V

−

110.0

112.5

115.0

117.5

120.0

110.0

112.5

115.0

117.5

120.0

V_DD= 1.8V

−

100

10k 20k

100

10k 20k

Frequency (Hz)

THD+N vs FREQUENCY, DOUBLE SPEED

−

(f_S= 96kHz, Input Level = 1dB, BW = 20Hz to 40kHz)

−

90.0

92.5

95.0

97.5

V_DD= 3.3V

−

100.0

102.5

105.0

107.5

V_DD= 1.8V

110.0

112.5

115.0

117.5

120.0

−

100

10k

40k

Frequency (Hz)

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PRODUCT OVERVIEW

The PCM4202 is a single channel audio analog-to-digital

converter (ADC) designed for use in low power, battery-

operated or portable professional audio equipment. Target

applications include digital wireless microphones and

portable digital audio recorders/processors. The

PCM4201 features 24-bit linear PCM output data, with a

format compatible with digital signal processors, digital

audio interface transmitters, and programmable logic

devices.

expense of increased power dissipation. The Double

Speed mode supports sampling frequencies up to 108kHz

and is provided for those applications where higher

sampling rates may be required.

A digital high-pass filter is included for DC removal.

Dedicated control pins are included for sampling mode

selection, Slave/Master mode audio serial port operation,

digital high-pass filter enable/disable, and reset/

power-down functions.

The PCM4201 includes three sampling modes, supporting

sampling rates up to 108kHz. The Normal Speed, Low

Power mode supports sampling rates up to 54kHz, and

employs 64x oversampling to reduce overall converter

power. The Normal Speed, High Performance mode

supports sampling rates up to 54kHz with 128x

oversampling, resulting in improved dynamic range and

THD+N when compared to the Low Power mode, at the

A +5V power supply is required for the analog section of

the device, while a +3.3V power supply is typically utilized

for the digital section. The digital supply may be operated

at voltages as low as +1.8V, with a corresponding 10 to 20

milliwatt (mW) reduction in power dissipation, depending

upon the sampling mode selection. Figure 1 shows the

functional block diagram for the PCM4201.

V_INR+

Delta−Sigma

Modulator

Decimation

Filter

HPF

FSYNC

BCK

−

_INR

Audio

Serial

Port

DATA

V_REF

Voltage

Reference

−

V_REF

S/M

HPFD

RATE

Reset

Logic

Clock

Control

Power

SCKI

RST

V_CCAGND

V_DDDGND

Figure 1. PCM4201 Functional Block Diagram

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SCKI (pin 12). The acceptable system clock frequency

and duty cycle range are listed in the Electrical

Characteristics table of this datasheet.

ANALOG INPUTS

The PCM4201 features differential voltage inputs. V +

(pin 1) and V − (pin 2) provide the noninverting and

The PCM4201 supports specific system clock rates, which

are multiples of the desired output sampling frequency.

The supported system clock rate is also dependent upon

the audio serial port mode. Table 1 and Table 2 specify the

system clock rates required for common output sampling

frequencies for both Slave and Master mode audio

serial-port operation.

inverting inputs, respectively. The full-scale input voltage,

measured differentially across these two pins, is

approximately 5.0V

The input impedance is

approximately 15kΩ per input pin.

In applications where the analog inputs can be driven

beyond the analog supply rails of the PCM4201, the input

buffer circuit should incorporate clamping or limiting

circuitry to ensure that the analog inputs are not driven

beyond the absolute maximum input levels for these pins.

Refer to the Absolute Maximum Ratings table of this

datasheet.

Table 1. System Clock Rates for Common Audio

Sampling Frequencies—Slave Mode Operation

SYSTEM CLOCK

FREQUENCY (MHZ)

SAMPLING

FREQUENCY

(kHz)

SAMPLING

MODE

SCKI = 256f_S

SCKI = 512f_S

VOLTAGE REFERENCE

Normal

Double

44.1

88.2

8.192

11.2896

12.288

22.5792

24.576

16.384

22.5792

24.576

N/A

The PCM4201 includes an on-chip band gap reference for

the delta-sigma modulator, eliminating the need for

external reference circuitry. The reference voltage is set to

N/A

+2.5V nominal. The V

+ (pin 16) and V

− (pin 15)

REF

outputs provide connections for reference decoupling

capacitors, which are connected between these two pins.

The V_REF− output is then connected to analog ground.

Figure 2 shows the recommended decoupling capacitor

connections and values.

Table 2. System Clock Rates for Common Audio

Sampling Frequencies—Master Mode Operation

SYSTEM CLOCK

FREQUENCY (MHZ)

SAMPLING

FREQUENCY

(kHz)

SAMPLING

MODE

SCKI = 256f_S

SCKI = 512f_S

Normal

Double

44.1

88.2

N/A

22.5792

24.576

16.384

22.5792

24.576

N/A

PCM4201

V_REF

10 F

0.1 F

N/A

−

V_REF

AGND

SAMPLING MODES

The PCM4201 supports three sampling modes, allowing the

user to select the most appropriate power/performance

Figure 2. Voltage Reference Connections

combination for

paragraphs describe the operation and tradeoffs for the three

sampling modes. For all cases, f is defined as the desired

output sampling rate at the audio serial port interface.

a given application. The following

The voltage reference output is not buffered, and should

not be connected to external circuitry other than the

decoupling capacitors. DC common-mode voltage for the

input buffer circuitry may be set using an external voltage

divider circuit, as shown in the Applications Information

section of this datasheet.

Normal Speed, Low Power mode provides the lowest

overall power dissipation, while supporting sampling rates

up to 54kHz. The modulator oversampling rate is 64f for

this mode, which results in lower dynamic range and

THD+N when compared to Normal Speed, High

Performance mode. For best dynamic performance and

lowest power consumption when using Low Power mode,

it is recommended to operate the PCM4201 from a +1.8V

digital power supply.

SYSTEM CLOCK

The PCM4201 requires an external system clock, which is

used internally to derive the modulator oversampling and

digital subsystem clocks. The system clock is input at

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Normal Speed, High Performance mode provides the best

overall dynamic performance at the expense of increased

power dissipation. Sampling rates up to 54kHz are

Table 3. Sampling Mode Configuration

RATE (PIN 5)

SAMPLING MODE SELECTION

Double Speed

supported. The modulator oversampling rate is 128f for

Normal Speed, Low Power

Normal Speed, High Performance

this mode, improving the overall dynamic range and

THD+N when compared to Low Power mode.

Float or Hi Z

Double Speed mode supports sampling frequencies up to

108kHz with power dissipation that is somewhat higher

than Normal Speed, High Performance mode. The

AUDIO SERIAL PORT

The PCM4201 audio serial port is a 3-wire synchronous

serial interface comprised of the audio serial data output,

DATA (pin 9); a frame synchronization clock, FSYNC (pin

10); and a bit or data clock, BCK (pin 11). The FSYNC and

BCK clocks may be either inputs or outputs, supporting

either Slave or Master mode interfaces, respectively. The

audio data format is 24-bit linear PCM, represented as

two’s complement binary data with the MSB being the first

data bit in the frame. Figure 3 illustrates the audio frame

format, while Figure 4 and the Electrical Characteristics

table highlight the important timing parameters for the

audio serial port interface.

modulator oversampling rate is 64f for this mode.

The sampling mode is selected using the RATE input (pin

5). The RATE pin is a tri-level logic input, with the ability to

detect low, high, and floating (or high-impedance) states.

Table 3 shows the available sampling mode

configurations using the RATE pin. For the floating or

high-impedance case, it is best to drive the RATE pin with

a tri-state buffer, such as the Texas Instruments

SN74LVC1G125 or equivalent. This allows the buffer to be

disabled, setting the output to a high-impedance state.

One Frame ⁽¹⁾⁽²⁾

1/f_S

FSYNC ⁽³⁾

Slave Mode

Frame Format

Data ⁽⁴⁾

DATA

FSYNC ⁽⁵⁾

Master Mode

Frame Format

Data ⁽⁴⁾

DATA

NOTES: (1) One Frame = 128 BCK clock cycles for Normal Speed modes and 64 BCK clock cycles for Double Speed mode.

(2) If BCK = 128f_Swhen Normal Speed, Low Power sampling is enabled, then the frame will begin on the falling edge of the FSYNC clock input.

The FSYNC clock is inverted for this case.

(3) For Slave Mode operation, the FSYNC pulse width high period must be at least one BCK clock cycle in length, while the FSYNC pulse low

period must be at least one BCK clock cycle in length. Best performance is achieved when the FSYNC duty cycle is 50%.

(4) The audio data word length is 24 bits and is Left−Justified in the frame. The audio data is always presented in two’s complement binary format

with the MSB being the first data bit in the frame.

(5) For Master mode operation, the FSYNC clock duty cycle is equal to 50%.

Figure 3. Audio Serial-Port Frame Format

t_DLK

FSYNC

BCK

t_DBK

t_BCKH

t_BCKL

DATA

t_S

t_H

Figure 4. Audio Serial-Port Timing

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Slave mode operation requires that the FSYNC and BCK

clocks be generated from an external audio processor or

master timing generator, as shown in Figure 5. Both clocks

are inputs in Slave mode. The FSYNC clock rate is the

DIGITAL HIGH-PASS FILTER

The PCM4201 includes a digital high-pass filter, which is

located at the output of the digital decimation filter block.

The purpose of the high-pass filter is to remove the DC

component from the digitized signal. The corner, or −3dB

frequency, for the digital high-pass filter is calculated using

the following relationship:

equal to the desired output sampling frequency, f . The

FSYNC high pulse width must be equal to at least one BCK

clock period. The BCK clock rate should be 128f for

Normal Speed, High Performance sampling mode. A BCK

rate equal to 64f results in no output for this sampling

mode. For Normal Speed, Low Power sampling mode, the

f_S

48000

*3dB

(1)

BCK rate may be 64f or 128f . See Note (2) in Figure 3

regarding the FSYNC edge used for start of frame when

BCK = 128f for this sampling mode. For Double Speed

where f = the output sampling frequency.

The digital high-pass filter may be enabled or disabled

using the HPFD input (pin 8). When HPFD is forced low,

the high-pass filter is enabled. Forcing HPFD high

disables the high-pass filter. Distortion for signal

frequencies less than 100Hz may increase slightly when

the high-pass filter is enabled.

sampling mode, the BCK rate should be 64f .

AUDIO DSP

FSR

PCM4201

FSYNC SCKI

BCK

CLKR

RESET OPERATION

DATA

S/M

The PCM4201 includes two reset functions: power-on and

externally controlled. This section describes the operation

of each of these functions.

V_DD

System

Clock

On power up, the internal reset signal is forced low, forcing

the PCM4201 into a reset state. The power-on reset circuit

monitors the V (pin 13) and V (pin 4) power supplies.

Figure 5. PCM4201 Slave Mode Configuration

When the digital supply exceeds 0.6 × V

nominal

400mV, and the V supply exceeds +4.0V 400mV, the

internal reset signal is forced high. The PCM4201 will then

wait for the system clock input (SCKI) to become active.

Once the system clock has been detected, the initialization

sequence begins. The initialization sequence requires

1024 system clock periods for completion. During the

initialization sequence, the ADC output data pin will be

forced low. Once the initialization sequence is completed,

the PCM4201 outputs valid data. Figure 7 shows the

power-on reset sequence timing.

For Master mode operation, the PCM4201 generates the

FSYNC and BCK clocks, deriving them from the system

clock input, SCKI (pin 12), as shown in Figure 6. The

FSYNC clock rate is equal to the output sampling

frequency, f . The FSYNC clock duty cycle is 50% in

Master mode. The BCK clock rate is fixed at 128f for

Normal Speed, High Performance sampling mode. For

Normal Speed, Low Power, and Double Speed sampling

modes, the BCK rate is fixed at 64f .

The user may force a reset initialization sequence at any

time while the system clock input is active by utilizing the

RST input (pin 7). The RST input is active low, and requires

a minimum low pulse width of 40ns. The low-to-high

transition of the applied reset signal will force an

initialization sequence to begin. As in the case of the

power-on reset, the initialization sequence requires 1024

system clock periods for completion. Figure 8 illustrates

the reset sequence initiated when using the RST input.

AUDIO DSP

FSR

PCM4201

FSYNC SCKI

BCK

CLKR

DATA

S/M

DGND

Figure 9 shows the state of the audio data output (DATA)

for the PCM4201 before, during, and after the reset

operations.

System

Clock

Figure 6. PCM4201 Master Mode Configuration

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~ 4.0V

V_CC

0.6 x V_DD

Nominal⁽¹⁾

V_DD

Internal

Reset

1024 System Clock Periods

Required for Initialization

SCKI

System Clock

Indeterminate

or Inactive

(1) V_DDnominal range is +1.8V to +3.6V.

Figure 7. Power-On Reset Sequence

t_RSTL> 40ns

RST

1024 System Clock Periods

Required for Initialization

Internal

Reset

SCKI

Figure 8. External Reset Sequence

Internal

Reset

Output

Data Pins

Outputs Forced Low

for 1024 SCKI Periods

Valid Output Data

Outputs Forced Low

Valid Output Data

Initialization

Period

Figure 9. ADC Digital Output State for Reset Operation

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

mode, the system and audio clocks should be restarted.

Once the clocks are active, the RST input may be driven

high, which initiates a reset initialization sequence.

Figure 10 illustrates the state of the output data pins

before, during, and upon exiting the power-down state.

POWER-DOWN OPERATION

The PCM4201 can be forced to a power-down state by

applying a low level to the RST input (pin 7) for a minimum

of 65,536 system clock cycles. In power-down mode, all

internal clocks are stopped, and the output data pin is

forced low. The system clock may then be removed to

conserve additional power. Before exiting power-down

RST

Output

Data Pins

Outputs

Forced Low

Outputs

Forced Low

Outputs

Forced Low

Valid Output Data

1024 SCKI Periods

Required for Initialization

65,536

SCKI Periods

Enter

Power−Down

State

Figure 10. ADC Digital Output State for Power-Down Operation

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

APPLICATIONS INFORMATION

A typical connection diagram for the PCM4201 is shown

in Figure 11. Power supply bypass and reference

decoupling capacitors are included, and are labeled with

recommended values. The 0.1µF capacitors should be

X7R ceramic chip type, although other low ESR capacitor

types may also be used. The 10µF capacitors may be low

ESR tantalum, multilayer ceramic, or aluminum

electrolytic capacitors. Analog and digital ground pins

should be connected at a common point, preferably

beneath the PCM4201 package.

INPUT BUFFER CIRCUIT EXAMPLES

The PCM4201 analog input requires some type of input

buffer or signal conditioning circuitry, especially when

interfacing to a microphone capsule. The input buffer or

amplifier must incorporate at least a single pole, RC

low-pass filter in order to provide antialias filtering for the

delta-sigma modulator. A filter with a −3dB corner

frequency in the range of 100kHz to 150kHz should be

sufficient for common audio output sampling rates equal to

or greater than 44.1kHz. However, a low-pass filter with a

lower corner frequency and possibly a higher filter order

will be required when running at the lower sampling rates,

depending upon the system requirements. Examples of

single-ended and differential input circuits are shown in

Figure 12 and Figure 13, respectively.

Printed circuit board layout is critical for best performance.

Please refer to the PCM4201EVM User’s Guide (TI

literature number SBAU108) for an example of a design

and layout that meets the published specifications for the

PCM4201.

Input

Buffer

V_IN

V_REF

Analog

Input

10 F

0.1 F

−

V_IN

−

V_REF

AGND

V_CC

DGND

V_DD

10 F

0.1 F

10 F

+1.8V to +3.6V

+5V

PCM4201

RATE

S/M

SCKI

From

BCK

Control

Logic

DSP, FPGA,

DIT4096

RST

FSYNC

DATA

HPFD

System Clock

Figure 11. Typical Connections for the PCM4201

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SBAS342B − DECEMBER 2004 − REVISED APRIL 2006

For single-ended or unbalanced inputs, the input buffer

circuit shown in Figure 12 provides the conversion to a

differential signal required for the PCM4201 analog inputs.

The buffer circuit may be configured for the appropriate

gain/attenuation using resistors R1 and R2. Capacitor C1

is chosen to provide the low-pass corner frequency.

Additional low-pass filtering is provided by the RC network

at the output of the buffer.

A differential input buffer circuit is shown in Figure 13. Like

the unbalanced circuit, the differential buffer

gain/attenuation may be set by using the R1/R2 and R3/R4

resistor pairs. The resulting gain or attenuation must be the

same for both pairs. Filtering is provided by the feedback

capacitors and the capacitors at the buffer output. This

circuit configuration is used for the PCM4201EVM

evaluation module.

10 F

to 100 F

100pF

Ω

40.2

Analog

Input

−

V_IN

U1A

Ω

2.49k

Ω

2.49k

+5V

0.022 F

Ω

40.2

Ω

10k

V_IN+

U1B

100pF

10 F

0.1 F

NOTE: U1 = OPA2134 or equivalent.

Figure 12. Single-Ended Input Buffer Circuit

1000pF

10 F

to 100 F

Ω

40.2

V_IN+

U1A

+5V

100pF

Analog

Input

Ω

10k

0.1 F

2700pF

10 F

10k

Ground

Lift

Switch

10 F

Ω

40.2

to 100 F

−

V_IN

U1B

100pF

1000pF

NOTE: U1 = OPA2134 or equivalent.

Figure 13. Differential Input Buffer Circuit

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The PCM4201 output data format is equivalent to the

Left-Justified data format supported by the DIT4096

transmitter. Although this format supports two channels for

stereo operation, the PCM4201 provides only one

channel, which corresponds to the left data channel of the

DIT4096 Left-Justified data format, and channel A of the

AES3 frame format. Figure 14 shows the physical

interface between the PCM4201 and the DIT4096

INTERFACING TO THE DIT4096 DIGITAL AUDIO

TRANSMITTER

The Texas Instruments DIT4096 digital audio transmitter

encodes linear PCM audio data into AES3 standard

formatted data, which is compatible with a number of

professional and consumer audio specifications and

interfaces. This encoding provides a convenient, standard

transmission format over which the audio data from the

PCM4201 may be carried. The physical interface may be

twisted pair or coaxial cable, or all-plastic optical fiber. The

combination of the PCM4201, the DIT4096, and the

appropriate microphone element and preamplifier circuit

may be used to create a cost-effective, digital-interface

microphone solution.

transmitter. The digital supply for the PCM4201 (V ) and

the digital I/O supply for the DIT4096 (V ) must be set to

the same voltage in order to ensure logic level

compatibility.

Preamplifier/Buffer

PCM4201

DIT4096

SCLK

SYNC

SDIN

BCK

FSYNC

DATA

V_IN

TX+

Microphone

Capsule

Balanced or Unbalanced

Line Interface or

Optical Transmitter

−

V_IN

−

S/M

SCKI

MCLK

M/S

Master

Clock

NOTES: The PCM4201 is in Master mode, while the DIT4096 is in Slave mode.

Both operate from the same Master clock source.

The data format for the DIT4096 is configured for Left−Justified mode.

Figure 14. Digital Interface Microphone Example

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Revision History

DATE

REV

PAGE

SECTION

DESCRIPTION

Added new Note (2) to Figure 3.

Product Overview

Changed order of notes in Figure 3 to accommodate new Note (2).

Replaced last sentence of first paragraph, left column to clarify BCK rate.

Several sentences used to replace original sentence.

4/12/06

Product Overview

Changed last sentence of second paragraph, left column to clarify BCK rate.

Several sentences used to replace original sentence.

NOTE: Page numbers for previous revisions may differ from page numbers in the current version.

PACKAGE OPTION ADDENDUM

www.ti.com

21-May-2010

PACKAGING INFORMATION

Status ⁽¹⁾

Eco Plan ⁽²⁾

MSL Peak Temp ⁽³⁾

Samples

Orderable Device

Package Type Package

Drawing

Pins

Package Qty

Lead/

Ball Finish

(Requires Login)

PCM4201PW

PCM4201PWG4

PCM4201PWR

PCM4201PWRG4

ACTIVE

TSSOP

Green (RoHS

& no Sb/Br)

CU NIPDAU Level-2-260C-1 YEAR

Green (RoHS

& no Sb/Br)

CU NIPDAU Level-2-260C-1 YEAR

2500

Green (RoHS

& no Sb/Br)

Green (RoHS

& no Sb/Br)

⁽¹⁾The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

⁽²⁾Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

⁽³⁾MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

Addendum-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

14-Jul-2012

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

PCM4201PWR

TSSOP

2500

330.0

12.4

6.9

5.6

1.6

8.0

12.0

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

14-Jul-2012

*All dimensions are nominal

Device

Package Type Package Drawing Pins

TSSOP PW 16

SPQ

Length (mm) Width (mm) Height (mm)

367.0 367.0 35.0

PCM4201PWR

2500

Pack Materials-Page 2

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PCM4201PWT [TI]

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