Analog Devices AD28MSP01KST, AD28MSP01KR, AD28MSP01KN Datasheet

16-BIT

SIGMA-DELTA

DAC

ANALOG

INPUTS

RESAMPLING

INTERPOLATION

FILTER

DIFFERENTIAL

ANALOG

OUTPUT

CLOCK INPUTS

CLOCK OUTPUTS

CLOCK

GENERATION

SERIAL

PORT

DIGITAL
DATA AND
CONTROL

VOLTAGE

REFERENCE

16-BIT

SIGMA-DELTA

ADC

a

PSTN Signal Port

AD28msp01

FEATURES
Complete Analog l/O Port for DSP-Based FAX/MODEM

Applications
Linear-Coded 16-Bit Sigma-Delta ADC
Linear-Coded 16-Bit Sigma-Delta DAC
On-Chip Anti-Alias and Anti-lmage Filters
Digital Resampling/lnterpolation Filter

7.2 kHz, 8.0 kHz, and 9.6 kHz Sampling Rates
8/7 Mode for 8.23 kHz, 9.14 kHz, and 10.97 kHz

Sampling Rates
Synchronous and Asynchronous DAC/ADC Modes
Bit and Baud Clock Generation
Transmit Digital Phase-Locked Loop for Terminal

Synchronization
Independent Transmit and Receive Phase Adjustment
Serial Interface to DSP Processors
+5 V Operation with Power-Down Mode
28-Pin Plastic DlP/44-Lead PLCC/28-Lead SOIC

APPLICATIONS
High Performance DSP-Based Modems

V.32ter, V.32bis, V.32, V.22bis, V.22, V.21,

Bell 212A, 103

Fax and Cellular-Compatible Modems

V.33, V.29, V.27ter, V.27bis, V.27, V.26bis
Integrated Fax, Modem, and Speech Processing

FUNCTIONAL BLOCK DIAGRAM

GENERAL DESCRIPTION

The AD28msp01 is a complete analog front end for high perfor­mance DSP-based modems. The device includes all data conver­sion, filtering, and clock generation circuitry needed to imple­ment an echo-cancelling modem with a single host digital signal
processor. Software-programmable sample rates and clocking
modes support all established modem standards. The AD28msp01
simplifies overall system design by requiring only +5 volts.

The inclusion of on-chip anti-aliasing and anti-imaging filters
and 16-bit sigma-delta ADC and DAC ensures a highly inte­grated and compact solution for FAX or data MODEM applica­tions. Sigma-delta conversion technology eliminates the need for
complex off-chip anti-aliasing filters and sample-and-hold circuitry.

The AD28msp01 utilizes advanced sigma-delta technology to
move the entire echo-cancelling modem implementation into the
digital domain. The device maintains a –72 dB SNR throughout
all filtering and data conversion. Purely DSP-based echo cancel­lation algorithms can thereby maintain robust bit error rates
under worst-case signal attenuation and echo amplitude condi­tions. The AD28msp01’s on-chip interpolation filter resamples
the received signal after echo cancellation in the DSP, freeing
the processor for other voice or data communications tasks.

REV. A

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.

On-chip bit and baud clock generation circuitry provides for
either synchronous or asynchronous operation of the transmit
(DAC) and receive (ADC) paths. Each path features indepen­dent phase advance and retard adjustments via software control.
The AD28msp01 can also synchronize modem operation to an
external terminal bit clock.

The AD28msp01’s serial I/O port provides an easy interface to
host DSP microprocessors such as the ADSP-2101, ADSP-2105,
and ADSP-2111. Packaged in a 28-pin plastic DIP, 44-lead
PLCC, 44-pin TQFP, or 28-lead SOIC, the AD28msp01 pro­vides a compact solution for space-constrained environments.
The device operates from a +5 V supply and offers a low power
sleep mode for battery-powered systems.

A detailed block diagram of the AD28msp01 is shown in
Figure 1.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700 Fax: 617/326-8703

AD28msp01

V

FB

V

IN

INPUT

AMP

ANALOG

SIGMA-DELTA

MODULATOR

1

1.728 MHz

DIGITAL

DECIMATION

FILTER

16-BIT SIGMA-DELTA ADC

16

28.8/32.0/38.4 kHz

DIGITAL

ANTI-ALIASING

LOW-PASS FILTER

16

7.2/8.0/9.6 kHz

DIGITAL

HIGH-PASS

FILTER

7.2/8.0/9.6 kHz

SDOFS

16

SDO

500kΩ

VOLTAGE

REFERENCE

V

V

OUT+

OUT–

OUTPUT

DIFF.

AMP

TSYNC

ANALOG

SMOOTHING

FILTER

INTERNAL CLOCK

CLOCK GENERATION

t

CONVtBAUDtBIT

1

1.728 MHz

r

CONV

16-BIT SIGMA-DELTA DAC

DIGITAL

SIGMA-DELTA

MODULATOR

1.728 MHz

r

BAUDrBIT

16

Figure 1. AD28msp01 Block Diagram

PIN DESCRIPTIONS

Name Type Description

Analog Interface

V

IN

I Analog input to the inverting terminal of the

input amplifier.
V
V

FB
OUTP

O Feedback terminal of the input amplifier.
O Analog output from the noninverting terminal

of the output differential amplifier.
V

OUTN

O Analog output from inverting terminal of the

output differential amplifier.

Serial Interface

SCLK O/Z Serial clock used for clocking data or control

bits to/from the serial port (SPORT). The

frequency of this clock is 1.7280 MHz. This

pin is 3-stated when the CS is low.
SDI I Serial data input of the SPORT. Both data

and control information are input on this pin.

This pin is ignored when CS is low.
SDO O/Z Serial data output of the SPORT. Both data

and control information are output on this

pin. This pin is 3-stated when CS is low.
SDIFS I Framing synchronization signal for serial data

transfers to the AD28msp01 (via the SDI

pin). This pin is ignored when CS is low.

RESAMPLING

INTERPOLATION

M

CLK

DIGITAL

FILTER

CONTROL CIRCUITRY

SEQUENCER

RESET

16

28.8/32.0/38.4 kHz

AND

CS

INTERPOLATION

FILTER

DIGITAL

ANTI-IMAGING

LOW-PASS

FILTER

7.2/8.0/9.6 kHz

CONTROL

REGISTERS

16

SERIAL

PORT

SCLK

SDI

SDIFS

Name Type Description

SDOFS O/Z Framing synchronization signal for serial data

transfers from the AD28msp01 (via the SDO
pin). This pin is 3-stated when CS is low.

Clock Generation

TSYNC I Transmit synchronization clock. This signal is

used to synchronize the transmit clocks and
the converter clocks to an external terminal/
bit-rate clock. It is used in the V.32 TSYNC
and Asynchronous TSYNC modes and is
ignored in other operating modes. The
frequency of the external clock must be
programmed in Control Register 0. This pin
must be tied high or low if it is not being
used.

TBIT O Transmit bit rate clock. This is an output

clock whose frequency is programmable via
Control Register 3. It is synchronized with
the TCONV clock.

TBAUD O Transmit baud rate clock. This is an output

clock whose frequency is programmable via
Control Register 3. It is synchronized with
the TCONV clock.

–2–

REV. A

AD28msp01

PIN DESCRIPTIONS (Continued)

Name Type Description

TCONV O Transmit conversion clock. This clock indicates

when the ADC has finished a sampling cycle.
The frequency of TCONV is programmed by
setting the sample rate field in Control Register

0. The programmed TCONV rate can be scaled
by a factor of 8/7 by setting Bit 9 in Control
Register 1. The phase of TCONV can be
adjusted by writing the Transmit Phase Adjust
Register (Control Register 5).

RBIT O Receive bit rate clock. This is an output clock

whose frequency is programmable via Control
Register 2. It is synchronized with the RCONV
clock.

RBAUD O Receive baud rate clock. This is an output clock

whose frequency is programmable via Control
Register 2. It is synchronized with the RCONV
clock.

RCONV O Receive conversion clock. This clock indicates

when the DAC has finished a sampling cycle.
The frequency of RCONV is programmed by
setting the sample rate field in Control Register

0. The programmed RCONV rate can be scaled
by a factor of 8/7 by setting Bit 9 in Control
Register 1. The phase of RCONV can be
adjusted by writing the Receive Phase Adjust
Register (Control Register 4).

Miscellaneous

MCLK I AD28msp01 master clock input. The frequency

of this clock must be 13.824 MHz to guarantee
listed specifications.

RESET I Active-low chip reset. This signal sets all

AD28msp01 control registers to their default
values and clears the device’s digital filters.
SPORT output pins are 3-stated when

RESET

is low. SPORT input pins are ignored when
RESET is low.

CS I Active-high chip select. This signal 3-states all

SPORT output pins and forces the AD28msp01
to ignore all SPORT input pins. If CS is
deasserted during a serial data transfer, the
16-bit word being transmitted is lost.

Power Supplies

V

CC

GND
V

DD

GND

A

D

Analog supply voltage (nominally +5 V)
Analog ground
Digital supply voltage (nominally +5 V)
Digital ground

FUNCTIONAL DESCRIPTION
A/D Conversion

The A/D conversion circuitry of the AD28msp01 consists of an
analog input amplifier and a sigma-delta analog-to-digital con­verter (ADC). The analog input signal to the AD28msp01 must
be ac coupled.

Analog Input Amplifier

The analog input amplifier is internally biased by an on-chip
voltage reference in order to allow operation of the AD28msp01
with a +5 V power supply.

Input signal level to the sigma-delta modulator should not ex­ceed V

, which is specified under “Analog Interface Electri-

INMAX

cal Characteristics.” Refer to “Analog Input” in the “Design
Considerations” section of this data sheet for more information.

ADC

The ADC consists of a 3rd-order analog sigma-delta modulator,
a decimation filter, an anti-aliasing low-pass filter, and a high­pass filter. The analog input is applied to the input amplifier.
The output of this amplifier is applied to an analog sigma-delta
modulator which noise-shapes it and produces 1-bit samples at
a 1.7280 MHz rate. This bit stream is fed to the decimation
filter, which increases the resolution to 16-bits and decreases the
sampling frequency. The parallel data stream is then processed
by the anti-aliasing low-pass filter which further reduces the
sampling rate. Finally, the high-pass filter removes input fre­quency components at the low end of the spectrum.

Either the high-pass filter alone or the high-pass/anti-aliasing
low-pass filter combination can be bypassed by setting the
appropriate bits in Control Register 1, thus producing samples
at 7.2/8.0/9.6 kHz or 28.8/32.0/38.4 kHz, respectively. The gain
and the frequency response of the AD28msp01 are altered when
these filters are bypassed. The DSP processor that receives
samples from the AD28msp01 may need to compensate for this
change.

Decimation Filter

The decimation filter is a sinc4 digital filter that increases resolu­tion to 16 bits and reduces the sample rate to 28.8, 32.0, or

38.4 kHz (depending on the input sample rate). The 16 bit, par­allel data stream output of the decimation filter is then pro­cessed by the anti-aliasing low-pass filter.

Anti-Aliasing Low-Pass Filter

The anti-aliasing low-pass filter further reduces the sampling
rate by a factor of four to 7.2 kHz, 8.0 kHz, or 9.6 kHz (de­pending on the output sample rate of the decimation filter). The
output is fed to the high-pass filter. The low-pass/high-pass filter
combination can be bypassed by setting the appropriate bits in
Control Register 1. If the filters are bypassed, the signal must be
scaled by the following multipliers to achieve normal levels:

2.046 for 9.6 kHz, 0.987 for 8.0 kHz, and 0.647 for 7.2 kHz.
When the filters are bypassed, the host DSP must be able to re-

ceive data at the 28.8/32.0/38.4 kHz rates. In this case,
resampling interpolation should be disabled because of insuffi­cient bandwidth to transmit both ADC and resampled data to
the SPORT.

High-Pass Filter

The digital high-pass filter removes frequency components at
the low end of the spectrum. The high pass filter can be by­passed by setting the appropriate bits in Control Register 1.

REV. A

–3–

AD28msp01

SDO

SDOFS

SCLK

CS

SDI

SDIFS

DR0
RFS0

SCLK0
FO

DT0
TFS0

ADSP-2101

AD28msp01

The output of the ADC is transferred to the AD28msp01’s se­rial port (SPORT) for transmission to the host DSP processor.

D/A CONVERSION

The D/A conversion circuitry of the AD28msp01 consists of a
sigma-delta digital-to-analog converter (DAC) and a differential
output amplifier.

DAC

The DAC consists of an anti-imaging low-pass filter, an interpo­lation filter, a digital sigma-delta modulator, and an analog
smoothing filter. These filters have the same characteristics as
the ADC’s anti-aliasing filter and decimation filter.

The DAC receives 16-bit samples from the host DSP processor
via AD28msp01’s SPORT. If the host processor fails to write a
new value to the serial port, the existing (previous) data is read
again. The data stream is filtered first by the DAC’s anti­imaging low-pass filter and then by the interpolation filter. The
output of the interpolation filter is fed to the DAC’s digital
sigma-delta modulator, which converts the 16-bit data to 1-bit
samples. The output of the sigma-delta modulator is fed to the
AD28msp01’s analog smoothing filter where it is converted into
a low-pass filtered, analog voltage.

Anti-lmaging Low-Pass Filter

The anti-imaging low-pass filter filters the 7.2 kHz, 8.0 kHz, or

9.6 kHz data stream form the SPORTs, and raises the sampling
rate to 28.8 kHz, 32.0 kHz, or 38.4 kHz.

The anti-imaging low-pass filter can be bypassed by setting the
appropriate bit in Control Register 1. This results in a gain
change. If the filter is bypassed, the signal must be scaled by the
following multipliers to achieve normal levels: 2.046 for 9.6 kHz,

0.987 for 8.0 kHz, and 0.647 for 7.2 kHz.
When the filter is bypassed, the host DSP must be able to trans-

mit data at the 28.8/32.0/38.4 kHz rates. In this case, re­sampling interpolation should be disabled because of
insufficient bandwidth to transmit both ADC and resampled
data to the SPORT.

Interpolation Filter

The interpolation filter contains is a sinc4 digital filter which
raises the sampling rate to 1.7280 MHz by interpolating be­tween the samples. These 16-bit samples are then processed by
the digital sigma-delta modulator which noise-shapes the data
stream and reduces the sample width to a single bit stream.

Analog Smoothing Filter

The AD28msp01’s analog smoothing filter consists of a 2nd­order Sallen-Key continuous-time filter and a 3rd-order switched
capacitor filter. The Sallen-Key filter has a 3 dB point at
approximately 80 kHz.

The analog smoothing filter converts the 1.7280 MHz bit
stream output of the sigma-delta modulator into a low-pass
filtered, differential analog signal.

Differential Output Amplifier

The differential output amplifier produces the AD28msp01’s
analog output (V
greater and has a maximum differential output voltage swing of

6.312 V peak-to-peak. The output signal is dc biased to the
AD28msp01’s on-chip voltage reference (2.5 V nominal) and
can be ac coupled directly to a load or dc coupled to an external

amplifier. Refer to “Analog Output” in the “Design Consider­ations” section of this data sheet for more information.

The V

OUTP

and V

outputs must be used as differential out-

OUTN

puts; do not use either as a single-ended output.

SERIAL PORT

The AD28msp01 includes a full-duplex synchronous serial port
(SPORT) used to communicate with a host processor. The
SPORT is used to read and write all data and control registers
in the AD28msp01. The SPORT transfers 16-bit words, MSB
first, at a serial clock rate of 1.7280 MHz.

When the AD28msp01 exits reset, both the analog circuitry and
the digital circuitry are powered down. The serial port will not
transmit data to the host until the host sets the digital power­down bit (PWDD) to 1 in Control Register 1. All control regis­ters should be initialized before this bit is set.

The SPORT is configured for an externally generated receive
frame sync (SDIFS), an internally generated serial clock
(SCLK), and an internally generated transmit frame sync
(SDOFS). The host processor should be configured for an ex­ternal serial clock and receive frame sync and an internal trans­mit frame sync.

DSP Processor Interface

The AD28msp01-to-host processor interface is shown in
Figure 2.

AD28msp01

SDOFS

SCLK

SDIFS

SDO

CS

SDI

DSP PROCESSOR

SERIAL DATA RECEIVE
RECEIVE FRAME SYNC

SERIAL CLOCK
FLAG

SERIAL DATA TRANSMIT
TRANSMIT FRAME SYNC

Figure 2. AD28msp01-to-DSP Processor Interface

The AD28msp01’s chip select (CS) must be held high to enable
SPORT operation. CS can be used to 3-state the SPORT pins
and disable communication with the host processor.

To use the ADSP-2101 or ADSP-2111 as host DSP processor
for the AD28msp01, refer to Figure 3.

Note that the ADSP-2101’s SPORT0 communicates with the
AD28msp01’s SPORT while the ADSP-2101’s Flag Output
(FO) is used to signal the AD28msp01’s CS input. SPORT1 on
the ADSP-2101 must be configured for flags and interrupts in
this system.

Figure 3. AD28msp01-to-ADSP-2101 Interface

OUTP

, V

). It can drive loads of 2 kΩ or

OUTN

Figure 4 shows an ADSP-2101 assembly language program that
initializes the AD28msp01 and implements a digital loopback
through the processor.

–4–

REV. A

AD28msp01

{This ADSP-2101 program initializes the AD28msp01}
{and executes a loopback, or talk-through, routine.}

. MODULE/RAM/BOOT = 0 MSP01;
. VAR/DM/CIRC rec[2]; {Receive word buffer}
. VAR/DM/CIRC trans[2]; {Transmit word buffer}

{lnterrupt Vectors}

rset: JUMP start;

RTI; RTI; RTI;
irq2v: RTI; RTI; RTI; RTI;
sprt0t: AX0 = 0x25; DM(0x3ff3) = AX0; {Disable TX autobuffer}

RTI; RTI;
sprt0r: JUMP receive;

RTI; RTI; RTI;
sprt1t: RTI; RTI; RTI; RTI;
sprt1r: RTI; RTI; RTI; RTI;
timerv: RTI; RTI; RTI; RTI;

{Initialize DAGs}

start:

I2 = ^rec;

L2 = %rec;

I3 = ^trans;

L3 = %trans;

M0 = 0;

M1 = 1;

S1 = 0;

DM(0x3000) = SI; {Reset the AD28msp01}

{Initialize the ADSP-2101}

init

dsp:

AX0 = 0x2a0f; {Ext RFS, Int TfS, Ext SCLK, SLEN = 15}

DM(0x3ff6) = AX0; {SPORT0 control register}

AX0 = 0x101f; {Enable SPORT0}

DM(0x3fff) = AX0; {System control register}

{Initialize AD28msp01 control register}

init

msp01: {Note: This section could be autobuffered.}

IMASK = 0x10; {Enable SPORT0 TX interrupt}

AR = 0;

CNTR = 6;

DO initi UNTIL CE;

TX0 = AR; {Transmit address}
IDLE;
TX0 = SI; {Transmit control word}
IDLE;
AY0 = AR;

initi: AR = AY0 +1; {Increment address}

AX1 = 1;

AR = 0x18; {Power up AD28msp01}

TX0 = AX1;

IDLE;

TX0 = AR;

AR = B#0025; {Enable RX autobuffering with I2, M1}

DM(0x3ff3) = AR; {Autobuffer control register}

IMASK = 0x18; {Enable RX and TX interrupt}
wait: JUMP wait; {Wait for receive interrupt}

{Receive Interrupt Routine}

receive:

DM(0x3ff3) = SI; {Disable autobuffering}

AX1= DM(I2, M1); {Read first receive word from buffer}

REV. A

–5–

AD28msp01

AX0 = DM(I2, M1); {Read data word}
AY0 = 8; {Verify AD28msp01 address = 8}
AR = AX1 – AY0;
IF EQ JUMP goodstuff;
RTI;

goodstuff;

MODIFY (I3, M1); {Point to second word of TX buffer}
DM(I3, M0) = AX0;
MX1 = 6; {Load address word into MX1}
AR = 0x06a7; {Enable TX and RX autobuffer}
DM(0x3ff3) = AR; {Write to SPORT control Register}
TX0 = MX1; {Autobuffer start}
RTI;

.ENDMOD;

Figure 4. AD28msp01 Initialization and ADSP-2101 Loopback Routine

Serial Data Output

When the digital power-down bit (PWDD) of Control Register 1
is set to 1, the AD28msp01’s SPORT begins transmitting data to
the host processor. All transfers between the host processor and
the AD28msp01 consist of a serial data output frame sync
(SDOFS) followed by a 16-bit address word, then a second
frame sync followed by a 16-bit data word. Address/data word
pairs are transmitted whenever they become available. The
ADC takes precedence over the Interpolator output data. If a
new word becomes available while a serial transfer is in progress,
the current serial transfer is completed before the new word starts
transmission.

Serial Data Input

The host processor must initiate data transfers to the
AD28msp01 by asserting the serial data input frame sync
(SDIFS) high. Each of the 16-bit address word and 16-bit data
word transfers begins one serial clock cycle after SDIFS is as­serted. The address word always precedes the data word. The
second serial data input frame sync for the data word can be as­serted as early as the last bit of the address word is transmitted,
or any time after.

The host processor must assert SDIFS shortly after the rising
edge of SCLK and must maintain SDIFS high for one cycle be­cause SDIFS is clocked by the SCLK falling edge. Data is then
driven from the host processor shortly after the rising edge of
the next SCLK and is clocked into the AD28msp01 on the fall­ing edge of SCLK in that cycle. Each bit of a 16-bit address and
16-bit data word is thus clocked into the AD28msp01 on the
falling edge of SCLK (MSB first).

If SDIFS is asserted high again before the end of the present
data word transfer, it is not recognized until the falling edge of
SCLK in the last (LSB) cycle.

When the serial port receives an interpolator or DAC input
word, it writes the value to an internal register which is read by
the AD28msp01 when it is needed. This allows the host to send
data words at any time during the sample period.

NOTE: Exact SPORT timing requirements are defined in the
“Specifications” section of this data sheet.

Clock Generation

The AD28msp01 generates all transmit and receive clocks
necessary to implement standard voice-grade modems. The
AD28msp01 can generate six different clock signals for transmit

and receive timing as well as an additional clock signal for serial
port timing.

The receive clocks are the RCONV, RBIT and RBAUD signals.
The individual clock rates are programmable and are all syn­chronized with RCONV.

The transmit clocks are the TCONV, TBIT and TBAUD sig­nals. The individual clock rates are programmable and are all
synchronized with TCONV.

Depending on the operating mode, the converter clocks can be
synchronized to an external clock signal (TSYNC) or can be
generated internally. The clocks can be adjusted in phase by set­ting the appropriate phase adjust register. All the AD28msp01
Bit/Baud clocks have a 50% duty cycle except the 1600 Hz baud
rate. This baud rate has a 33%–66% duty cycle.

Resampling Interpolation Filter

The resampling interpolation filter interpolates the data from
the TCONV rate to 1.7280 MHz. The data is then resampled
(decimated) in phase with the RCONV clock. The frequency re­sponse characteristics of the resampling interpolation filter are
identical to the frequency response characteristics of the anti­imaging, low-pass filter/interpolation filter combination.

Figure 5 illustrates the effects of a resampling interpolation
filter.

ANALOG SIGNAL

SAMPLED AT 9600 Hz

OUTPUT OF

INTERPOLATION

FILTER

OUTPUT OF

RESAMPLING

FILTER

Figure 5. Effects of Interpolation Filter

–6–

REV. A

AD28msp01

Since the resample phase is locked to RCONV, it can be ad­vanced or slipped by writing a signed-magnitude value to the
Receive Phase Adjust Register (Control Register 2). The phase
advance or slip is equal to the master clock period (13.824 MHz)
multiplied by the signed-magnitude 9-bit value in Control
Register 4.

The change in phase requires a maximum of two RCONV
cycles to complete. If the value written to Control Register 4 is
less than the oversampling ratio, then the change will complete
in one RCONV cycle.

Control Registers

The AD28msp01’s six control registers configure the device for
various operating modes including filter bypass and power­down. The AD28msp01’s host processor can read and write to

Control Register 0 address = 0x00

This register is used to:

• Enable/disable the resampling interpolation filter

• Set the external TSYNC clock rate

• Select the sampling rate

• Select the operating mode

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

0000000000000000

the control register through the AD28msp01’s serial port
(SPORT).

The control registers should be set up for the desired mode of
operation before bringing the AD28msp01 out of power-down
(by writing ones to the

PWDA and PWDD bits in Control

Register 1).
The control registers are cleared (set to 0x0000) when the

AD28msp01 is reset.
The sampling rate should be set before writing ones to the

power-down bits. Changing the sampling rate at any other time
will force a soft reset. For more information about soft resets,
refer to the end of this section of the data sheet.

NOTE: Reserved bits should always be cleared to 0.

INTEN

Interpolation filter enable

1 = enabled; 0 = disabled

TS3-0

TSYNC Rate (Hz)

0000 = 9600
0001 = 8000
0010 = 7200
0011 = 4800
0100 = 2400
0101 = 1200
0110 = 600
0111 = 19200
1000 = 14400
1001 = 12000

SR1-0

Sampling Rate (kHz)

00 = 9.6
01 = 8.0
10 = 7.2
11 = Reserved

Control Register 1 address = 0x01

This register is used to:

• Increase the sampling rate to 8/7 the rate selected in Control Register 0

• Power down the device

• Bypass the digital filters

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

000000000000000

SA87

When set to a 1, this bit increases the
sampling rate to 8/7 of the programmed
rate:
(8/7) 9.6 kHz = 10.97 kHz,
(8/7) 8.0 kHz = 9.14 kHz,
(8/7) 7.2 kHz = 8.23 kHz

PWDA

Power Down Analog

1 = Standard Operation
0 = Low Power

PWDD

Power Down Digital

1 = Standard Operation
0 = Low Power

FB2 FB1 FB0

0

FB2-0

Filter Bypass
Configuration

FB2 FB1 FB0

0 0 0 = No filter bypass (default)
0 0 1 = Reserved
0 1 0 = ADC Hi pass filter bypassed
0 1 1 = ADC Hi and Lo pass filter bypassed
1 0 0 = DAC filter bypassed
1 0 1 = Reserved
1 1 0 = DAC and ADC Hi pass filters bypassed
1 1 1 = DAC, ADC Hi and ADC Lo pass filters

OP2-0

Operating Modes

000 = Asynchronous fallback mode
001 = Reserved
010 = Reserved
011 = Reserved
100 = V.32 TSYNC
101 = V.32 Internal Sync
110 = V.32 Loopback
111 = Async. fallback mode TSYNC

bypassed

REV. A

–7–

AD28msp01

If any low-pass filter is bypassed, the resampling interpolation filter should be disabled (in Control Register 0.)

Control Register 2 address = 0x02

This register is used to:

• Select the frequency of the Receive baud clock (RBAUD)

• Select the frequency of the Receive bit clock (RBIT)

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

000000000000000

0

BA2-0

Receive baud rate clock selection

000 = 2400 (default)
001 = 1600
010 = 1200
011 = 600
100 = Reserved
101 = Reserved
110 = Reserved
111 = Reserved

Control Register 3 address = 0x03

This register is used to:

• Select the frequency of the Transmit baud clock (TBAUD)

• Select the frequency of the Transmit bit clock (TBIT)

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

000000000000000

BA2-0

Transmit baud rate clock
selection

000 = 2400 (default)
001 = 1600
010 = 1200
011 = 600
100 = Reserved
101 = Reserved
110 = Reserved
111 = Reserved

BI3-0

Receive bit rate clock selection

0000 = 9600 (default)
0001 = 8000
0010 = 7200
0011 = 4800
0100 = 2400
0101 = 1200
0110 = 600
0111 = 19200
1000 = 14400
1001 = 12000
1010 = 19200 with SA87 in
control register 1 set
(not scaled by 8/7)

0

BI3-0

Transmit bit rate clock selection

0000 = 9600 (default)
0001 = 8000
0010 = 7200
0011 = 4800
0100 = 2400
0101 = 1200
0110 = 600
0111 = 19200
1000 = 14400
1001 = 12000
1010 = 19200 with SA87 in
control register 1 set
(not scaled by 8/7)

–8–

REV. A

AD28msp01

Control Register 4 address = 0x04

This register is the Receive Phase Adjust Register and it is used to:

• Change the phase of the receive clocks (RBAUD, RBIT, RCONV)

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

000000000000000

0 – Phase advance
1 – Phase retard

P7-0

Phase Shift Magnitude

The amount of time slipped
or advanced is defined as
this number represented by
P7-P0 times the master
clock period.

Once you have written a value to the register, subsequent writes are ignored until the register is finished incrementing/decrementing
to zero.

The phase advance or slip is equal to the master clock period (13.824 MHz) multiplied by the signed-magnitude 9-bit value in
Control Register 4. The AD28msp01 decrements Control Register 4 as it adjusts the phase of RCONV. Control Register 4 will equal
zero when the phase shift is complete.

Control Register 5 address = 0x05

This register is the Transmit Phase Adjust Register and it is used to:

• Change the phase of the Transmit clocks (TBAUD, TBIT, TCONV)

0

15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

000000000000000

0 – Phase advance
1 – Phase retard

This register must be equal to zero before its value can be
changed. Once you have written a value to the register, subse­quent writes are ignored until the register is finished incrementing/
decrementing to zero.

The phase advance or slip is equal to the master clock period
(13.824 MHz) multiplied by the signed-magnitude 9-bit value in
Control Register 5. The AD28msp01 decrements Control Regis­ter 5 as it adjusts the phase of TCONV. Control Register 5 will
equal zero when the phase shift is complete.

Soft Resets

Certain conditions cause the AD28msp01 to perform a soft reset;
the DSP is reset but the control register values do not change.

Table I shows when a soft reset is caused by changing the values
of certain control register bits while the device is operating.
When these bits are modified, the AD28msp01 will perform a
soft reset and start up again in the new configuration. Reserved
bits in the control registers should always be set to zero.

0

P7-0

Phase Shift Magnitude

The amount of time slipped
or advanced is defined as
this number represented by
P7-P0 times the master
clock period.

Table I. Soft Reset

Bits Configures

Control Register 0, SR1–SR0 Sampling rate
Control Register 0, OP2–OP0 Clock generation operating modes

(async-to-V.32 or V.32-to-async)
Control Register 0, TS3–TS0 TSYNC rate
Control Register 1, FB2–FB0 Filter bypass configuration
Control Register 1, SA87 Sampling rate scaling by 8/7

Data Registers

The AD28msp01 contains four data registers.

Data Register 0 address = 0x06

DAC Input Register (write-only): The 16-bit twos complement
values written to this register are input to the AD28msp01’s
digital-to-analog converter.

REV. A

–9–