PCM67 Burr-Brown Corporation, PCM67 Datasheet - Page 10

PCM67

Manufacturer Part Number

PCM67

Description

Advanced 1-Bit BiCMOS Dual 18-Bit DIGITAL-TO-ANALOG CONVERTER

Manufacturer

Burr-Brown Corporation

Datasheet

1.PCM67.pdf (13 pages)

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THEORY OF OPERATION

Digital converters in audio systems have traditionally utilized

a laser-trimmed, current-source DAC architecture. Unfortu-

nately, this type of technology suffers from the problems

inherent in switching widely varying current levels. Design

improvements have helped, but DACs of this type still exhibit

low-level nonlinearity due to errors at the major carry.

Recently, DACs employing a different architecture have been

introduced. Most of these DACs utilize a one-bit DAC with

“noise shaping” techniques and very high oversampling rate

to achieve the digital-to-analog conversion. Basically, the

trade-off is from very accurate but slow current sources to one

rapidly sampled current source whose average output in the

audio frequency range is equal to the current desired. Noise

shaping insures that the “undesirable” frequencies associated

with one-bit DAC output lie outside the audio range.

These “Bitstream”, “MASH”, or one-bit DACs overcome the

low level linearity problems of conventional DACs, since

there can be no major carry error. However, this architecture

exhibits problems of its own: signal-to-noise performance is

usually worse than a similar conventional DAC, “dither

noise” may be needed in order to get rid of unwanted tones, a

separate high-speed clock may be required, the part may show

sensitivity to clock jitter, and a high-order low-pass filter is

necessary to filter the DAC output.

The PCM67/69A is a cross between these two architectures.

It includes both a conventional laser-trimmed, current-source

DAC and an advanced one-bit DAC. The conventional DAC

is a 10-bit DAC where each bit weight has been trimmed to 18-

bit linearity. The one-bit DAC has a weight equal to bit 10 and

employs a first-order noise shaper to generate the “bitstream.”

This approach does not eliminate all the problems associated

with the two architectures but rather minimizes them as much

as possible. The conventional DAC still exhibits some major

carry error which would normally reduce low-level linearity.

However, to reduce this error even further, the PCM67/69A

utilizes an offset technique whereby bit n is subtracted from

the digital input code whenever it is positive (see Figure 1 and

Table I). When this is done, an offset current equal to the

PCM67/69A

weight of bit n is switched in to compensate. This offset comes

from a one-bit DAC which has also been trimmed to 18-bit

linearity. While this technique doesn’t remove the major carry

error completely, the “glitch” is only present in higher ampli-

tude signals where it is much less audible.

As for the one-bit DAC, a number of problems with this

architecture are also reduced: the DAC is designed to operate

from the system clock, thus eliminating the need for a separate

clock; the lower quantizing level of the DAC make it less

sensitive to clock jitter; and output filtering requirements are

reduced because “out-of-band noise” has smaller amplitude,

is “farther-out,” and increases much more slowly due to the

first-order noise shaper. Still, it is important to keep in mind

that the one-bit DAC imposes some design considerations.

Figure 2 shows the THD + N of the converter versus “System

Clock” frequency. This is the clock used to operate the one-bit

DAC and noise shaper. Generally, the higher the oversampling

the better. However, near full-scale, the converter is limited by

other constraints and higher clock frequencies (past 96f

to slightly worsen its performance. At low levels, perfor-

mance improves almost linearly with increasing clock fre-

quency. The one-bit DAC was designed to operate between

96f

it can be operated at 48f

reduced performance.

TOTAL HARMONIC DISTORTION + NOISE

A key specification for audio DACs is usually total harmonic

distortion plus noise (THD + N). For the PCM67/69A, THD

+ N is tested in production as shown in Figure 12. Digital data

words are read into the PCM67/69A at eight times the stan-

dard compact disk audio sampling frequency of 44.1kHz

(352.8kHz) so that a sine wave output of 991Hz is realized.

The output of the DAC goes to an I-to-V converter, then to a

programmable gain amplifier to provide gain at lower signal

output test levels, and then through a 40kHz low pass filter

before being fed into an analog type distortion analyzer.

(4X oversampling) and 384f

(2X oversampling) with slightly

(16X oversampling). But,

) tend

PCM67 Burr-Brown Corporation, PCM67 Datasheet - Page 10

PCM67

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