EVAL-AD1954EB Analog Devices Inc, EVAL-AD1954EB Datasheet - Page 18

EVAL-AD1954EB

Manufacturer Part Number

EVAL-AD1954EB

Description

BOARD EVAL FOR AD1954

Manufacturer

Analog Devices Inc

Datasheet

1.AD1954YSTZRL.pdf (36 pages)

Specifications of EVAL-AD1954EB

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The biquad filter before the detector can be used to implement a

frequency-dependent compression threshold. For example, assume

that the overload point of the woofer is very frequency depen-

dent. In this case, one would have to set the compressor threshold

to a value that corresponded to the most sensitive overload fre-

quency of the woofer. If the input signal happened to be mostly

in a frequency range where the woofer was not so sensitive to

overload, then the compressor would be too pessimistic and the

volume of the woofer would be reduced. If, on the other hand,

the biquad filter were designed to follow the woofer excursion

curve of the speaker, then the volume of the woofer could be

maximized under all conditions. This is illustrated in Figure 15.

When using a filter in front of the detector, a confusing side effect

occurs. If one measures the frequency response by using a swept

sine wave with an amplitude large enough to be above the com-

pressor threshold, the resulting frequency response will not look

flat. However, this is not real in the sense that, as the sine wave is

swept through the system, the gain is being slowly modulated up

and down according to the response of the biquad filter in front of

the detector. If one measures the response using a pink noise gen-

erator, the result will look much better, since the detector will settle

on only one gain value.The perceptual effect of the swept sine wave

test is not at all what would be predicted by simply looking at the

frequency response curve; it is only the signal path filters that will

affect the perception of the frequency response, not the detector

path filters.

De-emphasis Filtering

The standard for encoding CDs allows the use of a pre-emphasis

curve during encoding, which must be compensated for by a

de-emphasis curve during playback. The de-emphasis curve

is defined as a first order shelving filter with a single pole at

(1/(2    50 µs)) followed by a single zero at (1/(2    15 µs)).

This curve may be accurately modeled using a first order digital

filter. This filter is included in the AD1954; it is not part of the

bank of biquad filters and so does not take away from the num-

ber of available filters.

Since the specification of the de-emphasis filter is based on an

analog filter, the response of the filter should not depend on the

AD1954

Figure 15. Optimizing Woofer Loudness Using the

Subwoofer rms Biquad Filter

20Hz

FREQUENCY

200Hz

20Hz

FREQUENCY

200Hz

–18–

incoming sampling rate. However, when the de-emphasis filter is

implemented digitally, the response will scale with the sampling

rate unless the filter coefficients are altered to suit each possible

input sampling rate. For this reason, the AD1954 includes three

separate de-emphasis curves: one each for sampling rates of

32 kHz, 44.1 kHz, and 48 kHz. These curves are selected by

writing to Bits 5 and 4 of Control Register 1 over the SPI port.

Alternatively, the 44.1 kHz curve can be called upon using the

DEEMP/SDATA_AUX pin.This pin is included for compatibility

with CD decoder chips that have a de-emphasis output pin.

Using the Sub Reinjection Paths for Systems with No Subwoofer

Many systems will not use a subwoofer but would still benefit

from two-band compression/limiting. This can be accommodated

by using sub reinjection paths in the program flow. These param-

eters are programmed by entering two numbers (in 2.20 format)

into the parameter RAM. Note that if the biquad filters are not

properly designed, the frequency response at the crossover point

may not be flat. Many crossover filters are designed to be flat in

the sense of adding the powers together, but nonflat if the sum is

done in voltage mode.The user must take care to design an appro-

priate set of crossover filters.

Interpolation Filters

The left and right channels have a 128:1 interpolation filter with

70 dB stop-band attenuation that precedes the digital - modu-

lator. This filter has a group delay of approximately 24.1875/f

taps, where f

taps, where f is the sampling rate. The sub channel does not use

an interpolation filter. The reason for this (besides saving valuable

MIPS) is that it is expected that the bandwidth of the sub output

will be limited to less than 1 kHz. With no interpolation filter, the

first image will therefore be at 43.1 kHz (which is f

first image will therefore be at 43.1 kHz (which is f – 1 kHz for

CD audio). The standard external filter used for both the main

and sub channels is a third order, single op amp filter. If the cut-

off frequency of the external subwoofer filter is 2 kHz, then there

are more than four octaves between 2 kHz and the first image

at 43.1 kHz. A third order filter will roll off by approximately

18 dB/oct  4 octaves = 72 dB attenuation. This is approximately

the same as the digital attenuation used in the main channel

filters, so no internal interpolation filter is required to remove the

out-of-band images.

Note that by having interpolation filters in the main channels

but not the subwoofer channel, there is a potential time-delay

mismatch between the main and sub channels. The group delay

of the digital interpolation filters used in the main left/right

channels is about 0.5 ms. This must be compared to the group

delay of the external analog filter used in the subwoofer path. If

the group-delay mismatch causes a frequency response error

(when the two signals are acoustically added), then the pro-

grammable delay feature can be used to put extra delay in either

the subwoofer path or the main left/right path.

REV. A

EVAL-AD1954EB Analog Devices Inc, EVAL-AD1954EB Datasheet - Page 18

EVAL-AD1954EB

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