AD1893JNZ Analog Devices Inc, AD1893JNZ Datasheet - Page 15

AD1893JNZ

Manufacturer Part Number

AD1893JNZ

Description

Manufacturer

Analog Devices Inc

Datasheet

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Specifications of AD1893JNZ

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REV. A

Figure 12. Allowable Input and Output Sample Frequencies

Multiple SamplePort Synchronization and Performance

Degradation

Multiple parallel AD1893 SamplePorts may be used in a single

system. Multiple AD1893s can be “synchronized” by simply

sharing the same reset and buffered crystal connections (see

Figure 10), and ensuring that all the SamplePorts leave the reset

state on the same crystal falling edge. No other provision is

necessary since the different AD1893s will process samples

identically if they are presented with the same input and output

clocks (neglecting the effect of excessive clock skew on the PCB,

as well process variations between ASRCs which could cause

different devices to trigger at slightly different times on excess-

ively slow rising or falling clock edges).

It is also likely that several AD1893s could end up in a serial

cascade arrangement, either in a single system design or as the

result of two or more systems, each using a single AD1893 in

the signal path. The audio signal quality will be degraded with

each pass through a SamplePort, though to a very minor degree.

The THD+N performance will degrade by 3 dB with every

doubling of the number of passes through an ASRC. For ex-

ample, the AD1893 THD+N specification of –94 dB will rise to

–91 dB if the signal makes two passes through an ASRC. The

overall system THD+N specification will rise to –88 dB with

four passes, and so on.

Clipping

Under certain rare input conditions, it is possible for the

AD1893 to produce a clipped output sample. This situation is

best comprehended by employing the interpolation/decimation

model. If two consecutive samples happened to have full-scale

amplitudes (representing the peak of a full-scale sine wave, for

example), the interpolated sample (or samples) between these

two samples might have an amplitude greater than full scale. As

this is not possible, the AD1893 will compute a full-scale ampli-

tude for the interpolated sample or samples (see Figure 13).

Clipping can also arise due to the pre-echo and post-echo Gibbs

phenomena of the FIR filter, when presented with a full-scale

step input. The result of this erroneous or clipped output

sample may be measured as an extremely small decrease in

headroom for transient signals.

CRYSTAL

6kHz

= 12 MHz Case

42kHz

SAMPLING

UP-

SAMPLING

DOWN-

SIN

– kHz

SOUT

42kHz

= 1/2

SIN

SOUT

SIN

= 1/1

SOUT

= 2/1

–15–

Sample Rate Conversion Ratio Range

The AD1893 does not support exact 1:2 (or 2:1) sample rate

conversion. The SamplePort will convert to within several hertz

of the 1:2 range, but will mute before reaching the exact 1:2

ratio. Thus the AD1893 will not support applications where the

input and output sample clocks are derived from a common

source but differ by a divide-by-two. When the ratio between

the input and output sample clock reaches to within 1% of 1:2

or 2:1, the THD+N performance may degrade by several deci-

bels, due to the wraparound of the internal read/write memory

location pointers.

Options for Sample Rate Conversion over a Wider Range

There are systems requiring sample rate conversion over a range

that is wider than the 1:2 or 2:1 range provided by a single

AD1893, such as for “scrubbing” in digital audio editors. There

are at least two options in this situation. The first is to use a

programmable DSP chip to perform simple integer ratio inter-

polation or decimation, and then use the AD1893 when this

intermediate output sample frequency is within the approximate

1:2 or 2:1 range of the final desired output sample frequency. The

second is to use multiple AD1893 devices cascaded in series to

achieve the required sample rate range.

“Almost Synchronous” Operation

It is possible to apply input and output sample frequencies

which are very close (within a few hertz) or in fact synchronous

(LR_I and LR_O tied together). There is no performance pen-

alty when using the AD1893 in “almost synchronous” applica-

tions. Indeed, there is a very slight performance benefit when

the input and output sample clocks are synchronous since the

alias distortion components which arise from the noninfinite

stopband attenuation of the FIR filter will pile up exactly on top

of the sinusoidal frequency components of the input signal, and

will thus be masked.

It has been empirically observed that during almost synchronous

operation, certain AES/EBU receivers, when used to generate

the input bit clock (BCLK_I) using a 128 times F

frequency, can suffer sympathetic phase lock to the output bit

clock (BCLK_O) when the output bit clock is also operated at a

128 times F

mechanism in the analog phase lock loop portion of these AES/

EBU receivers, the lock frequency is pulled to match the fre-

quency of the output bit clock. The system can suffer inter-

mittent bursts of audible distortion when this sympathetic lock

phenomenon occurs. Analog Devices recommends avoiding the

use of a 128 times F

chronous application is intended. The use of a 64 times F

output bit clock rate is recommended.

FULL-SCALE

AMPLITUDE

Figure 13. Nipped Output Sample

rate. In other words, due to a noise pickup

output bit clock frequency if almost syn-

CORRECTLY INTERPOLATED SAMPLE

CLIPPED INTERPOLATED SAMPLE

AD1893

TIME

bit clock

AD1893JNZ Analog Devices Inc, AD1893JNZ Datasheet - Page 15

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