User manual

ManualsBrandsAgilent Technologies ManualsGraphics TabletDP111

Programmer’s Guide Page 51 of 64

Model

Input

Frequency

range (MHz)

sFmax vs. nbrConvertersPerChannel

DP235/AP235

20 – 1000

½ × inputFrequency

1 × inputFrequency

DP240/AP240

20 – 2000

½ × inputFrequency

1 × inputFrequency

DP306

100 – 200

½ × inputFrequency

DP306 Rev A

100 – 400

½ × inputFrequency

DP308

100 – 400

½ × inputFrequency

DP308 Rev A

100 – 400

1 × inputFrequency

DP310

100 – 420

1 × inputFrequency

DP310 Rev A

100 – 400

1 × inputFrequency

AC210/SC210

20 – 2000

½ × inputFrequency

AC240/SC240

20 – 2000

½ × inputFrequency

1 × inputFrequency

U1084A

1000 or 2000

1 x inputFrequency

2x inputFrequency

generation

100 – 500

1 × inputFrequency

Example: When using a DC241 with 2 combined channels, and an external clock frequency of 1800 MHz (=

inputFrequency), the possible sampling frequencies are 3.6 GS/s, 1.8 GS/s, 900 MS/s and 450 MS/s.

The ratio of sFmax to inputFrequency can also be learned at run-time by using a call to

Acqrs_getInstrumentInfo(instrID," ExtCkRatio", &ratio).

The system computes the required memory overhead (in data samples) on the basis of the current sampFrequency

and nbrConvertersPerChannel. Use the function AcqrsD1_bestNominalSamples to obtain the maximum

available memory, after setting these parameters.

The equivalent of delayTime is defined with the value delayNbrSamples, which only applies to external clock

operation. The actual delay value is easily computed as follows:

delay = (delayNbrSamples – nbrSamples) / sampFrequency

Example: In a 1

generation module with an external clock running at 200 MHz, if you wanted to acquire 2000 data

points at 50 MS/s with the trigger point at the end of the first quarter of the time window, you would use the code:

AcqrsD1_configMemory(instrID,2000,1);

AcqrsD1_configExtClock(instrID,1,threshold, 1500, 2.0e+8, 5.0e+7);

AcqrsD1_acquire(instrID); // start the acquisition

AcqrsD1_waitForEndOfAcquisition(instrID, timeOut);

The value of delayNbrSamples is 1500 because 500 points need to be acquired before and 1500 points after the

trigger, in order to position the trigger point at the 1

quarter of the time window.

Equivalently, you could have computed the time window to be 2000 x 20 ns = 40 μs. The delay would therefore have

to be -10 μs to get the trigger point to the 1

quarter of the time window. Since nbrSamples = 2000 and

sampFrequency = 5.0e+7, you would obtain delayNbrSamples = 1500.

Since the sampling frequency is known in this clock mode, through the variable sampFrequency, any read functions

correctly return the value of the sampling interval.

In addition, if the user-supplied clock frequency inputFrequency is > 800 MHz on DC271-FAMILY digitizers or in

all cases for 10-bit and 12-bit digitizers, the system correctly measures the value horPos and returns it with any

waveform read function, such as AcqrsD1_readData. Thus, the time position of the sampled data points can be

known to within a small fraction of the sampling interval, permitting very precise timing measurements as with the

internal clock. However, the digitizer must be calibrated at the external clock frequency in use, whenever

inputFrequency or sampFrequency are changed. Use this code: