Sampling rate definition

Sampling rate means the frequency with which the automation system samples the various parameters. It represents the number of events that are measured within 1 second for each parameter.

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Sampling rate means the volume rate at which stack gases are drawn through a sampling train.

Sampling rate means the volume rate which stack gases are drawn through a sampling train. "Sampling train" means a combination of entrapment devices, instruments, and auxiliary apparatus

Examples of Sampling rate in a sentence

Sampling rate for measurement and verification Equipment performance testing and measurements can be sampled following standards published in the IPMVP.
It is based on four constraint types: Zero Crossing, Bounded Di er- ence, Sampling rate and FMU-requested.
Sampling rate was set at 0.125 ms with a record duration of 2 seconds (16000 points).
In addition to the channels to be displayed, the time interval used for querying data (Sampling rate within a range of 1 to 60 seconds) and the measured quantity (e.g. instantaneous power PMOM, interval energy EINT or Command) can be selected.
Rapid data download to graph Alarm levels set up before shipping according to manufacturer’s storage requirements LCD featuring up to 1 decimal point readings Alarm indication on LCD screen Sampling rate: at least 1 measure per hour Push button to activate and stop logging.

More Definitions of Sampling rate

Sampling rate means how many times the logger samples per second.

Sampling rate. Select the sampling rate you will use. The choices for “Sampling rate” will depend on the device you select for “Driver.” Select the output channels. This setting will always be a pair such as 1-2 or 3-4. The choices will depend on the device you select for “Driver.”

Sampling rate. A sampling rate constraint is a discrete constraint. It constrains the step size such that repetitive, prede ▇▇▇ time instants are exactly hit. This can be useful in co-simulation, for instance, when a modelled control unit reads a sensor value every x milliseconds. FMU Max Step Size: This constraint implements the getMaxStepSize method from [BBG+13, CLB+16] providing a prediction of the maxi- mal step size that a given FMU instance can perform at a given point in time. It limits the need to roll back a simulation, because each FMU participates in deciding the step size, and therefore all of them are ca- pable of performing the determined step size. It is enabled by default and it constrains the step size as follows: size = min({getMaxStepSize(i) | ∀i ∈ instances}) As previously described in Deliverable 4.2b [PBLG16], stability is an impor- tant aspect of any simulation both for the detection and ability to handle otherwise unstable co-simulations. The ▇▇▇ has the ability to detect some cases that may lead to an unstable model. In Year 3 it has also been up- graded to handle some models that it previously could not simulate because the model became unstable. Further detail on the stabilization techniques are described in Section 2.5 and in the Mass Spring Damper example i De- liverable D3.6 [MGP+17].