Clock Jitter Measurement

Input clock signal, specified as a scalar. The input signal must have only one threshold crossing per period.

Running RMS value of the period jitter calculated up to the current time step, returned as a scalar. Period jitter is the deviation in the cycle time of a clock signal with respect to the ideal period.

Running RMS value of the cycle-to-cycle jitter calculated up to the current time step, returned as a scalar. Cycle-to-cycle jitter is the difference in the period between the two consecutive cycles of the clock.

Dependencies

To enable this port, select Cycle-2-Cycle (C2C) Jitter.

Difference between the real duty cycle in percentage and the ideal 50% value, returned as a scalar.

Dependencies

To enable this port, select Duty Cycle Distortion (DCD).

Frequency of the input clock signal, specified as a positive real scalar in Hz. Clock Frequency is used to calculate the ideal value of the period of the input signal.

Programmatic Use

Threshold signal level to calculate the rising and falling edge of the signal, specified as a real scalar.

Programmatic Use

Select to calculate the RMS period jitter. This option is selected by default.

Period jitter is the deviation in the cycle time of a clock signal with respect to the ideal period.

Select to calculate the RMS cycle-to-cycle (C2C) jitter. This option is deselected by default.

Cycle-to-cycle jitter is the difference in the period between the two consecutive cycles of the clock.

Select to calculate the duty cycle distortion for each cycle. This option is deselected by default.

Duty cycle distortion is the difference between the real duty cycle in percentage and the ideal 50% value.

Select the simulation mode. This choice affects the simulation performance.

Simulating the model using the Code generation method requires additional startup time, but the subsequent simulations run faster. Simulating the model using the Interpreted execution method may reduce the startup time, but the subsequent simulations run slower. For more information, see Interpreted Execution vs. Code Generation.