Distance Element Time Domain Algorithm; Distance Element Frequency Domain Algorithm - GE D90 Plus Instruction Manual

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THE D90 DISTANCE ELEMENTS

Distance element time domain algorithm

Distance element frequency domain algorithm

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• Positive-sequence voltage is between 0.8 and 1.2 pu.
• Source frequency differs from tracking frequency by less than 0.5 Hz.
• Source frequency differs from nominal frequency by less than 5.5 Hz.
• No open pole condition exists.
If these conditions are not met, then the time-domain algorithm is not armed and the
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D90 will trip from the frequency domain algorithm if required. If the conditions are met,
then the arming logic will open a two-cycle window that begins when the disturbance is
detected. During this two-cycle period, the time domain algorithm will operate if required.
After this window expires, the time domain algorithm cannot be re-armed for another five
cycles.
The time domain algorithm uses virtually the same comparators to shape the impedance
zones. Short-window orthogonal filters (h
quadrature axis quantities for voltage and current in the time domain. These signals are
then used to calculate symmetrical components, fast magnitudes (for example, current
supervision), symmetrical components, and operating and polarizing quantities for
comparators. A particular operating characteristic (mho, quadrilateral, and so on) is
composed of several two-input comparators. The time domain and frequency domain
algorithms each utilize the same number of comparators and the same input signals as
described in Distance element characteristic summary
between the two algorithms is in the formation of the input signals and the comparators
themselves.
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The D90 samples AC input signals at 128 samples per power system cycle. A fast and
accurate frequency tracking mechanism ensures accurate filtering and phasor estimation
during off-nominal frequency conditions.
The frequency domain phasor estimation process for both currents and voltages is based
on the commonly used Fourier algorithm. Due to the different nature of signal distortions
in the current and voltage signals, digital pre-filtering algorithms have been designed and
optimized separately for the current and voltage channels.
The current signals are pre-filtered using an improved digital MIMIC filter. The filter
removes effectively the DC components, guaranteeing transient overshoot below 2%
regardless of the initial magnitude and time constant of the components. The filter has
significantly better frequency response for higher frequencies as compared to a classical
MIMIC filter. This was possible without introducing any significant phase delay thanks to
the high sampling rate used by the D90
and h ) are used to calculate direct and
D G
Figure 463: Time domain algorithm
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D90 LINE DISTANCE PROTECTION SYSTEM – INSTRUCTION MANUAL
CHAPTER 15: THEORY OF OPERATION
on page 546. The only difference