sophiecentaur said:Not quite arbitrary. For a frequency higher than the reference frequency (at which the axes are 'frozen', a higher frequency will be represented by a phasor which is rotating anticlockwise and vice versa because of the rate of change of phase relative to the reference.
gsal said:While the statement above is true for individual signals...
It is possible to make higher frequency signals show up rotating counterclockwise respect to the frame of reference...this can be accomplished via linear combination of spatially shifted higher frequency signals.
This is not as weird as it may seem...it is happening right now, somewhere in the world.
I am talking about a 3-phase electrical generator at some power plant that might not be working under perfect conditions and hence having non-purely sinusoidal waves through its winding...under these conditions, the waves can be decomposed (fourier) into purely sinusoidal ones starting with one at the fundamental frequency (f) and the rest at higher frequencies (2f, 3f, 4f, 5f, 6f, 7f...).
BUT, when we are talking about a 3-phase system, we have 3 sets of these signals that are (electrically) phase shifted 120 degrees (360/3) and being applied to windings ("mechanically", physically) located 120 degrees (for 2-pole generator) away from each other...when you add the signals vectorially, the resultant may rotate counterclockwise (CCW) or clockwise (CW) respect to the fundamental...
...for example, say the fundamental is rotating CCW at an angular velocity of 1f:
- when you add the 5th harmonics from all 3 phases, the resultant will rotate CW with a velocity of 5f
- when you add the 7th harmonics from all 3 phases, the resultant will rotate CCW with a velocity of 7f
A phasor is a vector representation of a sinusoidal signal that is typically used in electrical engineering and physics. It is used to represent the magnitude and phase of a sinusoidal signal. The reason why a phasor rotates anticlockwise is due to the fact that it is a complex number in the form of Aejωt, where A is the magnitude, e is the base of the natural logarithm, j is the imaginary unit, and ωt is the phase angle. As time increases, the phase angle increases, causing the phasor to rotate in an anticlockwise direction.
In AC circuits, the voltage and current are sinusoidal functions that vary with time. A phasor is used to represent these varying quantities in a simplified manner. By representing the sinusoidal signals as phasors, calculations and analysis of AC circuits become much easier and more efficient.
The direction of rotation of a phasor indicates the phase relationship between different sinusoidal signals. When two phasors rotate in the same direction, they are in phase, meaning they have the same frequency and are aligned at the same point in time. When two phasors rotate in opposite directions, they are out of phase, meaning they have different frequencies or are not aligned at the same point in time.
Technically, yes, a phasor can rotate clockwise if the phase angle is negative. However, it is standard convention to use the anticlockwise direction for representing phasors in electrical engineering and physics. This convention is used to simplify calculations and analysis of AC circuits.
The direction of rotation of a phasor is directly affected by changes in frequency. As the frequency of a sinusoidal signal increases, the phasor rotates at a faster rate in the anticlockwise direction. Similarly, as the frequency decreases, the phasor rotates at a slower rate in the anticlockwise direction.