100 Examples of sentences containing the common noun "phasor"

Definition

A Phasor is a complex number used in electrical engineering and physics to represent a sinusoidal function whose amplitude (magnitude), phase (angle), and frequency are time-invariant. Phasors are particularly useful in analyzing AC circuits and signal processing.

Synonyms

• Vector
• Complex number
• Sinusoid (in specific contexts)

Antonyms

• Non-sinusoidal
• Asynchronous (in specific contexts)

Examples

1. The engineer used a phasor to analyze the circuit's performance.
2. We can represent the voltage as a phasor for easier calculations.
3. The frequency of the phasor remained constant throughout the experiment.
4. In AC circuit analysis, the phasor simplifies the calculation of currents.
5. The phasor diagram showed the relationship between voltage and current.
6. After converting to a phasor, the calculations became much simpler.
7. The phasor representation helps in visualizing waveforms.
8. To find the total impedance, we must add the phasor values.
9. Engineers often use phasor analysis to improve circuit efficiency.
10. The phasor method is essential for understanding reactive power.
11. We can phasor the signals to eliminate phase discrepancies.
12. The phase shift in the phasor indicates how the waveform is delayed.
13. By using a phasor, we can easily calculate the power factor.
14. The output waveform can be represented using a phasor.
15. He learned how to convert time-domain signals into phasor form.
16. The phasor technique is widely used in telecommunications.
17. The results were plotted on a phasor diagram for clarity.
18. By analyzing the phasor, we determined the resonant frequency.
19. The phasor analysis revealed unexpected losses in the circuit.
20. We need to phasor the inputs to ensure accurate results.
21. The concept of a phasor was introduced in the early 20th century.
22. Understanding phasor relationships is key to mastering AC theory.
23. The phasor transformation simplifies the analysis of linear systems.
24. They had to phasor the signals before proceeding with the experiment.
25. The phasor representation aids in understanding harmonic distortion.
26. We will phasor the voltage and current to find their phase difference.
27. The phasor model is applicable to both single-phase and three-phase systems.
28. The technician used a phasor meter to measure the signals.
29. The phasor diagram helped visualize the phase relationships in the circuit.
30. He could easily phasor the waveforms after practicing the technique.
31. The phasor analysis showed that the system was out of phase.
32. They decided to phasor the inputs to improve the accuracy of their readings.
33. By representing the signal as a phasor, we can simplify the math involved.
34. The phasor approach is often favored in modern electrical engineering.
35. The team needed to phasor the outputs to troubleshoot the issue.
36. Using a phasor, they calculated the effective voltage in the system.
37. The phasor method allows for straightforward analysis of oscillating signals.
38. The relationship between current and voltage can be understood through phasor analysis.
39. He learned how to phasor complex signals effectively.
40. The phasor representation clarifies the relationship between frequency and amplitude.
41. The engineers chose to phasor their measurements for consistency.
42. The phasor display showed a clear representation of the waveforms.
43. They had to phasor the outputs to identify the phase shift.
44. The concept of a phasor is fundamental to many electrical engineering principles.
45. By using a phasor, they could analyze the circuit's behavior more effectively.
46. The phasor model helped in visualizing the circuit dynamics.
47. They decided to phasor the signals to analyze the system's stability.
48. The phasor analysis allowed for a deeper understanding of the circuit's operation.
49. He was able to phasor the complex waveforms with ease.
50. The phasor provides a tool for analyzing alternating current systems.
51. They had to phasor their inputs to ensure synchronization.
52. The phasor concept is crucial for understanding reactive components in circuits.
53. The technician demonstrated how to phasor the signals correctly.
54. By using a phasor approach, the team could simplify their calculations.
55. The phasor representation is essential for analyzing AC circuit responses.
56. They needed to phasor the outputs to understand the overall system behavior.
57. The phasor analysis indicated a phase difference of 90 degrees.
58. By learning to phasor signals, he improved his analytical skills.
59. The phasor diagram highlighted the importance of phase relationships.
60. The engineers aimed to phasor their results for better accuracy.
61. The phasor representation clarified the oscillation characteristics of the signal.
62. We will phasor the data to check for any discrepancies.
63. The phasor is a powerful tool in signal processing applications.
64. The team used a phasor to model the circuit's behavior effectively.
65. He could easily phasor the voltages in different phases.
66. The phasor approach helps in visualizing complex relationships in circuits.
67. They decided to phasor the results to facilitate analysis.
68. The phasor representation simplifies the analysis of periodic functions.
69. By converting to a phasor, we can analyze the system's response more effectively.
70. The phasor approach is widely accepted in modern electrical engineering.
71. He was able to phasor the signals without any issues.
72. The phasor analysis is essential for understanding load characteristics.
73. They needed to phasor the inputs to ensure they were in sync.
74. The phasor display provided a clear view of the circuit's operation.
75. By using a phasor, the calculations became straightforward.
76. The phasor model was crucial for their project.
77. They learned how to phasor complex waveforms over time.
78. The phasor representation is integral to understanding circuit dynamics.
79. He could quickly phasor the circuit for an accurate analysis.
80. The phasor technique helped in visualizing the interaction of signals.
81. The team had to phasor their findings to draw conclusions.
82. The phasor representation indicated a significant phase shift.
83. By learning to phasor, the students improved their understanding of AC theory.
84. The phasor approach simplifies the understanding of voltage and current relationships.
85. They needed to phasor the measurements for consistency in their data.
86. The phasor analysis revealed insights into the system's efficiency.
87. By analyzing the phasor, they identified potential issues in the circuit.
88. The phasor method is essential for working with sinusoidal functions.
89. They could easily phasor the signals after mastering the technique.
90. The phasor representation aids in understanding frequency response.
91. They decided to phasor the inputs to avoid phase misalignment.
92. The phasor analysis provided clarity on the circuit's performance.
93. The technician demonstrated how to phasor the signals accurately.
94. By using a phasor, they could simplify the process of analyzing circuits.
95. The phasor model is applicable to various engineering fields.
96. The team learned to phasor their results for a better understanding.
97. The phasor representation clarified the interaction between different signals.
98. They needed to phasor the outputs to ensure proper operation.
99. The phasor analysis helped in diagnosing the circuit problems.
100. By mastering how to phasor signals, he became proficient in electrical analysis.