Reactance is opposition. XL = 2 * PI * f * L. Inductive reactance = two times PI (i.e., 3.14) times frequency in hertz times inductance in henries. Reactance (opposition) is not influenced by the amplitude of the applied voltage. If frequency goes up, inductive reactance goes up. Intuitively, the higher the frequency (i.e., rate of change), the more significant become the counter-currents induced in adjacent turns.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Reactance is opposition. XC = 1 over ( 2 * PI * f * C ). Capacitive Reactance = 1 over the product of 'two times PI (i.e., 3.14) times frequency in hertz times capacitance in farads'. A behaviour opposite to inductors. Reactance (opposition) is not influenced by the amplitude of the applied voltage. If frequency goes up, capacitive reactance goes down. Intuitively, the more frequent the change of polarity (AC changes polarity every half-cycle), the more incessant becomes the charge/discharge current, current never seems to stop, less apparent opposition to current flow.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Reactance is opposition. XC = 1 over ( 2 * PI * f * C ). Capacitive Reactance = 1 over the product of 'two times PI (i.e., 3.14) times frequency in hertz times capacitance in farads'. A behaviour opposite to inductors. Reactance (opposition) is not influenced by the amplitude of the applied voltage. If frequency goes up, capacitive reactance goes down. Intuitively, the more frequent the change in polarity (AC changes polarity every half-cycle), the more incessant becomes the charge/discharge current, current never seems to stop, less apparent opposition to current flow.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Impedance (Z) is measured in ohms. It is the combined effect of reactance(s) and resistance. Resistance affects DC and AC equally. Reactance is a property only present under AC. [ DC = direct current, AC = alternating current ]. Impedance (Z) can also be seen as the ratio of voltage to current in AC circuits: Z = E / I. Generally, high impedance circuits function at high voltages and low currents, while low impedance circuits use low voltages at high currents.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Impedance (Z) is measured in ohms. It is the combined effect of reactance(s) and resistance. Resistance affects DC and AC equally. Reactance is a property only present under AC. [ DC = direct current, AC = alternating current ]. Impedance (Z) can also be seen as the ratio of voltage to current in AC circuits: Z = E / I. Generally, high impedance circuits function at high voltages and low currents, while low impedance circuits use low voltages at high currents.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Reactance is opposition. XL = 2 * PI * f * L. Inductive reactance = two times PI (i.e., 3.14) times frequency in hertz times inductance in henries. Reactance (opposition) is not influenced by the amplitude of the applied voltage. If frequency goes up, inductive reactance goes up. Intuitively, the higher the frequency (i.e., rate of change), the more significant become the counter-currents induced in adjacent turns.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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The coil (inductor) when dealing with an offending radio signal: chokes off radio frequency (high reactance), but passes audio frequencies (low reactance). Recall that the opposition of a coil to AC current flow (inductive reactance) grows as frequency increases.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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The bypass capacitor must provide a low impedance path for an offending signal without affecting lower frequency signals: low reactance for radio frequency, high reactance for audio. Recall that the opposition of a capacitor to AC current flow (capacitive reactance) decreases as frequency goes up.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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The bypass capacitor must provide a low impedance path for an offending signal without affecting lower frequency signals: low reactance for radio frequency, high reactance for audio. Recall that the opposition of a capacitor to AC current flow (capacitive reactance) decreases as frequency goes up.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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The coil (inductor) when dealing with an offending radio signal: chokes off radio frequency (high reactance), but passes audio frequencies (low reactance). Recall that the opposition of a coil to AC current flow (inductive reactance) grows as frequency increases.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

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Reactance is opposition. XL = 2 * PI * f * L. Inductive reactance = two times PI (i.e., 3.14) times frequency in hertz times inductance in henries. Reactance (opposition) is not influenced by the amplitude of the applied voltage. If frequency goes up, inductive reactance goes up. Intuitively, the higher the frequency (i.e., rate of change), the more significant become the counter-currents induced in adjacent turns.

Original copyright; explanations transcribed with permission from Francois VE2AAY, author of the ExHAMiner exam simulator. Do not copy without his permission.

Tags: none