A television channel is assigned the frequency range from 54 MHz to 60 MHz. A series RLC tuning circuit in a TV receiver resonates in the middle of this frequency range. The circuit uses a 21 pF capacitor.

A. What is the value of the inductor? B. In order to function properly, the current throughout the frequency range must be at least 50% of the current at the resonance frequency. What is the minimum possible value of the circuit's resistance? Express your answers to two significant figures and include the appropriate units.

Question

Jimmuy

Physics

6 June, 10:38

A television channel is assigned the frequency range from 54 MHz to 60 MHz. A series RLC tuning circuit in a TV receiver resonates in the middle of this frequency range. The circuit uses a 21 pF capacitor.

A. What is the value of the inductor? B. In order to function properly, the current throughout the frequency range must be at least 50% of the current at the resonance frequency. What is the minimum possible value of the circuit's resistance? Express your answers to two significant figures and include the appropriate units.

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Answers (1)

Know the Answer?

Marquis · Answer 1

A.) L = 0.37 μH B) 7.61 Ω

Explanation:

A) At resonance, the circuit behaves like it were purely resistive, so the reactance value must be 0.

So, the following condition must be met:

ω₀*L = 1 / (ω₀*C) ⇒ ω₀² = 1/LC

We know that, for a sinusoidal source, there exists a fixed relationship between the angular frequency ω₀ and the frequency f₀, as follows:

ω₀ = 2*π*f₀

⇒ (2*π*f₀) ² = 1 / (L*C)

Replacing by the givens (f₀, C), we can solve for L:

L = 1 / ((2*π*f₀) ²*C) = 1 / (2*π*57*10⁶) ² Hz²*21*10⁻¹² f = 0.37 μH

b) At resonance, the current can be expressed as follows:

I₀ = V/Z = V/R

We need to find the minimum value of R that satisfies the following equation:

I = 0.5 I₀ = 0.5 V/R = V/Z

⇒ 0.5/R = 1/√ (R²+X²)

Squaring both sides, we have:

(0.5) ²/R² = 1 / (R²+X²)

⇒ 0.25 (R²+X²) = R² ⇒ R² = X² / 3

We need to find the value of R that satisfies the requested condition througout the frequency range.

So, we need to find out the value of the reactance X in the lowest and highest frequency, as follows:

Xlow = ωlow * L - 1 / (ωlow*C)

⇒ Xlow = ((2*π*54*10⁶) * 0.37*10⁻⁶) - 1 / ((2*π*54*10⁶) * 21*10⁻¹²) = - 14.81Ω

Xhi = ωhi * L - 1 / (ωhi*C)

⇒ Xhi = ((2*π*60*10⁶) * 0.37*10⁻⁶) - 1 / ((2*π*60*10⁶) * 21*10⁻¹²) = 13.18Ω

For these reactance values, we can find the corresponding values of R as follows:

Rlow² = Xlow²/3 = (-14.81) ²/3 = 75Ω² ⇒ Rlow = 8.55 Ω

Rhi² = Xhi² / 3 = (13.18) ²/3 = 56.33Ω² ⇒Rhi = 7.61 Ω

The minimum value of R that satisfies the requested condition is R = 7.61ΩΩ.