Modulation Index Calculator
Convert modulation index between units instantly. Includes conversion tables, common equivalents, and calculation formulas.
Formula
AM: m = Am/Ac | FM: beta = delta_f / fm
For AM, divide message amplitude by carrier amplitude. For FM, divide frequency deviation by modulating frequency. AM efficiency = m^2/(2+m^2). Carson bandwidth = 2*fm*(beta+1).
Worked Examples
Example 1: AM Radio Broadcast Modulation
Problem: A carrier has amplitude 10V and the message signal has amplitude 7V. Find the AM modulation index.
Solution: Modulation Index (m) = Message Amplitude / Carrier Amplitude\nm = 7 / 10 = 0.7 (70%)\nEfficiency = 0.7^2 / (2 + 0.7^2) = 0.49 / 2.49 = 19.68%\nTotal power ratio = 1 + 0.49/2 = 1.245
Result: m = 0.7 (70%), efficiency = 19.68%, power ratio = 1.245
Example 2: Commercial FM Broadcasting
Problem: FM broadcast with 75 kHz deviation and 15 kHz audio bandwidth. Find the modulation index.
Solution: Modulation Index (beta) = Frequency Deviation / Message Frequency\nbeta = 75 / 15 = 5\nCarson bandwidth = 2 * 15 * (5 + 1) = 180 kHz\nNumber of significant sidebands = 6 pairs
Result: beta = 5 (wideband FM), Carson BW = 180 kHz
Frequently Asked Questions
What is the modulation index?
The modulation index is a dimensionless parameter that describes how much the carrier signal is varied by the modulating (message) signal. For amplitude modulation (AM), it is the ratio of the message amplitude to the carrier amplitude. For frequency modulation (FM), it is the ratio of the frequency deviation to the modulating frequency. A higher modulation index means more information bandwidth but also more spectrum usage.
What happens when AM modulation index exceeds 1?
When the AM modulation index exceeds 1 (over 100%), the signal is said to be overmodulated. This causes distortion because the carrier envelope crosses zero and inverts, making it impossible for a simple envelope detector to correctly recover the original message. Overmodulation produces spurious frequency components that cause adjacent channel interference. Practical AM transmitters include limiting circuits to prevent the modulation index from exceeding 1.
How does FM modulation index affect bandwidth?
The FM modulation index directly determines the bandwidth required for transmission. According to Carson's rule, the approximate bandwidth equals 2 * (frequency deviation + message frequency), or equivalently 2 * fm * (beta + 1) where beta is the modulation index. A higher modulation index produces more sideband pairs, increasing bandwidth but also improving signal-to-noise ratio. Narrowband FM (beta less than 0.5) has bandwidth similar to AM, while wideband FM (beta greater than 1) provides superior noise performance.
What is the efficiency of AM modulation?
AM efficiency measures the fraction of total transmitted power that carries useful information. The formula is efficiency = m^2 / (2 + m^2), where m is the modulation index. At 100% modulation (m=1), only 33.3% of the power is in the sidebands carrying information, while 66.7% is wasted in the carrier. This low efficiency is a major drawback of conventional AM, which led to the development of suppressed-carrier and single-sideband modulation techniques.
What formula does Modulation Index Calculator use?
The formula used is described in the Formula section on this page. It is based on widely accepted standards in the relevant field. If you need a specific reference or citation, the References section provides links to authoritative sources.
Is Modulation Index Calculator free to use?
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