This is machine translation

Translated by Microsoft
Mouse over text to see original. Click the button below to return to the English verison of the page.

comm.FSKModulator System object

Package: comm

Modulate using M-ary FSK method


The FSKModulator object modulates using the M-ary frequency shift keying method. The output is a baseband representation of the modulated signal.

To modulate a signal using frequency shift keying:

  1. Define and set up your FSK modulator object. See Construction.

  2. Call step to modulate a signal according to the properties of comm.FSKModulator. The behavior of step is specific to each object in the toolbox.

    Note:   Starting in R2016b, instead of using the step method to perform the operation defined by the System object™, you can call the object with arguments, as if it were a function. For example, y = step(obj,x) and y = obj(x) perform equivalent operations.


H = comm.FSKModulator creates a modulator System object, H. This object modulates the input signal using the M-ary frequency shift keying (M-FSK) method.

H = comm.FSKModulator(Name,Value) creates an M-FSK modulator object, H, with each specified property set to the specified value. You can specify additional name-value pair arguments in any order as (Name1,Value1,...,NameN,ValueN).

H = comm.FSKModulator(M,FREQSEP,RS,Name,Value) creates an M-FSK modulator object, H. This object has the ModulationOrder property set to M, the FrequencySeparation property set to FREQSEP, the SymbolRate property set to RS, and the other specified properties set to the specified values.



Number of frequencies in modulated signal

Specify the number of frequencies in the modulated signal as a numeric positive integer scalar value that is a power of two. The default is 8.


Assume bit inputs

Specify whether the input is bits or integers. The default is false.

When you set this property to false, the step method input requires a numeric (except single precision data type) column vector of integer values between 0 and ModulationOrder–1. In this case, the input vector can also be of data type logical if ModulationOrder equals 2.

When you set this property to true, the step method input requires a double-precision or logical data type column vector of bit values. The length of this vector is an integer multiple of log2(ModulationOrder). This vector contains bit representations of integers between 0 and ModulationOrder–1.


Symbol encoding

Specify how the object maps an integer or group of log2(ModulationOrder) bits to the corresponding symbol as one of Binary | Gray. The default is Gray.

When you set this property to Gray, the object uses Gray-coded ordering.

When you set this property to Binary, the object uses natural binary-coded ordering. For either type of mapping, the object maps the highest frequency to the integer 0 and maps the lowest frequency to the integer M–1. In baseband simulation, the lowest frequency is the negative frequency with the largest absolute value.


Frequency separation between successive tones

Specify the frequency separation between successive tones in the modulated signal in Hertz as a positive, real scalar value. The default is 6 Hz. To avoid output signal aliasing, specify an output sampling rate, Fs = SamplesPerSymbol×SymbolRate, which is greater than ModulationOrder multiplied by FrequencySeparation.


Phase continuity

Specify if the phase of the output modulated signal is continuous or discontinuous. The default is true.

When you set this property to true, the modulated signal maintains continuous phase even when its frequency changes.

When you set this property to false, the modulated signal comprises portions of ModulationOrder sinusoids of different frequencies. In this case, a change in the input value can cause a discontinuous change in the phase of the modulated signal.


Number of samples per output symbol

Specify the number of output samples that the object produces for each integer or binary word in the input as a positive, integer scalar value. The default is 17.


Symbol duration

Specify the symbol rate in symbols per second as a positive, double-precision, real scalar. The default is 100. To avoid output signal aliasing, specify an output sampling rate, Fs = SamplesPerSymbol×SymbolRate, which is greater than ModulationOrder × FrequencySeparation. The symbol duration remain the same, regardless of whether the input is bits or integers.


Data type of output

Specify the output data type as one of double | single. The default is double.


cloneCreate M-FSK modulator object with same property values
getNumInputsNumber of expected inputs to step method
getNumOutputsNumber of outputs from step method
isLockedLocked status for input attributes and nontunable properties
releaseAllow property value and input characteristics changes
resetReset states of M-FSK modulator object
stepModulate using M-ary FSK method


expand all

Modulate and demodulate a signal using 8-FSK modulation with a frequency separation of 100 Hz.

Set the modulation order and frequency separation parameters.

M = 8;
freqSep = 100;

Create FSK modulator and demodulator System objects™ with modulation order 8 and 100 Hz frequency separation.

fskMod = comm.FSKModulator(M,freqSep);
fskDemod = comm.FSKDemodulator(M,freqSep);

Create an additive white Gaussian noise channel, where the noise is specified as a signal-to-noise ratio.

ch = comm.AWGNChannel('NoiseMethod', ...
    'Signal to noise ratio (SNR)','SNR',-2);

Create an error rate calculator object.

err = comm.ErrorRate;

Transmit one hundred 50-symbol frames using 8-FSK in an AWGN channel.

for counter = 1:100
    data = randi([0 M-1],50,1);
    modSignal = step(fskMod,data);
    noisySignal = step(ch,modSignal);
    receivedData = step(fskDemod,noisySignal);
    errorStats = step(err,data,receivedData);

Display the error statistics.

es = 'Error rate = %4.2e\nNumber of errors = %d\nNumber of symbols = %d\n';
Error rate = 1.40e-02
Number of errors = 70
Number of symbols = 5000


This object implements the algorithm, inputs, and outputs described on the M-FSK Modulator Baseband block reference page. The object properties correspond to the block parameters, except:

  • The Symbol set ordering parameter corresponds to the SymbolMapping property.

  • The SymbolRate property takes the place of the block sample rate capability.

Introduced in R2012a

Was this topic helpful?