Music notes

Ode To Joy

This is a handy quicky test:

int odeToJoy[] = { F2S,QUARTER, F2S,QUARTER, G2 ,QUARTER, A3 ,QUARTER,
A3 ,QUARTER, G2 ,QUARTER, F2S,QUARTER, E2 ,QUARTER,
D2 ,QUARTER, D2 ,QUARTER, E2 ,QUARTER, F2S,QUARTER,
F2S,DOTTED_QUARTER, E2,EIGHTH, E2,HALF,
F2S,QUARTER, F2S,QUARTER, G2 ,QUARTER, A3 ,QUARTER,
A3 ,QUARTER, G2 ,QUARTER, F2S,QUARTER, E2 ,QUARTER,
D2 ,QUARTER, D2 ,QUARTER, E2 ,QUARTER, F2S,QUARTER,
E2 ,DOTTED_QUARTER, D2,EIGHTH, D2,HALF,
E2 ,QUARTER, E2 ,QUARTER, F2S,QUARTER, D2 ,QUARTER,
E2 ,QUARTER, F2S,EIGHTH,  G2,EIGHTH, F2S,QUARTER, D2 ,QUARTER,
E2 ,QUARTER, F2S,EIGHTH,  G2,EIGHTH, F2S,QUARTER, E2 ,QUARTER,
D2 ,QUARTER, E2 ,QUARTER, A,QUARTER, REST,ETERNITY } ;

Digital filter

filter ( input, tunefactor, damping )
{
lowpass  += tunefactor * bandpass ;
highpass  = input - lowwpass  - damping * bandpass ;
bandpass += tunefactor * highpass ;
notch     = lowpass + highpass ;  // Optional!
}

Another Low-pass filter

Calculate each output-signal sample as the sum of the input signal and the previous output signal with scaling. This defines a low pass single-pole filter:

Yn = Xn.(1-T) + Yn-1.T

Where:

• Xn is the input
• Yn is the output, Yn–1 is the output from the previous loop.
• T is our frequency control: 0<T<1

Physically, T is the amount of decay between adjacent output samples for a 'step' input. You can directly specify the value of T or derive it from the time constant of the filter, d, which is the number of samples it takes the output to rise to 63.2% of the steady-state level for a lowpass filter. T=e–1/d.

Instead of multiplying by 1–T, it is more convenient to divide by the F=1/(1–T):

Yn = Yn–1 + (Xn–Yn–1)/F

You can determine the digital filter’s parameters using the following steps:

1. Choose a value for F. Suppose F==8, so you can do a right-shift instead of a divide.
2. Calculate T = 1–1/F = 1–1/8 = 0.875.
3. Calculate the time constant as d = –1/ln(T) = –1/ln(0.875) = 7.49 samples.
4. Multiply that into your sample rate: 22000/7.49 = 2.9kHz

Here are some sample values for a 22000Hz sample rate:

 Freq. (Hz) t F Freq. (Hz) t F Freq. (Hz) t F Freq. (Hz) t F 22000 0.367 1.58 21000 0.384 1.62 20000 0.402 1.67 19000 0.421 1.72 18000 0.441 1.78 17000 0.461 1.85 16000 0.483 1.93 15000 0.505 2.02 14000 0.529 2.12 13000 0.553 2.24 12000 0.579 2.37 11000 0.606 2.54 10000 0.634 2.73 9000 0.664 2.98 8000 0.695 3.28 7000 0.727 3.66 6000 0.761 4.18 5000 0.796 4.91 4000 0.833 6.01 3000 0.872 7.84 2000 0.913 11.5 1000 0.955 22.5 900 0.959 24.9 850 0.962 26.4 800 0.964 27.9 750 0.966 29.8 700 0.968 31.9 650 0.970 34.3 600 0.973 37.1 550 0.975 40.5 500 0.977 44.4 450 0.979 49.4 400 0.981 55.4 375 0.983 59.1 350 0.984 63.3 325 0.985 68.2 300 0.986 73.7 275 0.987 80.4 250 0.988 88.5 225 0.989 98.4 200 0.990 110.0 175 0.992 126.0 149 0.993 147.0 100 0.995 219.0 75 0.996 292.0 50 0.997 440.0

Yet another

Summarized from this paper.

First order filter

(Similar to Yn = Yn–1 + (Xn–Yn–1)/F as described above)

Y = X.B0 + Z.B1 - Z.A1
Z = Y
Z = X

Where:

• X is the input
• Y is the output

Second order filter

Y = X.B0 + Z.B1 + Z.B2 + Z.A1 + Z.A2
Z = Z
Z = Y
Z = Z
Z = X

The first order version is just this with B2 = A2 = 0.

Input parameters:

• Fc = cutoff frequency (Hz)
• Fs = sample rate (Hz)
• W = tan(pi.Fc/Fs)
• Q = quality factor
 Filter Parameters H(S) N B0 B1 B2 A1 A2 Lowpass 1st order 1/(S + 1) 1/(W + 1) W*N B0 0.0 N*(W-1) 0.0 Highpass 1st order S/(S + 1) 1/(W + 1) N -B0 0.0 N*(W-1) 0.0 Lowpass 2nd order 1/(S2 + S/Q + 1) 1/(W2 + W/Q + 1) N*W2 2*B0 B0 2*N*(W2 + 1) N*(W2 + W/Q + 1) Highpass 2nd order S2/(S2 + S/Q + 1) 1/(W2 + W/Q + 1) N -2*N B0 2*N*(W2 + 1) N*(W2 + W/Q + 1) Bandpass 2nd order (S/Q)/(S2 + S/Q + 1) 1/(W2 + W/Q + 1) N*W/Q 0.0 -B0 2*N*(W2 + 1) N*(W2 + W/Q + 1)

The first order lowpass or highpass section has a slope of 6dB/Octave, and the second order section has a slope of 12dB/Octave. If the better slope is required, you have to cascade several sections.

Butterworth

All stages of Butterworth filter have the same cutoff frequency Fc. The parameter which is different for the stages is the filter Q. Here is the table for Q for Butterworth up to 6-th order:

1. ---
2. 0.71
3. --- 1.0
4. 0.54 1.31
5. --- 0.62 1.62
6. 0.52 0.71 1.93

If the value of Q is skipped, it means this is a first order section. Otherwise it is a second order section.

LR consists of two identical Butterworth filters in series. Use the same table that is used for Butterworth filter design.

Bessel

Bessel design is a little bit more complicated, since not only Q but the Fc also differs from the stage to stage.

You should multiply the Fc for each stage by the following coefficients:

1. 1.00
2. 1.27
3. 1.32 1.45
4. 1.60 1.43
5. 1.50 1.76 1.56
6. 1.90 1.69 1.60

The corresponding Q values are:

1. ---
2. 0.58
3. --- 0.69
4. 0.81 0.52
5. ---- 0.92 0.56
6. 1.02 0.61 0.51

If the value of Q is skipped, it means this is a first order section. Otherwise it is a second order section.

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