Dattorro industry scheme

Dattorro block diagram

The Dattorro industry scheme is a digital system used to implement a wide range of delay-based audio effects for digital signals. It was proposed by Jon Dattorro.^[1] The common nature of these effects allows to produce an output signal as the linear combination of (dynamically modulated) delayed replicas of the input signal. The proposed scheme allows to implement such effects in a compact form, only using a set of three parameters to control the type of effect.

The Dattorro industry scheme is based on digital delay lines and to ensure a proper resolution in the time domain, it leverages fractional delay lines, thus avoiding discontinuities.^[2]

The effects that this scheme is able to produce are: echo, chorus, vibrato, flanger, doubling, white chorus. These effects are characterized by a nominal delay, a modulating function for the delay and the depth of modulation.^[3]

Delay line interpolation

Consider continuous time signal ${\displaystyle y(t)}$. The ${\displaystyle \tau }$-delayed version of such signal is ${\displaystyle y(t)=x(t-\tau )}$. Considering the signal in the discrte time domain (i.e., sampling it with sampling frequency ${\displaystyle F_{s}}$ at ${\displaystyle n=tF_{s}}$), we obtain ${\displaystyle y[n]=x[n-M]}$. The delay line can then be described in terms of the Z-transform of the discrete time signal as

${\displaystyle Y(z)={\mathcal {Z}}\{y\}(n)=z^{-M}X(z)=H_{M}(z)X(z)}$.

When going back in the time domain exploiting the inverse Z-transform, this corrsponds to ${\displaystyle h_{m}[n]=\delta [n-M]}$, where ${\displaystyle \delta [\cdot ]}$ is the Dirac delta. The former equation holds for ${\displaystyle D\in \mathbb {N} }$ but for the implementation we need a fractional delay, meaning ${\displaystyle D=\lfloor D\rfloor +(D-\lfloor D\rfloor )=M+d,\quad d\in \mathbb {R} ,\ 0<d<1}$. In this case, interpolation is required to reconstruct the value of the signal that lies between two samples.^[4] One can resort to the preferred interpolation technique, e.g., Lagrange interpolation,^[5] or all-pass interpolation.^[6]

Linear interpolator block diagram

All-pass interpolator block diagram

Block diagram

The output of the delay block ${\displaystyle H_{M}(z)=z^{-M}}$ is noted above and below as rarely it is taken from the last sample of the tap but instead it changes dynamically. Considering the end to end structure, we can write the filter as:

Dattorro scheme

$${\displaystyle Y(z)=H(z)X(z)={\frac {b+f_{f}z^{-D(t)}}{1+z^{-D(t)}f_{b}}}X(z)}$$

Setting the coefficients according to the desired effect results in a change of the filter topology. For example, setting the feedback to 0 results in a FIR filter, whereas, if the coefficients are set to be equal, we approximate an all-pass filter.^[1]

Guitar string ${\displaystyle E_{2}}$ sound

Echo

Vibrato

Flanger

Doubling

Chorus effect

White chorus

Effects

All the effects can be obtained by changing the parameters of the Dattorro system and by setting the delay ranges according to the following table. Delay values are expressed in milliseconds.^[1]

Effect	Onset	Nominal	Range End
Vibrato	0	Minimal	5
Flange	0	1	10
Chorus	1	5	30
Doubling	10	20	100
Echo	50	80	${\displaystyle \infty }$

Vibrato

Vibrato is a small quasi-periodic change in pitch of a tone. It's more of a technique than an effect per se but can be added to any audio signal.^[7] The delay is modulated with a low frequency sinusoidal function and no mix of the direct path of the signal is considered.

Chorus

The chorus is an effect which tries to emulate multiple independent voices playing in unison. This effect is made as a linear combination of the input signal (dry signal) and a dynamically delayed version of the input (wet signal).^[8]

Flanging

The flanging effect originated with tape machines. This effect was created by mixing two tape machines set to play the same track but one of them is slowed down. This produces a lowering in pitch and a delay of the slow track. The process is then repeated with the other track reabsorbing the accumulated delay.^[9] This effect is very similar to chorus and the main difference is due to the delay range. Chorus usually has longer delay, larger depth and lower modulating frequency.^[7]

White chorus

White chorus is a modification to the standard chorus effect aimed at reducing the aberrations introduced by the forward path. The change consists in adding a negative feedback path with a different and fixed tap point in order to obtain an approximation of an all-pass configuration.^[1]

Doubling

When the system is used without feedback we achieve doubling. This effect is analogous to that of the Leslie speaker, a particular kind of speaker consisting of a rotating chamber in front of the bass loudspeaker and rotating cones above the treble loudspeakers .^[10]

Knob settings

Effect	Blend ${\displaystyle b}$	Feedforward ${\displaystyle f_{f}}$	Feedback ${\displaystyle f_{b}}$	Modulation type D(t)
Vibrato	0.0	1.0	0.0	sinusoid
Flanger	0.7071	0.7071	${\displaystyle -}$0.7071	sinusoid
White chorus	0.7071	1.0	0.7071	low pass noise
Chorus	1.0	0.7071	0.0	low pass noise
Doubling	0.7071	0.7071	0.0	low pass noise
Echo	1.0	${\displaystyle \ll }$1.0	<1.0	none

Pseudocode

The filter can be implemented in software or hardware. In the following is the pseudocode for a software Dattorro system.

function dattorro is
    input: x,                                   # input signal
           Fs,                                  # sampling frequency
           depth,                               # modulation depth
           freq,                                # LFO frequency
           b,                                   # blend knob
           ff,                                  # feedforward knob
           fb,                                  # feedback knob
           mod                                  # modulation type
    output: y                                   # signal with FX applied

    depth_samples = depth·Fs                    # compute delay in samples
    if mod is sinusoid                          # compute delay sequence
        delay_seq = depth_samples*(1 + sin(2·${\displaystyle \pi }$·freq*t))
    else mod is noise
        lowpass_noise = noise_gen()             # generate white noise and low-pass filter it
        delay_seq = depth_samples + depth_samples·lowpass_noise
    
    for each n of the N samples

        d_int = floor(delay_seq(n))             # integer delay
        d_frac = delay_seq(n) - d_int           # fractional delay        
        h0 = (d_frac - 1)·(d_frac - 2)/2        # first FIR filter coefficient
        h1 = d_frac·(2 - d_frac)                # second FIR filter coefficient
        h2 = d_frac/2·(d_frac - 1)              # third FIR filter coefficient
        
        x_d = delay_line(d_int + 1)·h0 + delay_line(d_int + 2)·h1 + delay_line(d_int + 3)·h2  # delay input                                       
        
        f_b = fb·x_d                            # delayed input feedback
        delay_line(2:L) = delay_line(1:L-1)     # delay line update
        delay_line(1) = x(i) - fb_comp
        
        f_f = ff·x_d                            # feedforward component
        blend_comp = b·delay_line(1)            # blend component

        y(n) = ff_comp + blend_comp             # compute output sample
  
    return y

See also

• Digital delay line
• Effects unit
• Filter design

References

1. Dattorro, Jon (1997). "Effect Design - Part 2: Delay-Line Modulation and Chorus". Journal of the Audio Engineering Society. 45 (10): 764–788.
2. Smith, Julius O.; Lee, Nelson (June 5, 2008), "Computational Acoustic Modeling with Digital Delay", Center for Computer Research in Music and Acoustics, retrieved 2007-08-21
3. Zolzer, Udo (2011). DAFX: Digital Audio Effects (PDF). John Wiley and Sons.
4. Laakso; Valimaki; Karjalainen (1996). "Splitting the unit delay [FIR/all pass filters design]". IEEE Signal Processing Magazine. 13 (1): 30–60. Bibcode:1996ISPM...13...30L. doi:10.1109/79.482137.
5. Rocchesso, Davide (2000). "Fractionally addressed delay lines". IEEE Transactions on Speech and Audio Processing. 8 (6): 717–727. arXiv:cs/0005022. doi:10.1109/89.876310. S2CID 9626440.
6. Hacthabiboglu, H.; Gunel, B.; Kondoz, A.M. (2006). "Interpolated Allpass Fractional-Delay Filters Using Root Displacement". 2006 IEEE International Conference on Acoustics Speed and Signal Processing Proceedings. Vol. 3. IEEE. pp. III–864–III-867. doi:10.1109/ICASSP.2006.1660791. ISBN 978-1-4244-0469-8. S2CID 234579.
7. McPherson, Joshua D. Reiss, Andrew (2015-01-13). Audio Effects: Theory, Implementation and Application. Boca Raton: CRC Press. doi:10.1201/b17593. ISBN 978-0-429-09723-2.
8. Smith, Julius O. "Chorus effect".
9. Smith, Julius O. "Flanging".
10. Henricksen, Clifford A. "Unearthing The Mysteries Of The Leslie Cabinet".

Further reading

• ${\displaystyle H^{\infty }}$-optimal delay filters by Masaaki Nagahara and Yutaka Yamamoto
• Digital Audio Signal Processing by Udo Zolzer
• Dattorro, Jon, ed. 1988; The Implementation of Recursive Digital Filters for High-Fidelity Audio; (JAES Volume 36 Issue 11),

External links

• Introduction to Digital Filters by Julius Smith
• Discrete-Time Modeling of Acoustic Tubes Using Fractional Delay Filters by Valimaki Vesa
• Time varying delay effects by Julius Smith