Gakken SX-150 Panduan Perakitan dan Penggunaan - Halaman 4

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Operating Principles for
the Supplement's Synthesizer
The electric circuit in the supplement's Synthesizer is made up of a
combination of several circuits, each performing a simple operation.
Breaking the circuit down at this level would yield a configuration like
the one shown in the diagram below. Each of the blocks in the diagram
is referred to as a function block. The function blocks send requests to
each other to operate as a synthesizer. The requests that the function
blocks send to each other are called "signals." The signals used in the
supplement's Synthesizer can roughly be divided into two groups of
"sound signals" and "control signals."
This may seem a little bit difficult to understand, but it might be easier
if you think of it in terms of a piano. Roughly speaking, a piano is made
This part
corresponds to the
keyboard in a regular
synthesizer.
CV
Controller
Gate
* Here, this explains the
electrical characteristics
of the supplement's
electric circuit. Please
read from page 76 for a
more general
description of the
Structure of the supplement's Synthesizer
Synthesizer.
EXT.SOURCE
F/V
LFO
LFO WAVE
CV
Gate
TOUCH PEN
Controller
ATTACK
DECAY
PITCH ENV
Envelope generator
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Written by: Gan
up of the following:
A mechanism for generating sound
(Strings wound with piano wire Sounding board)
A mechanism for controlling how sound is released
(Keyboard/hammers/dampers)
The supplement's Synthesizer is similar to this, where sound signals
are the mechanism for generating sound and control signals are the
mechanism for controlling how the sound is released.
LFO WAVE
LFO
LFO RATE
CUTOFF
RESONANCE
VCO
VCF
Amplifier
PITCH ENV
Sound signal
Envelope
ATTACK
Control signal
DECAY
generator
Electric circuit diagram for the supplement's Synthesize
LFO RATE
VCO
CUTOFF
OUTPUT
POWER
RESONANCE
VCF
Amplifier
So, what happens inside the supplement's Synthesizer once you
actually start playing sounds using the electrode?
Once you start playing sounds with the electrode, the controller
generates two types of control signals. One signal is referred to as the
control voltage (CV) and is a signal for controlling the pitch of the
sound. The other signal is referred to as a gate and is a signal for
controlling ON/OFF for the sound. The CV changes according to the
position of the electrode on the slider panel. The gate turns ON when
the electrode touches the slider panel. These two signals are sent to a
voltage controlled oscillator (VCO). The VCO generates a sound signal
while the gate signal is ON. The pitch of the sound is determined by
the CV. If the output of the VCO is left as is, the only sound that will be
produced is a monotone buzzer-like "bzzz" sound. To change this, this
signal is passed through a voltage controlled filter (VCF). Of the
frequency components of the sound signal, the VCF removes only
those from the high pitch region and modifies the tone. At this time,
the sound is not only merely processed, but application of the filter is
changed in response to the amount of time that passes since the gate
starts working, and the tone of the sound is changed. This variation in
time is controlled by a signal from an envelope generator (EG). The EG
How a VCO works
A VCO is made up of a part for charging and discharging
capacitors, a part for monitoring the charging and
Sound
discharging, and a discharge switch. Charging is done
output
slowly at a speed that is based on the CV. Once a certain
amount of electricity has built up in the capacitor, the
monitoring part responds and turns on the discharge
switch, and the electricity is discharged at high speed.
The waveform output is a sawtooth wave.
How a VCF works
The basic structure of a VCF is formed of transistors
and capacitors. It may be easier to understand how
a VCF works if the transistors are replaced with
resistors. Capacitors have a property that allows
them to pass signals with high frequencies more
easily, so, only those components of high pitch are
removed, out of all of the sound signals. If the
control signals applied to the transistors are
changed, the frequency at which the filter begins
to be applied will change. Sounds passed through
the VCF become softer and the waveforms become
more rounded. This supplement employs a Korg
MS-20-type filter.
Power supply
Sound signal
input
Considering what would happen if the
transistors were replaced with resistors...
Sound signal input
Speaker
generates a signal with a pattern that decays after it has risen once in
response to the gate being turned ON. You can adjust the rising times
and the decay times and use the results to produce different kinds of
variant patterns. The supplement's Synthesizer has one more control
signal generator, which is referred to as an LFO. The LFO will make the
pitch of the sound of the VCO vibrate by generating a control signal
with a repeating pattern. You can produce a variety of sounds using
combinations of these functions.
η Waveform output from the VCO.
η Waveform output from the VCO.
In the low pitch
Control signal
Sound signal input
Sound signal output
region, signals do not
Sound signal
pass through the
output
capacitors very easily
Sound signals
pass through
unaffected
In the high pitch
Sound signal input
Sound signal output
region, signals pass
through the
Sound signal output
capacitors quite easily
Sound signals
decay
Analog Synthesizer
Discharge switch
Performing
charging
and
discharging
Monitoring
amount of
charge
Control signal
VCO output
How an Envelope Generator (EG) works
An envelope generator (EG) obtains a
control signal that varies with time through
charging and discharging of a capacitor.
Charging
Output
Discharging
Signal level
Time
Charging
Discharging
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