Discrete Robot

This simple robot, which
responds to light and avoids obstacles, can be built without using a
microcontroller, programmer or PC. The only ‘special’ component in the
circuit is a window discriminator (a fancy version of a window
comparator). Resistors R1 and R2 in combination with light-dependent
resistors LDR1 and LDR2 form a voltage divider (with the current being
limited by R1 and R2 for bright light). Window discriminator TCA965
compares the mid-point voltage with an upper threshold value (adjustable
using P1) and a lower threshold value (adjustable using P2). Outputs
AU, AI, AO, and AA go High if the voltage lies below, inside, above or
outside this window, respectively; otherwise they remain Low.

Output AA switches transistor T1, which drives the right-hand motor.
The light-dependent resistors can be attached on the left and right
sides of the vehicle, or at the front and rear. This causes the robot to
turn to the right, due to the motor on one side being stopped, until
the desired lighting relationship is restored. The vehicle will then
continue to travel in a straight line until the lighting relationship
again changes, at which point it will again turn, and so on. You can
experiment with various behaviour patterns by using the other outputs of
the window discriminator. If a transistor is provided for each of the
AU and AO outputs of the TCA965, the robot can be made to travel toward
or away from a light source, depending on the connections.

Using the window discriminator, the robot will operate under the
rules of a three-point controller (left, straight ahead, or right). If
you fit the light-dependent resistors in a box under the vehicle
together with a light source, you can try to have the robot follow a
black line on a white background. A reflective IR sensor enables the
robot to respond to obstacles. This not as simple as it might seem,
since the Sharp IS471 operates the IR LED with
pulsed light and uses sophisticated detection processing. When an
obstacle is detected, the output (pin 2) goes Low and blocks transistor
T2. This causes the motor to stop, and the vehicle will rotate about the
stationary wheel until the obstacle is no longer in its path.

Discrete Robot Circuit

Discrete Robot Circuit Diagram

The sensitivity of the IS471 can be set using P3. As its range is
only around 10–15 cm, the vehicle must not travel too quickly, since
otherwise it will not be able to avoid obstacles in time. This part of
the circuit is also open for experimentation. If a relatively large and
fast robot requires an obstacle detector (or isn’t fitted with the
IS471), an ultrasonic detector can also be used. Suitable complete
construction kits are available from Conrad, for example. You can also
fit a suitable mechanical pushbutton switch mounted on a flexible rod.
The obstacle detector can also drive a warning buzzer or a lamp; the
circuit leaves lots of room for your own ideas. The circuit works over a
wide range of supply voltages from 4.5 to 16 V.

If larger motors are used, transistors with increased power-handling
capacity and heavier batteries are necessary. The author connected two
4.8-V rechargeable batteries in series and used BC388 transistors as
drivers for Lego micromotors. You can build the robot entirely according
to what you have in your parts box. The mechanical elements can also be
freely selected, but they partially determine the behaviour and
operation of the robot. The author’s robot is made from a Lego chassis
with a prototyping board holding the circuitry attached using elastic
bands. The motors are fitted on the left-hand and right-hand sides. The
third wheel at the front can turn freely.

One problem must be mentioned: if an obstacle is detected while an
incorrect lighting relationship is present, the vehicle remains
standing. In this case, a bit of logic could be added to cause both
motors to rotate in reverse. However, that would require directional
switches for the motors or motor driver ICs (L293D). The simple circuit
would become more complicated and larger, and at some point you would
end up using a microcontroller after all – but that’s just the point of
the story.

Author: Gerhard Nöcker – Copyright: Elektor Electronics

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