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To date, this is my most successful design. It is powered by an Atmel 8535, which means you can write fairly complex applications (8Kb flash). It has 4 tactical sensors, two eyes based on LDR resistors placed in a tube to have directional sensory, one RC5 Ir diode to be able to command the robot using a standard remote control unit and expansion bus on the top of the vehicle (Wireless module has been build).

"MicroRover"

Introduction

This small robot measures 75x38x50 mm, and is powered by two geared DC motors (ref#0). Four NiMH cells, delivering 120mAh at 1.2 V each provide enough power for approximately 1 hour autonomy. The brains of the robot are made up of a AT90LS8535 running at 4MHz in a TQFP package. The motors are driven by a 74AC244, an octal buffer/line driver which I used to make 2 H-bridges.

The robot has 8 sensors; 4 touch sensors on each corner, two directional LDR light sensors, one IR sensor (TSOP1736, RC5 type) and one proprioceptive sensor indicating battery status. This sensor package seems to be enough to provide for rather intelligent behavior.

The robot has a tank like locomotion. I've grown fond of this type of locomotion as it provides traction on all wheels. Also, I really enjoy the skid steering.

The robot has 4 connectors; one to charge the batteries, another one to program the robot, a serial connector and one expansion bus, exposing 8 data lines, from which 4 our ADC capable. I've build a wireless module to put on top of the robot. More on that will follow, sufficient to say now that it uses a BIM2 transceiver from radiometrix. I've experienced some troubles getting the PCB ready for the PC host adapter, as I had to redo the PCB for a few times to get it _right_. Hence, I put the wireless module on a lower priority.

"Preview image of the video"

Link to a small video (ref#1)

Schematic

"microrover schematic" {: dither="no" }

Sample code

The next code is a small BASCOM program that can drive the MicroRover. It is a simple subsumption architecture, using 3 behaviors; photofobic, wandering and react to touch.

Subsumption

"subsumption1" {: dither="no" }

You can read more about the subsumption architecture in the following wikipedia article about subsumption architecture (ref#2).

Code

:::basic

'(

r o v e r

---------

test code for rover based on 8535

')

M1A alias portd.7

M1B alias portd.6

M2A alias portc.1

M2B alias portc.0

BAT_CONTROL alias portc.4

const BAT_LEVEL = 5

TOUCH_BACK_LEFT alias pinc.5

TOUCH_BACK_RIGHT alias pinc.6

TOUCH_FRONT_LEFT alias pind.4

TOUCH_FRONT_RIGHT alias pind.5

EYE_CONTROL alias portc.7

const EYE_LEFT = 7

const EYE_RIGHT = 6

config Adc = Single , Prescaler = Auto

config debounce = 10

config Rc5 = pind.2

enable interrupts

' -- subroutine declarations

declare sub forward

declare sub backward

declare sub turn_left

declare sub turn_right

declare sub halt

declare sub diagnostics

declare sub motor

declare sub touch

declare sub photofoob

declare sub wander

' -- variable declarations

dim eye_l as Word

dim eye_r as Word

dim bat as Word

dim tch_bl as bit

dim tch_br as bit

dim tch_fl as bit

dim tch_fr as bit

dim c as byte

dim rc5_address as byte, rc5_command as byte

dim temp as byte

dim i as integer

' -- define behaviours

' . global settings

const BEAT = 50 ' -- unit of execution time

' a behaviour will use this as a standard

' time tick for action

const BEAT2 = 100

' . touch

dim touch_state as byte ' - state of the 'touch' behaviour

dim touch_dur as word ' - duration

dim touch_turn as byte

dim touch_direction as byte

' . motor

dim motor_vector as byte ' - drive vector for motors

const M_STOP = 0

const M_FORWARD = 1

const M_RIGHT = 2

const M_BACK = 3

const M_LEFT = 4

' . photofoob

dim photofoob_state as byte

dim photofoob_turn as byte

dim photofoob_dur as word

dim photofoob_offset as word

' . wander

dim wander_state as byte

dim wander_turnorgo as bit

dim wander_dur as long

const WANDER_RUN = 200*BEAT

' -- main

DDRD = &B11001011

DDRC = &B10011111

start Adc

set PORTC.6

set PORTC.5

set PORTD.5

set PORTD.4

wander_state = 0

photofoob_state = 0

photofoob_offset = 50

touch_state = 0

motor_vector = 0

do

' pull in data from the sensors

gosub latch_sensors

' behaviours

photofoob

wander

touch

' override controls now with RC5 commands

' gosub remote

' motor control

motor

temp = inkey()

if temp > 0 then

call diagnostics

end if

loop

' -- control the engine

sub motor

select case motor_vector

case M_STOP:

call halt

case M_FORWARD:

call forward

case M_BACK:

call backward

case M_LEFT:

call turn_left

case M_RIGHT:

call turn_right

end select

end sub

' -- Pull the sensory data into globals

latch_sensors:

set EYE_CONTROL

waitus 250

c = EYE_LEFT

eye_l = getadc(c)

c = EYE_RIGHT

eye_r = getadc(c)

reset EYE_CONTROL

set BAT_CONTROL

waitus 250

c = BAT_LEVEL

bat = getadc(c)

reset BAT_CONTROL

tch_bl = TOUCH_BACK_LEFT

tch_br = TOUCH_BACK_RIGHT

tch_fl = TOUCH_FRONT_LEFT

tch_fr = TOUCH_FRONT_RIGHT

return

' --

remote:

getrc5( rc5_address, rc5_command)

if rc5_address <> 255 then

rc5_command = rc5_command and &B10111111

select case rc5_command

case 32:

motor_vector = M_FORWARD

case 33:

motor_vector = M_BACK

case 16:

motor_vector = M_RIGHT

case 17:

motor_vector = M_LEFT

case 12:

motor_vector = M_STOP

case 14:

call diagnostics

end select

end if

return

' -- print out some diagnostics

sub diagnostics

print "el "; eye_l

print "er "; eye_r

print "ba "; bat

print "wd "; wander_dur

print "bl "; tch_bl

print "br "; tch_br

print "fl "; tch_fl

print "fr "; tch_fr

print "vc "; motor_vector

end sub

' -- move forward

sub forward

set M1A

reset M1B

set M2A

reset M2B

end sub

' -- move backward

sub backward

reset M1A

set M1B

reset M2A

set M2B

end sub

' -- turn right

sub turn_right

set M1A

reset M1B

reset M2A

set M2B

end sub

' -- turn left

sub turn_left

reset M1A

set M1B

set M2A

reset M2B

end sub

' -- stop rover

sub halt

reset M1A

reset M1B

reset M2A

reset M2B

end sub

' ------------------------------------------------------------------------

' -- B E H A V I O U R S

' ------------------------------------------------------------------------

sub touch

' we always react to touch, even when processing a touch

if tch_bl = 0 then

touch_turn = M_RIGHT

touch_direction = M_FORWARD

touch_state = 1

touch_dur = BEAT2

end if

if tch_br = 0 then

touch_turn = M_LEFT

touch_direction = M_FORWARD

touch_state = 1

touch_dur = BEAT2

end if

if tch_fl = 0 then

touch_turn = M_RIGHT

touch_direction = M_BACK

touch_state = 1

touch_dur = BEAT2

end if

if tch_fr = 0 then

touch_turn = M_LEFT

touch_direction = M_BACK

touch_state = 1

touch_dur = BEAT2

end if

select case touch_state

case 0:

case 1:

motor_vector = touch_direction

if touch_dur = 0 then

touch_state = 2

touch_dur = BEAT2

end if

decr touch_dur

case 2:

motor_vector = touch_turn

if touch_dur = 0 then

touch_state = 0

touch_dur = 0

motor_vector = M_STOP

end if

decr touch_dur

end select

end sub

sub photofoob

select case photofoob_state

case 0:

' we kick into action when it is too light

if eye_l > photofoob_offset or eye_r > photofoob_offset then

photofoob_turn = M_LEFT

if eye_l > eye_r then

photofoob_turn = M_RIGHT

end if

photofoob_dur = BEAT

photofoob_state = 1

end if

case 1:

motor_vector = photofoob_turn

if photofoob_dur = 0 then

photofoob_state = 2

photofoob_dur = BEAT

end if

decr photofoob_dur

case 2:

motor_vector = M_FORWARD

if photofoob_dur = 0 then

photofoob_state = 0

motor_vector = M_STOP

end if

decr photofoob_dur

end select

end sub

sub wander

select case wander_state

case 0:

i = rnd(100)

i = i * 10

wander_dur = i * BEAT

wander_state = 1

case 1:

if wander_dur = 0 then

wander_state = 2

wander_turnorgo = 0

wander_dur = WANDER_RUN

end if

decr wander_dur

case 2:

if wander_turnorgo = 0 then

motor_vector = M_LEFT

if eye_l < eye_r then

motor_vector = M_RIGHT

end if

else

motor_vector = M_FORWARD

end if

if wander_dur = 0 then

wander_state = 0

motor_vector = M_STOP

end if

decr wander_dur

i = wander_dur mod BEAT2

if i = 0 then

toggle wander_turnorgo

end if

end select

end sub

The most primitive behavior is reaction to touch, this behavior can subsume over all other tasks. Most of the time, the robot is in a photofobic state, it will wander of to a dark place by constantly steering in the most dark direction. Light values are measured by an ADC channel on the AVR MPU. Whenever the robot reads the light intensity on its two eyes, it'll power the LDRs for a short time and - enough time for the ADC to setlle - and then read out the intensities (lines 149-155). This intermittent powering of the LDRs prevent battery drain. When the light intensities falls below a certain threshold, the robot will sit happy until light levels are up again.

Whenever an object hits one of the touch sensors, the robot will try to turn away from the obstacle by reversing its direction and turning towards the opposite site of the touched sensor. If both front or aft sensors are touched, the robot just reverses direction, no turn takes place (lines 250-302).

After a random time, the rover wants to wander around. This wandering behavior has priority over its photofobic state, but lower priority than the touch behavior. When in wandering state, the robot is attracted to light. It will run of as fast as it can to brightest spot it can detect. The time that the robot wanders around is determined by another random number. I've found that this wandering state is very usefull for the robot to roam the complete room. If the wandering behavior would not be included, the robot would simply drive to a dark spot and sit there until light intensities are high enough to get it moving again. With the wandering behavior, though, the robot can sit idle on a dark spot, come to life again and run straight into the light. When the wandering behavior shuts down, the robot gets a panic attack and hurries to the nearest dark spot it can find (lines 337-374).

Lines 171 to 190 implement code to steer the robot via a TV remote control. The remote control can steer the robot in all 4 directions. Moreover, it can let the robot dump its internal state to its serial port. This can come in handy when debugging.

Although the battery level is already measured (lines 157-161) , by comparing a constant voltage drop over 3 diodes against the battery voltage, nothing is done with it. The idea is to have a small hardware extension on the robot that allows it to charge automatically. This extension can be made of just two wires that can connect to a docking station, composed of two metal plates. The idea is to let the robot navigate to a charging station as soon as battery levels drop below a certain treshhold. Moreover, the idea is to use the LDRs to navigate to the charging station. A LED, pulsating at a low enough frequency can be easily detected by the LDRs. The LED would indicate the position of the charging station.

Some images

"simg0823_640x480"

"simg0818_640x480"

"simg0822_640x480"

[=> images/simg0816_640x480.jpg "simg0816_640x480"

"simg0814_640x480"

Table of refs:

geared DC motors1

Link to a small video1

wikipedia article about subsumption architecture1

---
(C) 2023 Johan Van den Brande, brewed by trash.make.site