FUTURE KIT AVR1 SUPER SUMO ROBOT, Manual

Troubleshooting:
As the circuit has only a few components, the main 

cause of troubles will come from component 
misplacing and defaulted soldering. When found out 
that the circuit does not work, check for the proper 
component placings and various soldering points.

This super sumo can be controlled to attack or retreat and 

ready for battle with opponent. This robot is using the AVR 
microcontroller, so the user can re-program into IC for getting 
new applications.

Technical Specifications:
- Power supply : 2 AA batteries (not included).
- Consumption : 80mA.
- PCB dimensions : 2.54 x 1.18 in. (sensor board)
                                  2.54 x 2.70 in. (control board)

(1) ROBOT CONTROL CIRCUIT

How To Work: 
The circuit is composed of 2 major parts, sensor board and 

control board, as shown in Fig. 1.

Sensor board have 3 sets, in set as transmitter and receiver 

of infrared light. Transmitter part is consist TR4 and LED 
INF. VR4 is used for adjust the level of infrared light. Receiver 
part, when photo-transistor received infrared light from LED 
INF, causing voltage being passed through. The more reflected 
light will lessen the internal resistance and give bigger passing 
through voltage. Less reflected light will enlarge the internal 
resistance and give less passing through voltage. TR1 to TR3 
will work when the photo-transistor received infrared light.

Control board, at the heart of the circuit is the AVR 

microcontroller IC1. When below photo-transistor is not 
receiving infrared light (white ground), TR1 to TR3 are not 
working. IC1 will send the voltage to pin 12 and pin 15, 
causing both motor is running forward. If some below photo-
transistor received infrared light (black ground), motor is 
running backward. For center sensor, when sensor detects the 

object, IC1 will send the voltage pin 9 and pin 14, causing 
motor is rotate faster. IDE port is used for connect AVR 
programmer.

Circuit Assembling:
The PCB will be divided into two boards, AVR1-1 for 

circuit controlling and Body set for body, motor gear, wheel 
and battery holder assembling.

The AVR1-1 circuit assembling has been shown in Fig 2. It 

is recommended to assemble the circuit starting with a less 
height component i.e. diodes, resistor, electrolytic capacitors 
and transistors etc. Be careful while assembling and check for 
the matching of PCB poles and components before soldering as 
shown in Fig 3. For IDE port, press the pin of IDE port to be 
level with the black plastic before soldering. Use a max. 40W 
solder and soldering tin with a tin and lead ratio of 60/40 
together with a joint solution inside. Recheck the assembled 
circuit for your own confidence. Better use a lead sucker or a 
lead wire absorber in case of component misplacing to protect 
PCB from damage.

The Body set is to be assembled as shown in the next page.
Testing:
When the two circuit boards have been completely 

assembled. Insert four AA batteries into the battery holder. 
Then adjust VR1 to VR4 to the middle side and slide switch 
SW to "on" position. LED at sensor board is lighted on. Lay 
down the assembled robot on the test paper. Robot is running 
inside the black frame. The robot will backward and turn 
when below sensor detecting the black line. But front sensor 
detects the any object, the robot will run forward and running 
up the speed to bump.

VR1 to VR3 will act as sensitivity of photo-transistor. 

Adjust the left hand side for decreasing sensitivity and to the 
right hand side for increasing sensitivity. VR4 will act as level 
of infrared light.

SW1 is used for set the speed of robot. When you want to 

setting the speed, slide switch SW to "off" position then push 
and hold SW1. Slide SW to "on" position. Seeing LED at 
control board. LED will chasing step by step. LED1 is slowly 
speed and LED4 is higher speed.

FUTURE KIT

FUTURE KIT

HIGH QUALITY ELECTRONIC KITS

HIGH QUALITY ELECTRONIC KIT SET FOR HOBBY & EDUCATION

AVR1 SUPER SUMO ROBOT

CODE 1109

LEVEL 3

Figure 1. AVR1 Super Sumo Robot Circuit

Figure 2. AVR1-1 and SENSOR1-1 Circuit Board Assembling 

R

NOTE : 

For all IDE port to

insert the PC-board and solder

without trim leg.

RESISTOR

ELECTROLYTIC

CAPACITOR

TRANSISTOR

TRIMMER

POTENTIOMETER

Figure 3. Components Installing

Watch the polarity

!

RED LED

LED Infrared

(Blue Clear)

R .....

Ω

R

R

TR

TR

NPN

B

E

C

K

A

LED

K

A

LED

LED

VR .....K

Ω

1

2

3

VR

VR

C

+

+

C .....

µ

F

C

+

PNP

B

E

C

P H O T O   T R

P

I

I

P

D

K

A

K

A

K

A

K

A

L E D   I N F

DIODE

Photo-Transistor

(Black)

AVR1-1

ON                OFF

4001

C9012

9

C9013

8

C9013

7

C9013

10

C9012

6

C9013

5

C9013

3

C9013

4

C9012

1

C9012

2

+

47

µ

F

+

47

µ

F

1K

0.1

ATTINY2313

SW1

500

500

1K

1K

500

1K

1K

500

150

150

150

50

500

G

J

J

0.1

0.1

500

500

500

500

500

J

J

LED

3

A

K

LED

4

A

K

LED

1

A

LED

2

A

K

SENSOR2-1

N

+

P

I

1K

3K

500

1K

3K

1K

10

C9013

4

C9013

3

C9013

1

LED

A

K

VR1

L

VR3

R

VR4 I

VR2

N

3K

1K

C9013

2

http://www.futurekit.com

SENSOR BOARD

RESISTOR 1/8W

R1 500

Ω

- green-black-brown-gold

R2,R5,R7,R9 1k

Ω

- brown-black-red-gold

R4,R6,R8 3k

Ω

- orange-black-red-gold

RESISTOR 1/4W

R3 10

Ω

- brown-black-black-gold

TRIMMER POTENTIOMETERS

VR1-VR4 = 

10k

Ω

or  103

CONTROL BOARD

RESISTOR 1/4W

R1,R2,R4 150

Ω

- brown-green-brown-gold

R3 50

Ω

- green-black-black-gold

R5,R6,R12,R14,R19 1k

Ω

- brown-black-red-gold

R7-R11,R13,R15-R18 500

Ω

- green-black-brown-gold

IDE port

IDE port

µ

F

µ

F

µ

F

µ

F

µ

F

Photo-Transistor

AND LED Infrared

COPPER

LAYER

IDE port

IDE port

IDE port 

(Connect with programmer)

Photo-Transistor

AND LED Infrared

COPPER

LAYER