Project report on Asuro robot

Abstract: This article illustrates the project about the Asuro Robot, which conducted in Xi’an Jiao Tong Liverpool University. In this study, students required to learn the practical skills in building and troubleshooting a circuit. However, there were several difficulties occurred in the experiment, such as the polarities of the components. Due to these difficulties, students need to be well prepared about the basic of electronic circuit.

Introduction

Since the beginnings of civilization man has had a fascination for a human-like creation that would assist him. Robots, such as human creatures built in by the electronic devices and created into one. In this experiment, Asuro Robot were chosen because this robot equipped with a diversity of components such as an Atmel AVR RISC-processor, two independently controlled motors, an optical line tracer, six collision detector switches, two odometer-sensors, three indicators LED, an IR-Interface for programming and remote controlled by a PC. These components all have their own specially function. For instance, the line tracer is used to help the robot go through a traced way, the orders given to the robot to make possible ASURO follows the road can be designed and developed by C programming. In order to assemble and install properly the elements of the robot, basic knowledge about soldering is requested and is expected the builder improve his skills.

In this experiment, each participant achieves the project through the team work. On the one hand people can learn how to weld the devices, and how to use computer to write program into the robot. One other hand, people also can learn the skills which are how to communicate with other people and how to coordinate the teammates through the team work.

Theory:

The basic theory of the experiment was Ohm’s law: The current flowing in the resistor is proportional to the voltage across the resistor. And the formula is: V=i*R, where V=voltage (V), i=current (A), and R=resistance (Ω).

Also the capacitor was very important: the voltage difference between the two conductors is proportional to the charge and q=C v, therefore i=dq/dt=C dv/dt. The proportionality constant C is called capacitance. The units of Farads (F) =Coulomb/Volt and for two parallel plates: C= εA/d.

i(t)=CAbbildung in dieser Leseprobe nicht enthalten v(t)=Abbildung in dieser Leseprobe nicht enthalten

Experimental method:

The materials use in this project consists of many different type of electronic components. such as resistor, capacitor, LEDs light, and transistor. Furthermore, for the equipment use in this project was solder, multimeter. See appendix for partlists

Circuit Design:

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Fig. 1 Component layout

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Fig.2 Schematic Diagram of the PCB circuit

Procedure:

The following inserting sequence may be used as a guideline:

- IC1: at first insert only the socket (either one Dual in line 28 pole-socket or two Dual in line
- 14 pole sockets). Pay attention to polarity! A slight asymmetry is a mark for polarity in the socket and in the symbols on the PCB!
- IC3: Again insert only the socket (Dual in line 14 pole-socket). Pay attention to polarity! A slight asymmetry is a mark for polarity in the socket and in the symbols on the PCB!
- K1, K2, K3, K4, K5, K6: Sensor-switches, which must be mounted fl at to the PCB surface!
- Q1; Resonator 8MHz
- D1, D2, D3, D4, D5, D6, D7, D8: Diode 1N4148; Pay attention to polarity!
- D9: 1N4001; Pay attention to polarity!
- JP1: Jumper; Short pins will be soldered; do not yet apply the jumper connector element!
- D12: Dual colored LED, 3 mm diameter, three legs; Pay attention to polarity! (Polarity may differ from part to part, however: the shortest leg must be inserted into the square soldering pad)!
- C2, C3, C4, C5: 100nF Ceramic; Imprinted: 104
- C6, C7: 4,7nF Ceramic; Imprinted: 472
- T1, T3, T5, T7: BC327-40 or BC328-40
- T2, T4, T6, T8: BC337-40 or BC338-40
- R1, R2, R3, R4, R5, R6, R7, R8, R19, R21: 1KΩ 5% (brown, black, red, gold)
- R9, R16: 220Ω 5% (red, red, brown, gold)
- R10, R17, R22, R31: 5% 470Ω (yellow, violet, brown, gold)
- R11: 100Ω 5% (brown, black, brown, gold)
- R12: 12KΩ 1% (brown, red, orange, gold)
- R13: 10KΩ 1% (brown, black, orange, gold)
- R14, R15: 20KΩ 5% (red, black, orange, gold)
- R18, R20: 4,7KΩ 5% (yellow, violet, red, gold)
- R23: 1MΩ 5% (brown, black, green, gold)
- R24: 1KΩ 1% (brown, black, black, brown, brown)
- R25, R26, R32: 2KΩ 1% (red, black, black, brown, brown)
- R27: 8,2KΩ 1% (grey, red, black, brown, brown)
- R28: 16KΩ 1% (brown, blue, black, red, brown)
- R29: 33KΩ 1% (orange, orange, black, red, brown)
- R30: 68KΩ 1% (blue, grey, black, red, brown)
- C1, C8: Elco 220μF 10V or higher values; Pay attention to polarity!
- IC2: SFH5110-36 Infrared-receiver-IC, bend the legs with long-nose pliers!
- Pay attention to polarity (the side with dome-shaped curvature must be positioned to the outside)! Caution: electrostatic discharge (ESD) and excessive soldering or heating may damage the part!
- D10: SFH 415-U IR-LED 5mm; black case; Pay attention to polarity! Case must be settled close to PCB.
- T11, T12: LPT80A, Phototransistor, colorless case;
- Case must be settled close to PCB; Pay attention to polarity!
- D13, D14: IRL80A, IR-LED, rosy case;
- Case must be settled close to PCB; Pay attention to polarity!
- D15, D16: LED 5 mm red, rosy respectively red case. Pay attention to polarity
- (Short leg must be inserted at the mark)!
- S1: On/Off-Switch
- Three more parts will be needed (which will be used to follow a line), but they will be placed at the bottom side of the PCB and have to soldered from the upper side
- T9, T10: SFH300, Phototransistor 5 mm; Pay attention to polarity! These components have to be placed at some distance from the PCB.
- D11: LED 5 mm red, red or reddish case; Pay attention to polarity! (short leg must be inserted at the mark)!

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Fig. 3

Assembling the RS232 infrared-transceiver

- IC1: Initially insert the 8-pole socket. The polarity mark of the (slightly asymmetrical) socket must correspond to the mark in the accompanying symbol on the PCB.
- D1, D2, D3: 1N4148, pay attention to polarity! Read the imprints of the parts and take care not to interchange with ZPD5.1 or BZX55-C5V1!
- D4: ZPD5.1 or BZX55-C5V1, pay attention to polarity! Read the imprints of the parts and
- take care not to interchange with 1N4148!
- D5: SFH-415-U IR LED (Black LED) pay attention to polarity, press downwards to the PCB
- C1: 100μF at least 16 volt, pay attention to polarity!
- C2, C4: 100nF ceramic capacitor, imprint: 104
- C3: 680pF ceramic capacitor, imprint: 681
- Q1: BC547 (A,B or C) or BC548 (A,B or C)
- R1, R5: 20kΩ_ (red, black, orange, gold)
- R2: 4.7kΩ (yellow, violet, red, gold)
- R3: 470Ω (yellow, violet, black, gold)
- R6: 10kΩ (brown, black, orange, gold)
- R7: 220Ω (red, red, brown, gold)
- TR1: 10KΩ variable resistor
- IC2: SFH5110-36 Infrared receiver IC bends the legs with appropriate tongs! Pay attention to polarity (the curvature must be positioned to the outside)! Caution: electrostatic discharge
- (ESD) and excessive soldering or heating may damage the part!
- X1: 9pol. SUB-D connector, case must be settled close to PCB. Attachment strips must be soldered as well!
- IC1: insert the NE555P, pay attention to polarity!

Results:

When finish building the robot and complete the soldering process, it is satisfying that the robot can work successfully. The results meet the requirements of this experiment completely.

Turning the switch, the robot starts to work though need to take some minutes to run the programs. First of all, the diode12 which is colorless start to shine. When the diode works, the color of the diode will have a change. At the very beginning, the colorless diode becomes yellow for some seconds. After that it will turn to green for other seconds. Finally, the diode will turn off and return to colorless. By finishing the work of the circuit, another diode will work. Diode15 which is red will start to work after diode 12 finish working in some seconds. It will get bright. Next, the three diodes in front of the robot will continue to work when diode12 turns off. The three diodes turn on at the same time at the beginning. Then the two diodes on both sides will get dark. In other words, the middle one gets brighter than the other two diodes. When the process lasts for a short time, the three diodes will turn off. Then the diodes16 will start work, then gets bright red for some seconds.

After all the diodes finish working, the robot will begin to run as the route which is decided by the program. The whole process contains four steps. The robot begins to turn left for the first step. Because the program determines that there is just the right wheel working and the left wheel stay still. Next, the robot will run the opposite program which permits the left wheel to spin and the right wheel stays still, then to find that the robot will get back to the position it has been. Then the robot runs the program which allows both wheels work at the same time. As a result, the robot runs forward in a straight line for a distance. Oppositely, the program will make the robot run back at the route which takes to run forward.

Discussion:

Troubleshooting:

1.Soldering

Soldering is the step which behind the preparing the legs. Soldering is a hard thing. Users put a small quantity of solder to the legs and at the same time, melting, the solder will flow into the metal hole until the hole is filled completely.

More over, soldering is also the most important part in the experiment to do the robot. There are two attentions for soldering. Firstly, for the legs, experimenters should n’t leave too much copper legs over the circuit board, it is not beautiful, some future, if two copper legs touched, that may cause the exploding. It’s dangerous.

Secondly, for the soldering. The perfect weltering hole is the solder filled the hole exactly. If user putting little solder, it may make the circle doesn’t work, otherwise, too much looks bad.

2.The Positive and negative parts of component

3. Diode-- A diode is a two-terminal electronic component that conducts electric current in only one direction. The function of a diode is to allow an electric current to pass in one direction while blocking current in the opposite direction. Thus, if users put the wrong pole to the holes then the function will be opposite.

LED— LED is also one kind of diodes.

Processor—A processor is the brand of the robot. If experimenter assembled it in the wrong way, the robot may didn’t do the right work and even didn’t work.

4.Some details

Wheel sensors—the tags on the wheels also are significant part. The tags are the odometer. A complete set of adhesive odometer markers is supplied with this kit. Place them on to the 50/10 gear. Using the sensor-markers with 6 black and white segments is recommended for compatibility for compatibility with other ASURO’s. Cars do the different work by the difference between light and dark.

5. C-programme

Every word in one C-programmed is important, a little mistake also can lead to the destroy.

6. check

If the car doesn’t work, check all above.

Conclusion

To sum up, in this experiment allow every student know exactly how to built up a single robot car from an electronic components. On the other hand, students also gain the experience from the soldering, from build and troubleshooting.

Moreover, there were several limitations during this experiments such as, the student soldering in long duration, may cause some components were burned. So in order to decrease the percentage of burned components, students should solder quickly.

Appendix

A. Parts list Besides a table-tennis ball the following parts are needed to build an ASURO:

1x Printed circuit board ASURO

2x Motors Type Igarashi 2025-02

1x Diode 1N4001

8x Diodes 1N4148

4x Transistors BC 327/40 or BC 328/40

4x Transistors BC 337/40 or BC 338/40

1x Integrated circuit CD 4081BE

1x Processor ATmega 8L-8PC (preprogrammed)

1x IR-receiver SFH 5110-36

1x IR-LED SFH415-U

2x phototransistors SFH300

3x LEDs 5mm red bright diffuse or asymmetric wide-angle

1x Dual-LED 3mm

2x Side-phototransistors LPT80A

2x Side-LEDs IRL80A

1x Crystal 8MHz

2x Elco 220μF at least 10V RM 3,5/10

4x ceramic capacitors 100nF RM 5,08

2x ceramic capacitors 4,7nF RM 2,54

1x 100Ω 1/4 W 5%

2x 220Ω 1/4 W 5%

4x 470Ω 1/4 W 5%

10x 1KΩ 1/4 W 5%

1x 1KΩ 1/4 W 1%

3x 2KΩ 1/4 W 1%

2x 4,7KΩ 1/4 W 5%

1x 8,2K Ω 1/4 W 1%

1x 10KΩ 1/4 W 1%

1x 12kKΩ 1/4 W 1%

1x 16K Ω 1/4 W 1%

1x 20KΩ 1/4 W 5%

1x 33kKΩ 1/4 W 1%

1x 68K Ω 1/4 W 1%

1x 1M Ω 1/4 W 5%

3x Socket 14 pol.

6x Detector switch

1x Switch (main on/of)

1x Battery holder

1x Battery clip

1x Jumper

1x Jumper pins 2pole RM 2.5

2x Cogwheel 10/50 cogs; 3,1mm drilling hole Module 0,5

2x Cogwheel 12/50 cogs; 3,1mm drilling hole Module 0,5

2x Pinion gear 10 (oder 12) cogs; drilling hole 1,9mm Module 0,5

2x Collar for 3mm-axle

4x Cable binder

1x Cable binder releasable

2x Rubber tires 38mm

2x Messing shaft 42mm long 3mm diameter,

2x Messing shaft 24,5mm lang, 3mm diameter

ca. 15 cm wire red 0,14mm_

ca. 15 cm wire black 0,14mm_

2x Encoder sticker

The additional RS-232-IR-transceiver will be equipped with the following parts:

1x Printed circuit board IR-RS232-transceiver

3x Diodes 1N4148

1x Zener diode ZPD5.1

1x Transistor BC547 A,B or C or BC548 A,B or C

1x Integrated circuit NE555N

1x IR-receiver SFH 5110-36

1x IR-LED SFH415-U

1x Elco 100μF at least 16V RM 2,5/6

2x ceramic capacitors 100nF RM 5,08

1x ceramic capacitors 680pF RM 2,54

1x 220Ω 1/4 W 5% or better

1x 470Ω 1/4 W 5% or better

1x 4,7KΩ 1/4 W 5% or better

1x 10KΩ 1/4 W 5%

2x 20KΩ 1/4 W 5% or better

1x Trimmer 10k vertically mounted RM 2,5/5

1x Socket 8 pole

1x 9-pol. SUB-D-entry

B. Asuro Diagram

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C. RS-232 Transceiver

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D. Block Diagram Asuro

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E. Block Diagram PIC Processor

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F. Contents Asuro Kit

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References

“Robot”, Wikipedia foundation Inc. accessed November 22, 2010,

<http://en.wikipedia.org/wiki/Robot>

“Educational Robots”, Wikipedia foundation Inc., accessed November 22, 2010,

<http://en.wikipedia.org/wiki/Category:Educational_robots>

“Frontiers of Mechanical Engineering in China”, Review Article, Springer accessed November 22, 2010

<http://www.springerlink.com/content/c7051m07pt38p242/>

Frequently Asked Questions About Asuro Robot Project

What is the Asuro Robot project about?

The Asuro Robot project, conducted at Xi’an Jiao Tong Liverpool University, focuses on students learning practical skills in building and troubleshooting electronic circuits. The project utilizes the Asuro robot, which has various components like an Atmel AVR RISC-processor, motors, line tracer, collision detectors, odometer sensors, LEDs, and an IR-Interface.

What is the purpose of using the Asuro Robot in this project?

The Asuro Robot is chosen for its diverse components and functionalities. It allows students to learn about soldering, circuit assembly, C programming for robot control, and teamwork skills.

What basic theories are involved in this project?

The primary theories involved are Ohm's Law (V=i*R) and capacitor behavior (q=Cv, i=C dv/dt).

What materials are used in the Asuro Robot project?

The project utilizes various electronic components like resistors, capacitors, LEDs, transistors, and equipment such as solder and a multimeter. Refer to the appendix for a detailed parts list.

What is the recommended inserting sequence for components during assembly?

A specific insertion sequence is provided, starting with IC sockets, followed by sensor switches, resonators, diodes, jumpers, LEDs, capacitors, transistors, and resistors. Polarity is crucial for several components like diodes, LEDs, and electrolytic capacitors.

How is the RS232 infrared transceiver assembled?

The RS232 infrared transceiver assembly also follows a specific order, starting with IC sockets, diodes, transistors, capacitors, resistors, a variable resistor, the infrared receiver IC, and the SUB-D connector. Polarity and proper component identification are essential.

What are some expected results when the Asuro robot is successfully built?

Upon successful assembly and programming, the robot will perform a sequence of actions. The dual-colored LED (D12) changes color, followed by D15 lighting up. The front LEDs activate, and then the robot executes programmed movements, such as turning left, right, and moving forward/backward.

What are some common troubleshooting steps in this project?

Troubleshooting includes careful soldering techniques, ensuring correct component polarity, proper placement of wheel sensors, and accurate C programming. If the robot malfunctions, check all these aspects.

What are some common problems encountered during assembly and how can they be resolved?

Common issues include poor soldering (resulting in weak connections or shorts), incorrect polarity of components (especially diodes and LEDs), and errors in the C program. Careful attention to detail and thorough checking are essential.

What is the importance of soldering in this project?

Soldering is crucial for creating reliable electrical connections between components. Proper technique involves applying the right amount of solder to fill the hole completely, avoiding both insufficient and excessive solder. Also, avoid leaving excessive copper legs that could cause short circuits.

Why is it important to pay attention to the polarity of components?

Some components, like diodes, LEDs, and electrolytic capacitors, have specific polarity requirements. Incorrect polarity can cause the component to function improperly or not at all.

What is contained in the appendix?

The appendix includes a detailed parts list for both the Asuro robot and the RS-232-IR transceiver, diagrams of the Asuro circuit, the RS-232 transceiver, block diagrams, and a content list of the Asuro kit.

What is included in the parts list for the Asuro robot?

The parts list details the specific quantities and specifications of each component needed, including resistors, capacitors, integrated circuits, transistors, LEDs, motors, and mechanical parts.

What is the RS-232 transceiver used for?

The RS-232 transceiver is used for communication between the robot and a computer. It enables programming and control of the robot via an infrared interface.

What references were cited in this document?

References include Wikipedia articles on robots and educational robots, a Springer article on Frontiers of Mechanical Engineering in China, and C. Zhao's lectures in experimental skills.