Design And Construction Of An Electric Dice Display With Audio Unit
An Electric Dice Display with Audio Unit is an innovative gaming accessory that combines visual and auditory elements to enhance the gaming experience. This device features a digital display that showcases the rolled dice results in real-time, offering players instant feedback and excitement. Simultaneously, the integrated audio unit generates sound effects corresponding to the dice rolls, further immersing players into the game atmosphere. This interactive combination of visual and auditory stimulation not only adds a dynamic dimension to gaming but also fosters engagement and enjoyment, making it an enticing option for both casual and serious gamers alike.
This work deals extensively with the design and construction of an electrodice display (EOD) with audio unit. The device displays the value of a ludo dice in numerical form and also produces sound as it displays the number.
The device works with principle of chance employed by ludo game players. The output of the display is usually very rapid that the player does not actually see the number when the device is switched ON so that it will purely be a game of chance. When the off key is pressed, a particular number is displayed and this number is the number the player got.
The operation of the device starts by the generation of a pulse frequency. The pulse frequency (square wave signal) is generated by times (555 timer) by connecting in unstable multi-vibrator. The output from the timer is used in clocking the binary counter (mode 10 counter) but this counter is biased in the mode 10 counter, the output from Qo, Q1 and Q2 were connected to the reset pins so that once the counter finishes the count of six of goes back to zero.
The result from the binary counter is then fed to the decoder / driver before connecting it to seven segment so that the decoder will be able to convert the binary values to the decimal values that are being used in the ludo game dice. The seven segment then displays the numbers by lightening the diodes that make up that particular.
This device is being regulated by a latch (4-edge triggered flip-flop which has two switches, one is used for putting the power supply and the other two push switches for the working of the dice display.
Cover page
Title page
Approval page
Dedication
Acknowledgement
Abstract
Organization of work
List of figures
List of table
CHAPTER ONE
INTORDUCTION
1.0 Statement of problem
1.1 Purpose of study
1.2 Aim and objectives
1.3 Scope of the study
1.4 Limitations of the study
1.5 Definitions of terms.
CHAPTER TWO
LITERATURE REVIEW
CHAPTER THREE
DESCRIPTION AND ANALYSIS OF THE EXISTING SYSTEM FACT FINDING METHODS
Organization structure
Objectives of the existing system
CHAPTER FOUR
DESIGN OF THE NEW SYSTEM
Output specification and design
Input specification and design
File design.
Procedure chart
System flow chart
System Requirement.
CHAPTER FIVE
IMPLEMENTATION
Program Design
Program Flowchart
Pseudocodes
CHAPTER SIX
DOCUMENTATION
CHAPTER SEVEN
RECOMMENDATION
CONCLUSION
REFERENCE
INTRODUCTION
Instrumentation engineering has advanced widely with the introduction of medium scale integration (MIS), large scale Integration (LSI) and very large scale Integration (VLSI). For the purpose of accuracy and reliability analogue instruments are being replaced by the digital ones. The electronic dice display (EDD) with audio unit is among this now bread of instruments.
1.0 STATEMENT OF PROBLEM.
The design of an electronic dice display is invented because of the quest fort reducing strenuous activities encountered by man, especially on the area of its recreational activities. This device is used in ludo game. The ludo game on its manual operation, as he manipulated by the experts so that it can no longer be a game of chance. Sometimes players can employ tricks on their opponents which playing the game, for example if the both players are not vigilant, one of the them can event thwart the dice and claimed that nothing happened. The players too may get tired after playing two or three times because of the stress in shaking and playing the dice, the frequent hitting of the dice on the ludo board can even give cracks on the glass covering the ludo board. One can even experience the dice getting lost in the game because the dice is very small so if care is not taken, it can fall out from the board. All these problems were taken into consideration before constructing the electronic dice display.
1.1 PURPOSE OF THE STUDY.
As stated earlier, the design of this device is to help man conquer his environment. With the advent of medium scale integration (MSI), Integration circuit (IC) can be used to design devices that can help man perform his work effectively. With little or no stress and even sometimes at a cheaper rate. The device too will eradicate all the stress, tricks and pranks encountered when playing ludo game.
1.2 AIMS AND OBJECTIVES
The device will increase the fun derived from playing the game, even little kids can now join since they only need to press the buttons for the device to work. The game will now be purely based on chance because all bias will be eradicated, no expert can manipulate the device no matter how many times you use it. the normal phenomenon of playing tricks will be a thing of the past.
1.3 SCOPE OF THE STUDY
The work covered that playing and displaying of number got. This that the device when switched ON and STAR button is pressed, a particular number will be shown and this is the number the player got. This means that the player still need to get a ludo board and the seeds for the game.
1.4 LIMITATIONS OF THE STUDY
It will be an unfair treatment to this project if the discussion of the limitations that handicapped this important research work is overlooked. Hence, it is considered necessary for it will be a stepping stone for the improvement in further work.
The work is limited to just playing of the number got and the generation of sound through emphasis was not laid on the sound system. Part of the limitations in this project is as a result of their inclusion in the scope while others are due to constraints. The design specification was to achieve an electronic dice display that can display from 1 – 6. also the system is not protected from wrong voltage supplies. Voltage polarities wrongly connected or supplies greater than the specific supply voltage will damage the system.
Most of the constraints were due to lack of test with detailed information on the theory and the practice of electronic dice display (EDD). As 90% of the components are purely digital. They are not readily available on the market. Some of the components especially the transistors used sound display were not found in the market so I was forced to use the equivalent as specified in the data book and when some of these components are found, they are usually expensive.
Another problem was lack of equipment in the departmental laboratory for the executing and monitoring of the project. Some of the equipment used in the other department/ market were bad and gave false result. The oscilloscope used was not sophisticated enough to display very low frequency output of about 1Hz. Also, lack of textbooks was another serious problem. The few books seen treated components of dice display so shallowly. This calls for designing and re-designing till a working circuit was realized.
1.5 DEFINITION OF TERMS
AND GATE.
It is a circuit which gives a high outputs (ie logic 1 = high and logic O = low)an AND gate is represented by a dot to indicate it is a multiplication.
A
A.B
B fig 1.0 AND GATE
CAPACITORS:
It provides a means of storing electrical energy in form of an electric field.
Fig 1.1 Capacitor
COUNTER:
A circuit, which gives output pulse for every two inputs pulses. If the input pulses are irregular the circuit is regarded as counter. Counters usually come as integrated circuit.
DECODER/DRIVER:
A decoder can be the reverse of an encoder circuit, there are a variety of decoders designed for specific purpose. In this case it is used as a code converter where it is required to convert from binary coded decimal (BCD) to decimal.
DIODE:
Diode are two terminal devices which exhibit low resistance to current flow in the other.
FLIP FLOP:
It is a continual logic that can be able to hold one bit at a time.
LATCH:
A latch is a combination of flip flops, in the particular (IC 7474) latch, it has a combination of 4 positive edge triggered flip flops. It changes state on reseipt of an input signal but a way that it does not change state.
MULTIVIBRATOR (ASTABLE)
They are flip flops that has no stable state. It is called astable or free running multivibrator. These type of logic circuit switches back and forth (oscillates) between unstable states. Useful for providing clock signals for asynchronous digital circuits.
RESISTORS:
Resistors provide us with a means of controlling voltage in a circuit electronic circuit.
SWEN SEGMENT DISPLAY:
This is a method of displaying the numerals from 0 – 9 by illuminating 2 or more elements out of the seven arranged in a form. If all the elements 1,2,7,5 and 4 are illuminated a 5 is displayed. Seven segment display is extensively used in electronic equipment e.g recoders, calculators and digital watches.
TIMER:
Timers are used to generate continuous waves or pulse frequency which is usually used for linear applications such as low level amplification, for switching applications, high frequency application and can also be designed to handle high voltage.
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Electric Dice Display With Audio Unit:
Creating an electric dice display with an audio unit can be a fun DIY project. This project will involve building a device that rolls a virtual dice and displays the result on an electronic display while also producing an audio output to announce the result. Here’s a high-level overview of how you can create such a device:
Components Needed:
Microcontroller (e.g., Arduino, Raspberry Pi)
LED Display (e.g., 7-segment display)
Push-button switch or accelerometer for dice rolling input
Speaker or buzzer for audio output
Power supply (e.g., batteries or USB power)
Breadboard or custom PCB (Printed Circuit Board)
Wiring and connectors
Optional: Enclosure to house the components
Steps to Create an Electric Dice Display with Audio:
Plan your design: Decide on the form factor and appearance of your device. Sketch out a basic design to help guide your project.
Choose a microcontroller: Select a microcontroller platform like Arduino or Raspberry Pi, which will serve as the brain of your device. You’ll program it to generate random dice rolls, control the LED display, and play audio.
Acquire the components: Gather all the necessary components mentioned above. Make sure they are compatible with your chosen microcontroller.
Circuit assembly:
Connect the LED display to the microcontroller using appropriate pins.
Connect the push-button switch or accelerometer to trigger the dice roll event.
Connect the speaker or buzzer for audio output.
Write the code:
Program your microcontroller to generate random dice rolls (1 to 6) when the button is pressed or the accelerometer detects a motion (shake).
Create a function to display the result on the LED display.
Implement an audio module to announce the result using the speaker or buzzer.
Test and debug: Test your device thoroughly, and ensure that it generates random numbers correctly, displays them on the LED display, and plays the corresponding audio.
Enclosure: If desired, create an enclosure to house your components and give your device a polished appearance. This can be made from various materials like plastic, wood, or 3D-printed parts.
Finalize the project: Once everything works as intended, finalize the connections, secure components in the enclosure (if used), and ensure the device is safe and functional.
User interface: Consider adding user-friendly features like an on/off switch, volume control, and a reset button.
Documentation and sharing: Document your project with clear instructions and diagrams so others can replicate it. Share your creation with the maker community or friends.
Remember to exercise caution when working with electronics, and ensure that your device complies with safety standards, especially if you plan to use it around children. This project combines hardware and software skills, making it an exciting and educational endeavor.