Design And Construction Of A Hearing Aid Using Bluetooth

Electrical Electronics Engineering

The design and construction of a hearing aid utilizing Bluetooth technology involve the development of a sophisticated device aimed at enhancing auditory perception for individuals with hearing impairments. This process integrates various disciplines such as electronics, acoustics, and software engineering to create a compact and efficient system. The device incorporates Bluetooth connectivity to enable seamless communication with smartphones or other compatible devices, allowing for wireless audio streaming and control functionalities. By leveraging Bluetooth technology, the hearing aid can provide users with greater flexibility and convenience in adjusting settings, receiving audio input, and managing their hearing experience. The construction phase involves meticulous assembly of components such as microphones, amplifiers, signal processors, and miniature speakers into a discreet and comfortable form factor suitable for daily wear. Additionally, considerations for power management, signal processing algorithms, and user interface design play crucial roles in optimizing the device’s performance and usability. Overall, the design and construction of a Bluetooth-enabled hearing aid represent a dynamic intersection of engineering innovation and user-centric design principles, offering individuals with hearing loss enhanced accessibility to audio communication and improved quality of life.

ABSTRACT

This work is on a Bluetooth based hearing aid. A hearing aid is a device designed to improve hearing. Hearing aids are classified as medical devices in most countries, and regulated by the respective regulations. Hearing aids are the best option for correcting hearing loss and resuming a high quality of life. Bluetooth hearing aids contain at least one microphone to pick up sound, a computer chip that amplifies and processes sound, a speaker that sends the signal to your ear, Bluetooth module to connect to other devices wirelessly and a battery for power. Hearing aids are incapable of truly correcting a hearing loss; they are an aid to make sounds more accessible.

TABLE OF CONTENTS

COVER PAGE

TITLE PAGE

APPROVAL PAGE

DEDICATION

ACKNOWELDGEMENT

ABSTRACT

CHAPTER ONE

INTRODUCTION
BACKGROUND OF THE PROJECT
OBJECTIVE OF THE STUDY
SIGNIFICANCE OF THE STUDY
SCOPE OF THE PROJECT
APPLICATION OF THE PROJECT
METHODOLOGY
PROJECT ORGANISATION

CHAPTER TWO

LITERATURE REVIEW

OVERVIEW OF THE STUDY
USES OF THE STUDY
REVIEW OF CANDIDACY AND ACQUISITION OF THE STUDY
REVIEW OF DIFFERENT TYPES OF HEARING AID
HISTORICAL BACKGROUND OF HEARING AIDS
REVIEW OF BLUETOOTH TECHNOLOGY
IMPLEMENTATION OF BLUETOOTH
COMMUNICATION AND CONNECTION

CHAPTER THREE

METHODOLOGY

BASICS OF THE SYSTEM
BLOCK DIAGRAM OF THE SYSTEM
SELECTING THE BLUETOOTH HEADSET, ON/OFF SWITCH, AND LEDS
CIRCUIT DIAGRAM
WIRING DIAGRAM
BASIC THEORY OF COMPONENT USED

CHAPTER FOUR

TEST AND RESULT ANALYSIS

CONSTRUCTION PROCEDURE
ASSEMBLING OF SECTIONS
PACKAGING
TESTS
RESULTS

CHAPTER FIVE

DISCUSSION
CONCLUSION
RECOMMENDATION
REFERENCES

CHAPTER ONE

1.0 INTRODUCTION

An electronic hearing aid is a small device placed in or around the ear to improve the hearing of those with hearing loss. The basic components of a hearing aid are a microphone, signal conditioning, a receiver also known as a speaker, and a battery. The microphone converts the sound into an electric signal. The signal then undergoes conditioning that can be as simple as amplifying all of the sound equally, to more advanced equalization involving a digital signal processor. The receiver converts the electronic signal back to sound, and the battery powers the electronics (Schum, D.J. 2004).

There are four main styles of hearing aids on the market today. From largest to smallest, they are behind the ear (BTE), in the ear (ITE), in the canal (ITC), and completely in the canal (CIC). The BTE style sits behind the ear with a clear tube going to an earmold in the ear to deliver the sound. A variation on this style is called an open-fit-behind-the-ear (OTE) where the earmold is replaced by a small tip, resulting in a more open feeling. Other variations include replacing the tube with wires and moving the receiver from the behind the ear to inside the ear. The ITE style moves the hearing aid into the outer ear, where it becomes a single unit with the earmold. This style fills up most of the outer ear and appears as a solid mass. The ITC style moves some of the hearing aid into the ear canal and reduces the space taken up in the outer ear, but is still plainly visible. The CIC style is the smallest of them all, as it fits completely inside the ear canal, thus nearly disappearing from view.

There are many features available for today’s hearing aids, including volume control, remote control, telecoil, direct audio input, FM reception, Bluetoothcapabilities, directional microphone, compression, clipping, frequency shifting, wind-noise management, data logging, self-learning, moisture resistance, and earmold venting. Some of these features require external area to implement and become more difficult to include as the size of hearing aids shrinks, while other features can be implemented in all hearing aids.

Volume control is performed manually with buttons or a rotary dial on the hearing aid. A remote control eliminates the need for buttons and dials on the hearing aid and can be used to control all the features of the hearing aid. A telecoil is an alternate input other than the microphone, and it originally picked up the magnetic signal generated by older telephones with speakers driven by magnetic coils so that listeners could hear better when talking on the telephone. Today’s telephones and other alternate listening devices build-in this capability in order to work with a telecoil and specifically indicate that they are hearing aid compatible. Direct audio input and FM reception are other ways to input sound or speech into the hearing aid, the first using a wired connector as an input, and the other an FM radio receiver. An emerging trend is to include Bluetooth capability to receive sound from a cell phone or music player. The Bluetooth device can either be integral to the hearing aid or an add-on device through the telecoil or FM input (Schum, D.J. 2004).

A hearing aid with directional microphones uses two or more microphones to receive sound from multiple directions. This improves the signal-to-noise ratio (SNR) of speech when heard in a noisy environment, and enhances the quality of speech further when used with digital signal processing. Compression and clipping both increase listening comfort by reducing portions of the sound that are too loud but, in some cases, just clip or limit the sound. Frequency shifting uses digital signal processing to shift speech to a lower frequency, which is helpful for people with high-frequency hearing loss. Wind-noise management detects wind and eliminates the feedback that would otherwise cause ringing sounds to be heard by the hearing aid wearer (Paul, S. 2000).

Data logging records the listening environment and how the hearing aid is used. A hearing professional can use this information to fine-tune hearing aid performance. Self-learning uses the data logs and fine-tunes the performance on its own over time. Moisture resistance helps reduce repairs due to exposure to moisture, and earmold vents provide additional comfort by reducing the closed-in sensation felt when wearing an earmold type of hearing aid (Schum, D.J. 2004).

Hearing aids with Bluetooth technology help you stay connected to iOS and Android phones, televisions, tablets and other favorite audio devices.

Hearing aids of the past often limited the wearer’s access to many personal audio devices such as mobile phones and music players. For example, to use a music player while jogging, you would have had to remove your hearing aids to accommodate a pair of earbuds. However, today’s sophisticated wireless hearing aids, such as the Oticon More^TM, use Bluetooth technology to make it possible to connect with personal electronic devices and stream sound directly to hearing aids.

1.1 BACKGROUND TO THE STUDY

Hearing is one of the five senses along with vision, taste, smell and touch. The ear serves asa receiver of incoming sounds. Although the ear receives sound and is the sense organ for hearing, it is the brain and central nervous system that interpret the sound. The human auditory system can generally hear sounds within the frequency range of 20 Hz and 20 kHz but the frequency range between 100Hz and 6 kHz contains most of the information of human voice (Sergei Kochkin, 2015). Although the sensation of hearing requires an intact and functioning auditory portion of the central nervous system as well as working ear, human deafness (extreme insensitivity to sound) and hearing loss most commonly occur because of damages of the ear, rather than the central auditory system.

Hearing aid device is a small electronic gadget that is fit in or behind the ear to improve one’s hearing and consequently communication ability (J., Moore, Brian C., 2007). While some people are born with hearing problem some others develop it as they grow. This problem can occur as a result of disease, aging, and injury from noise or intake of certain medicines (J., Moore, Brian C., 2007). Hearing problems could be that of complete deafness or partially impaired type. Hearing problem could occur after a person learned to talk (post lingual) or those with trilingual deafness that is, deafness that occurs before a person learns to talk. Deafness, whatever the degree or course, is generally a source of worry and frustration to the patient concerned as it affects almost all aspects of one’s life.

Hearing loss is usually reserved for people who have relative insensitivity to sound in the speech Frequency range. A hearing loss can happen when any part of the auditory system is not working in the usual way (J., Moore, Brian C., 2007)

The design and constructed hearing aid device can improve the quality of sound for people with hearing loss. The heart of the circuit is an integrated circuit which amplifies all the signals picked by the condenser microphone and converts them back into sound and sent to the ear. It is a battery-powered electronic device that can amplify sound for people with hearing loss. The amplification function of the hearing aid is made possible with several components; a microphone (input transducer) which picks up sound an amplifier which increases the volume or the sound, a receiver (output transducer) which changes the electrical signal back into sound and sends it to the ear (Schum, D.J. 2004).

Hearing aids have been available in four styles: body, eyeglass, behind-the-ear (BTE), and in-the-ear (ITE) hearing aid. Included in the category of ITE hearing aids are in-the- canal (ITC) and completely-in-the-canal (CIC) styles. While body and eyeglass style hearing aids were regularly used 40-50 years ago, they comprise only about 1% of all hearing aids marketed today. Instead, most individuals choose ITE (approximately 80%) or BTE (approximately 20%) style hearing aids. This transition in style, use, and preference is occurring for a number of reasons, including the reduction in the size of the components, durability, and cosmetic concerns on the part of the consumer (Theradja, B.L., 2003).

1.2 OBJECTIVE OF THE PROJECT

The objective of this work is to design an electroacoustic device which amplifies sound for the wearer which incorporated a Bluetooth technology to make it possible to connect with personal electronic devices and stream sound directly to hearing aids. The objectives are:

To make speech more intelligible
To correct impaired hearing as measured by audiometry.

To connect to other audio devices wirelessly

To build and evaluate the performance of the device

1.3 SIGNIFICANCE OF THE PROJECT

Bluetooth hearing aids are incapable of truly correcting a hearing loss; they are an aid to make sounds more accessible. Two primary issues minimize the effectiveness of hearing aids:

When the primary auditory cortex does not receive regular stimulation, this part of the brain loses cells which process sound. Cell loss increases as the degree of hearing loss increases.

Damage to the hair cells of the inner ear results in sensorineural hearing loss, which affects the ability to discriminate between sounds. This often manifests as a decreased ability to understand speech, and simply amplifying speech (as a hearing aid does) is often insufficient to improve speech perception.

1.4 SCOPE OF THE PROJECT

The scope of this work focused on building a hearing aid device circuit works using Bluetooth module and the major device and other several passive electronic components. Bluetooth based hearing Aids offers the best variety of digital in ear.

1.6 APPLICATION OF THE PROJECT

These hearing aids are designed for medical practitioners with hearing loss who use stethoscopes. The hearing aid is built into the speaker of the stethoscope, which amplifies the sound. Hearing aid can also be used by aged people or people suffering from problem to improve their hearing.

1.7 METHODOLOGY

To achieve the aim and objectives of this work, the following are the steps involved:

Study of the previous work on the project so as to improve it efficiency.
Draw a block diagram.

Test for continuity of components and devices,

Design and calculation for the device was carried out.
Studying of various component used in circuit.
Construction of the circuit was carried out.

Finally, the whole device was cased and final test was carried out.

1.8 PROJECT WORK ORGANISATION

The various stages involved in the development of this project have been properly put into five chapters to enhance comprehensive and concise reading. In this project thesis, the project is organized sequentially as follows:

Chapter one of this work is on the introduction to this work. In this chapter, the background, significance, objective limitation and problem of this work were discussed.

Chapter two is on literature review of this work. In this chapter, all the literature pertaining to this work was reviewed.

Chapter three is on design methodology. In this chapter all the method involved during the design and construction were discussed.

Chapter four is on testing analysis. All testing that result accurate functionality was analyzed.

Chapter five is on conclusion, recommendation and references.