JPH01158900A - Heating aid - Google Patents

Abstract

PURPOSE:To reduce an operating time by providing an acoustic signal output means with a low impedance, a digital sound volume varying means and an amplifier means with a low output impedance so as to improve the frequency characteristic of the hearing aid. CONSTITUTION:A current drive amplifier 4b with a low output impedance is used as an amplifier means B, a voice coil type earphone 5 with a low impedance is used as an acoustic signal output means D and a digital variable resistor 6 is used as a sound volume change means E. The digital variable resistor 6 is connected across the current drive amplifier 4b. Thus, the audible band is spread and the operating time in the sound volume change is reduced and the hearing capability close to a normal human being is ensured.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to hearing aids.

[Prior art and its problems]

In today's aging society, the population of people with hearing loss is on the rise. Hearing aids are devices used to compensate for the hearing loss of people with hearing loss. The basic configuration of the hearing aid will be explained below.

FIG. 6 shows an example of the basic configuration of a hearing aid. Basically, a hearing aid consists of an electrical signal input means (, A), an amplification means (
B), a power source (C), an audio signal output means (D), and a volume change means (E). The electric signal input means (A) is connected to the amplification means (B) and converts an external acoustic signal into an electric signal. The amplification means (B) is connected to the power source (C) and the acoustic signal output means (D), and amplifies the electric signal sent from the electric signal input means (A). A power source (C) supplies power to drive this amplification means (B). The acoustic signal output means (D) is further connected to the volume change means (E) and converts the electric signal amplified by the amplification means (B) into an acoustic signal. Volume change means (
E) changes the volume output from the audio signal output means (D).

As a power source, mercury batteries, lithium batteries, etc. are used due to the need for smaller size and lighter weight. However, these batteries generally have a higher internal resistance than normal dry batteries, so they lengthen the battery life and reduce the power supply. In order to utilize the voltage as effectively as possible in the audio signal output means (D) such as earphones, a high impedance audio signal output means (D) is used.

Furthermore, in order to effectively drive this acoustic signal output means (D), an amplification means (B) having a high output impedance is used in consideration of impedance matching. in this case,
Since the voltage applied to the load is high, for example, amplification means (
As B), a voltage-driven type is generally used.

FIG. 7(a) shows the configuration of a conventional hearing aid. Conventional hearing aids include a voltage-driven, common-emitter transistor (1) as the amplification means (B), and an acoustic signal output means (
A voice coil type earphone (2) is used as D), two terminals are provided on a resistor as a volume change means (E), and a sliding contact connected to the terminal is continuously slid while being in contact with the resistor between the terminals. An analog variable resistor (3) (for example, a carbon-based variable resistor) that changes the resistance value by changing the resistance value has been used. Figure (b) is equal to Figure (a) = 3
- This shows the circuit configuration of the amplifying means (B) in. Here, resistors R and R are leader resistors that provide forward bias between the base and emitter B and stabilize the bias current. The resistor R6 is for taking out the output, and the resistor RE is for stabilizing the bias current. Further, the capacitor CSC is for blocking the direct current component. Note that a capacitor C having a sufficiently large capacity is connected in parallel with R so that the emitter is grounded for AC components (signal components). The output impedance of this emitter E-shaped grounded transistor (1) is relatively high. This is because a high-impedance voice coil earphone (2) is used, so we try to match the impedance.
This is to eliminate losses as much as possible.

Conventional hearing aids use high impedance earphones (2) and high output impedance amplification means (1) as described above, so the audible band is relatively narrow, approximately 200Hz to 6kHz. .

However, in normal life, the natural voices spoken by normal people in conversations, the voices spoken through telephones, and the sounds heard on television and radio range over a wide range (20 Hz to 20 kHz). For this reason, the audible band of conventional hearing aids is too narrow, making it impossible for people with hearing loss to lead a fully satisfying social life.

In addition, the volume change means of conventional hearing aids had a structure that continuously changed the volume (for example, a carbon-based variable resistor), so it took time to adjust the volume when external conditions changed, and the structure It also had the disadvantage of poor durability.

Therefore, an object of the present invention is to provide a hearing aid that has a wide audible band, is easy to operate, and has good durability.

[Means for solving problems]

In order to solve the above problems, the present invention provides an electric signal input means for converting an acoustic signal into an electric signal and inputting the electric signal;
an amplification means for amplifying the electric signal; a power source for driving the amplification means; an acoustic signal output means for converting the electric signal amplified by the amplification means into an acoustic signal and outputting the same; and an acoustic signal output means for changing the volume of the acoustic signal. In a hearing aid configured to include a volume change means, the sound signal output means has a wide band and has a low impedance approximately equal to the internal resistance of the power supply, and the volume change means is configured to control the sound signal outputted from the sound signal output means. The sound volume of the sound signal is increased or decreased in steps, and the amplification means is current-driven and has an output impedance that is relatively smaller than the impedance of the acoustic signal output means.

[Effect]

Since the present invention is configured as described above, the frequency characteristics of the hearing aid are improved by the interaction of the low-impedance acoustic signal output means, the digital volume change means, and the low-output impedance amplification means, and the operating time is reduced. It can be shortened.

〔Example〕

Hereinafter, one embodiment of a hearing aid according to the present invention will be described based on the accompanying drawings. In the description, the same elements are denoted by the same reference numerals, and redundant description will be omitted.

FIG. 1 shows an embodiment of a hearing aid according to the present invention. What is different from conventional hearing aids is that the amplification means (B) is a current-driven amplifier (4B) with low output impedance.
), a low impedance voice coil type earphone (5) as an acoustic signal output means (D), and a volume change means (E)
The point here is that a digital variable resistor (6) is used as the resistor. The digital variable resistor (6) is a current-driven amplifier (
4b). In addition, the amplification means (B)
The amplifier (4a) in is a current-driven amplifier (4b)
This is an auxiliary element for increasing the input, and is not an essential element in the present invention. The explanation will be given below.

Figure 2 shows a current-driven amplifier (4b) that can be used in Figure 1.
). FIG. 5A shows an emitter follower type transistor.

Although an NPN type transistor is used in this embodiment, a PNP type transistor or an FET may be used. Same figure (
b) is one in which two transistors are linked together.

When T r 1 is conductive, i flows and charges C3. Next, when T r 2 is conductive, C3 is discharged and 12 flows.

The earphone (5) is activated by this action of 12.

Although this example has been described using a transistor, the current drive type amplifier (4b) may be an FET, an IC, or the like with low output impedance in addition to the transistor.

The earphone of the acoustic signal output means (D) is not limited to the voice coil type, and a wide variety of earphones can be used. The important thing is that the impedance is low.

The digital variable resistor (6) has a resistor (for example, R1
) and switches are connected in series, and multiple combinations of resistors and switches are connected in parallel (see Figure 1). Each resistor (RSRSR
SR) is generally composed of fixed resistors, but the respective resistance values do not have to be the same. Practicality is improved by flexibly increasing or decreasing the degree of increase or decrease in the audible band. For example, the most frequently used range can be secured by operating one switch, the lower range for telephones etc. can be secured by operating a second switch, and the higher range can be secured by a third switch. . Note that this combination of switches is not limited to the one in this example.
A wide variety of things are possible. Further, each resistor used as the variable resistor does not need to be a fixed resistor, and may be, for example, a variable resistor. Variable resistors include carbon-based variable resistors, slide type variable resistors, metal film variable resistors, metal glaze variable resistors, and the like. By using variable resistors as individual resistors, the range of volume that can be varied can be significantly expanded. In this case, each resistance value is set in advance and changed digitally. The important thing is that it uses a digital variable resistor instead of the conventional analog variable resistor.

Note that the combination of the amplifying means (B), the acoustic signal outputting means (D), and the volume changing means (E) in the present invention is not limited to the above.

What is important is that the impedance of the earphone (5) is low, that the output impedance of the amplifier (4b) for driving the earphone (5) is low, and that the variable resistor (4b) that adjusts the output of the earphone (5) is low. 6) is digital.

Note that the power source (C) that can be used in the present invention may be a solar cell that converts the sunlight spectrum and incident light into electrical energy. As solar cells, for example those made of silicon, gallium arsenide or indium phosphide can be used.

In particular, indium phosphide solar cells are useful because they are resistant to radiation and their characteristics hardly change due to temperature changes.

FIG. 3 shows an example of the configuration of a power switch (7) that can be used in the embodiment of the present invention. Below, the same figure (a)
The operating principle will be explained based on the following. When the power supply (C) is ON and switch A is closed, current i3 flows and transistor Q2 is activated.

When transistor Q2 operates, current i4 flows, so
Transistor Q is activated, current i5 flows, and LED lights up. The lighting of this LED indicates that the power is in the input state. Note that even if switch A is opened, current 1 flowing to the base of transistor Q2
7, the self-hold state is maintained and the current i5 continues to flow. When the power supply (C) is in the OFF state, when switch B is closed, currents i and 17 flow to ground, and transistor Q
2 becomes OFF state. Therefore, the current i4 stops flowing and the transistor Q1 is turned off, so the current i4
5 will no longer flow. Therefore, the LED does not light up, indicating that no power is being input.

Note that since this LED is connected in series with the electric circuit, it operates regardless of the degree of consumption of the power source (C).

Figure 3(b) shows the power supply (C) connected to the power switch in Figure 3(a).
) is added with a second LED that lights up when the voltage drops. The principle of operation is essentially the same as in Figure 11-(a), so the explanation will be omitted. As described above, by using a so-called non-contact type switch, it is possible to prevent noise from being amplified at the time of contact and a decrease in clarity.

Further, since it can be used even if there is a contact resistance of several hundred ohms, a rubber switch using conductive rubber with high resistance can be applied, and the feel and durability during use can be improved.

FIG. 4 shows another embodiment of the hearing aid according to the present invention. The difference from the embodiment shown in FIG. 1 is the connection position of the volume changing means (E). In this embodiment, a digital variable resistor (6) is connected in parallel across resistor R5.

FIG. 5 shows experimental data regarding the frequency characteristics of the present invention and the prior art. In the present invention, audio type earphones (
A current-driven transistor with low output impedance was used to match the impedance with the earphone.

On the other hand, in the prior art, a high impedance (coupled impedance 470Ω) is used as an earphone, and a voltage-driven transistor with a high output impedance is used to match the impedance with the earphone.

According to conventional hearing aids, the audible range is 200Hz to 6kHz.
However, the audible band of the hearing aid according to the present invention extends from approximately 50 Hz to 20 kHz as shown in the figure, and the frequency characteristics are significantly improved.

〔Effect of the invention〕

Since this invention is configured as explained above,
The audible band is widened, and the operation time when changing the volume can be shortened. Therefore, the audible band can be easily set depending on the external situation, and hearing ability close to that of a normal human can be ensured.

Additionally, by connecting it to audio equipment such as a telephone or tape record, it is possible to assist in listening to audio signals such as calls and music.

Furthermore, by using paper batteries that are lightweight and have a long life, it is possible to provide an ultra-compact hearing aid with a wide audible band that can be placed directly on the ear.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the hearing aid according to the present invention, FIG. 2 is a diagram showing an example of the configuration of the amplification means in FIG. 1, and FIG. 3 is an example of the power switch in FIG. 1. 4 is a block diagram showing another embodiment of the hearing aid according to the present invention, FIG. 5 is a diagram showing experimental data regarding the frequency characteristics of the present invention and the prior art, and FIG. 6 is a block diagram showing another embodiment of the hearing aid according to the present invention. FIG. 7, a block diagram showing an example of the basic configuration of a hearing aid, is a diagram for explaining a conventional hearing aid. A...Electrical signal input means B...Amplification means C...
Power supply D...Acoustic signal output means E...
Volume changing means 1 Voltage driven amplifier 2 High impedance earphone 3 Analog variable resistor 4 Current driven amplifier 5 Low impedance earphone 6 Digital variable resistor 7・・・Power switch

Claims (1)

[Claims] 1. Electric signal input means for converting an acoustic signal into an electric signal and inputting it, an amplification means for amplifying the electric signal, a power source for driving the amplification means, and a signal amplified by the amplification means. A hearing aid configured to include an acoustic signal output means for converting and outputting an electric signal into an acoustic signal, and a volume changing means for changing the volume of the acoustic signal, wherein the acoustic signal output means has a broadband It has a low impedance that is almost equivalent to the internal resistance of the power supply, the volume changing means increases or decreases the volume of the acoustic signal output from the acoustic signal outputting means in stages, and the amplifying means is current-driven. A hearing aid characterized in that the hearing aid has an output impedance that is relatively smaller than the impedance of the acoustic signal output means. 2. The hearing aid according to claim 1, wherein the amplifying means is a current-driven transistor. 3. The hearing aid according to claim 1, wherein the amplifying means is a field effect transistor. 4. The hearing aid according to claim 1, wherein the volume changing means is a digital switch.