BRPI1002508A2 - electronic and digital noise canceling device to replace audiometric booths for audiometry exams and the like - Google Patents

Abstract

ELECTRONIC AND DIGITAL DEVICE FOR ACTIVE CANCELLATION OF NOISE TO REPLACE AUDIOMETRIC CABINETS IN AUDIOMETRY AND RELATED EXAMS, comprising an acoustic protective cover (1), made of acoustically insulated material accompanied by an adjustable protection arc (la), which covers the earphones by ear. (F) that integrate usual audiological equipment (E), by two external microphones (2), fixed externally on the cover (1), by two internal microphones (3) housed in each of the patient's ears and which monitor the signal that follows the patient's ear, through two probe loudspeakers (4), assembled together with microphones (3), housed between each ear and which send the complement of noise to each ear, and by electronic module (5) digital processing, which monitors the signal that arrives from the diagnostic equipment (E), generating its complement and sending it to each of the patient's ears.

Description

"ELECTRONIC AND DIGITAL DEVICE FOR ACTIVE CANCELING OF NOISES TO REPLACE AUDIO CABINES IN AUDIOMETRY AND RELATED EXAMINATIONS"

The purpose of the present invention is to define a device controlled by electronic and digital circuit that provides noise canceling in the performance of audiological examinations - audiometry and impedanciometry eliminating the use of audiometric booth without prejudice to the final result of the exams and with the ease of that such examinations can be performed in any environment without the need to carry any mechanical noise isolation system. The product of this patent does not require any changes or modifications to existing audiological equipment - audiometer and impedanciometer, together with their accessories - which gives an advantage in terms of integrity in the investments made in these expensive diagnostic equipment.

As is well known in the art, hearing diagnostic equipment is based on sending signals to the auditory system and based on the patient's response to these signals (eg audiometer), one can interpret the capacity of the hearing.

There are three types of audiometry: tonal, vocal and bone audiometry. All examinations are performed with the patient placed in an audiometric booth (Figure 1):

a) Tonal audiometry: The audiometer scans signals in the audio range from low frequencies (eg 125 Hz) to high frequencies (eg 8 kHz), where there is a variation in signal strength ( eg from -10dB to 120dB). These stimuli (signal and intensity) are controlled by the operator (speech therapist or otorhinolaryngologist), who performs the test and sends them to the headset placed on both ears of the patient.

Because these are short-term periodic signals and represent the fundamental frequency, they are called pure tones. The purpose of this exam is to measure the subjective ability to understand elementary sounds.

b) Vocal audiometry (Iogoaudiometry) - the operator turns off pure tone stimulation and speaks words from very close phonetic classes through a microphone in order to measure speech comprehension ability. To prevent lip reading, the operator blocks the patient's visual access through a piece of paper or another. Similarly to tonal audiometry, the voice reaches the patient's ear through the earphone. The purpose of this exam is to objectively measure speech comprehension.

c) Bone or conductive audiometry - instead of using the conventional binaural headset, this exam uses a monaural bone vibrator attached to the skull through a tiara. After performed on one ear (strictly speaking, on the mastoid bone). The purpose of this test is to stimulate the cochlea without the airway and is useful for diagnosing comparisons between the response to the tonal stimulus and bone stimulation. To avoid lateralization (perception of stimuli in the ear that is not being stimulated) the operator can use masking, a type of noise internally generated by the audiometer. In addition, the operator can pass instructions to the individual through the audiometer, such as how and when to respond to stimuli.

All these signals are produced or conducted through the audiometer and reach the individual's earphone. Competitively with these signals are internal sounds, such as internal noise from the audiometric booth (eg sounds from the body itself: breathing, swallowing, heartbeat; fluorescent lamp reactor, and the cab's own reverberation). Such acoustic perceptions distract the individual's attention from the sound stimuli used in the research of tonal thresholds. This scenario is aggravated by the existence of more complex and more difficult to predict external noises (eg noise of people talking, footsteps, passing cars, air conditioning, horns, machines, among others). Although there is acoustic insulation inside the cabs, this isolation is passive, ie if there is a change in signal format (internal or external) there is no device that can act actively, which will suppress it in order to not interfere with the progress of the exam.

In addition, the audiometric booth has some disadvantages: it definitely takes up physical space, requires maintenance and is not transportable, and represents a considerable purchase cost. Audiologists who perform services in various locations often complain that they must pass the audiometer cables, along with the headphone cables through the cab, and complain about the noise level from unruly, old or poorly designed cabs, inefficient door locks , noisy indoor fluorescent lamp reactors, among others.

Indeed, speech therapists are unable to dismantle, load and use their own booths and are at the mercy of booths that are available in these workplaces, which depending on external noise may lead to errors in patient responses. Additionally, audiometers are regularly calibrated along with their earphones and only this set (audiometer and earphone) should be used to represent a sound stimulus pattern.

With this scenario in mind and with the firm purpose of overcoming the problems described here, an electronic and digital device for active noise cancellation has been developed to replace audiometric booths in audiology equipment and the like. This electronic device advantageously replaces the use of audiometric cabs because it is portable and does not require any changes to the audiometer or headset.

To this end, the present invention is composed of the electronic device itself and a protective cover, preserving the original architecture of the audiology equipment in its original format.

The external acoustic protective cover is designed to improve the individual's acoustic insulation from the environment. It has proportions that allow the original earphone to be housed inside, without prejudice to its functions or causing discomfort to the patient. It can be adjusted according to the anatomy of each individual through a tiara, so that the pressure on the sides of the head is fixed, causing no discomfort during the exams. A material of high acoustic insulation coefficient based on polyester polyurethane is used in the internal acoustic insulation of the protective cover.

The device detects the internal and external signals of the booth and creates its complement, be it its symmetrical signal and injects it into the headset, in order to electronically and actively cancel out such external signals. The protective cover, in turn, is highly acoustic insulated, and further assists in the task of acoustic insulation, made of insulated acoustic material and in proportions allow the original earphone to be housed inside, without prejudice to their functions or that causes discomfort to the patient.

The signals produced by the usual audiology equipment are sent directly to the headphones that integrate it. Outside the acoustic protective cover are two microphones that pick up the ambient sound and send it to the digital electronic device, which analyzes the ambient signal (format, intensity, duration, timbre, etc.).

Two other microphones continuously monitor the amplified signal going to the patient's ear. The digital electronic device identifies what is desirable and what is not, being generated internally the same signal of noise (shape, amplitude, intensity), but 180 ° out of phase which is sent to two micro speakers. The sum of two complementary signs is zero. The micro speakers are mounted together with the two microphones. There are no adjustments or adjustments as the signal is continuously monitored by an electronic and digital circuit.

In short, the digital electronic device circuit actively and electronically cancels out external noises, while the acoustic protective cover passively reduces the incidence of noise in the patient's ear during audiometric examinations. The combined action of both (digital electronic circuit and the protective acoustic cover) allows the reduction of up to 95% of noise outside the audiological examination, far exceeding the values observed only with the audiometric booth.

Also, there is no change in the original equipment either in the audiometer or in the headphones. After the exam, simply remove the acoustic protective cover, the micro speakers and turn off the electronic device. It can be plugged into the mains or even with rechargeable batteries, showing versatility and portability to any location.

Although the proposed system has been described for use in audiometers, nothing prevents it from being used on other equipment (eg impedance meter), or even non-medically, to eliminate external noise. For generating noise without therapeutic purposes do not require registration with the National Health Surveillance Agency.

By way of illustration, attached are drawings of the present invention through which it will be better visualized:

Figure 1 schematically illustrates the state of the art with the usual audiometric examination equipment and the audiometric cabin;

Figure 2 schematically illustrates the digital device now innovated;

Figure 3 is a partial perspective view of the acoustic protective cover incorporating the object of the present invention, schematically illustrating one of the headphones housed therein;

Figure 4 shows schematically the flow of electrical signals that occur during an audiological examination performed using the device now innovated;

Figure 5 is the block diagram of the electronic circuit provided for in the present digital electronic device. The subject-matter of the present invention is an "Electronic and digital device for active noise cancellation to replace audiometric booths for audiometry and related tests", comprising an acoustic protective cover (1), made of acoustically isolated material accompanied by an acoustic isolation device. adjustable protection (1a), which covers the headphones (F) that incorporate usual audiological equipment (E), by two external microphones (2), fixed externally on the cover (1), by two internal microphones (3) housed in each of the patient's ears and monitoring the signal that follows the patient's ear through two probe speakers (4), assembled together the microphones (3), housed between each ear and sending the noise complement for each ear, and by an electronic digital processing module (5), which monitors the signal coming from the diagnostic equipment (E), generating its complement and sending it to each of the patient's ears. entente.

The signals (Au) exiting the audiometer (E) reach the ear via the standard earphone (not shown), which is supplied with the audiometer (E); external microphones (2) located on the outside of the protective earbud (1) that cover the standard headphone (F) monitor the surround sound and send these signals (ur) to the electronics module (5); the internal microphones (3) inserted between the ears and the standard headset (F) monitor the signal perceived by the individual: these signals (ui) are sent to the individual's ear; the digital electronic device (5) continuously analyzes all these signals - Au, ur and ui - and as soon as it perceives the presence of impure signals to the system, it immediately identifies it and generates its complement (Ai), sending it through the highs. speakers (4) arranged in conjunction with the internal microphones (4).

According to the block diagram described (Figure 5), signals from the audiometer and part of the noise that reach the patient's ear - "if (t)" - pass through a microphone that will transduce the acoustic signals into electrical signals; These electrical signals then pass through an A / D analog to digital converter and are then identified by high frequency modulated digital pulses "s (t)" which vary according to the input signal "if (t)"; "ne (t)" external noises are picked up by external microphones (2), pass through a microphone and go to the A / D analog to digital converter and are then identified by high frequency modulated digital pulses "n (t) "and vary according to the input signal" ne (t) "; a derivation of external noises "no (t)" is sampled by sampler circuit σ, whose sampled signals are summed in summing circuit Σ1, producing "so (t) + no (t)".

External noises "n (t)" provide reference to the actuation of the programmable digital filter AF, which seeks to generate symmetrical signals "-b (t)" to "no (t)" signals; a summing circuit Σ2 adds "s (t)" and "no (t)" with the signal "-b (t)", obtaining "s (t) + no (t) - b (t)". Ideally, the signals "no (t)" and "-b (t)" have identical dynamic behavior, have the same amplitude but are lagged by 180 ", so they do not cancel out immediately due to the dynamics of external noise. However, the signal "s (t) + no (t) - b (t)" is sent to an estimator circuit ρ, which also receives the signals "n (t)" and which adjust the programmable digital filter AF at a first If elimination does not occur on the first interaction, the estimator ρ again acts, causing the second interaction, and so on until "no (t) is equivalent - ideally - symmetrical to the signal" -b (t) ". As soon as the noise of the "s (t)" signal is eliminated, it should be returned to its acoustic format via the D / A converter.

Interactions for noise elimination will be finite and should not introduce delays that disturb the progress of the audiological test. The "if (t)" signals will not change due to digital processing, maintaining their integrity - frequency, phase and amplitude - throughout the processing. However, due to the dynamics of noise, it is not expected that noise will be completely eliminated, but a reduction of at least 80%, which forces some noise residue on the signal going to the ear, and the output signal is agreed by " if '(t) ".

Claims (3)

1. "ELECTRONIC AND DIGITAL DEVICE FOR ACTIVE CANCELING OF NOISES FOR REPLACING AUDIO CABINES FOR AUDIOMETRY AND RELATED EXAMINATIONS", WHICH IS INCLUDED BY AN ACOUSTIC INSULATED PROTECTIVE MATERIAL WITH ARCHIVE PROTECTIVE ARC (la), which covers the headphones (F) that incorporate usual audiological equipment (E), by two external microphones (2), fixed externally on the cover (1), by two internal microphones (3) housed in each one. of the patient's ears and monitoring the signal following the patient's ear through two probe speakers (4) assembled together the microphones (3) housed between each ear and sending the noise complement to each one of the ears, and by an electronic digital processing module (5), which monitors the incoming signal from the diagnostic equipment (E), generating its complement and sending it to each of the patient's ears. 2. "ELECTRONIC AND DIGITAL DEVICE FOR ACTIVE CANCELING OF NOISES FOR REPLACING AUDIO CABINES IN AUDIOMETRY AND RELATED EXAMS" according to claim 1, characterized in that the signals (Au) coming from the audiometer (E) reach the ear via the standard headset (not shown), which is supplied with the audiometer (E); external microphones (2) located on the outside of the protective earbud (1) that cover the standard headphone (F) monitor the surround sound and send these signals (ur) to the electronics module (5); the internal microphones (3) inserted between the ears and the standard headset (F) monitor the signal perceived by the individual: these signals (ui) are sent to the individual's ear; the digital electronic device (5) continuously analyzes all these signals - Au, ur and ui - and as soon as it perceives the presence of impure signals to the system, it immediately identifies it and generates its complement (Ai), sending it through the highs. speakers (4) arranged in conjunction with the internal microphones (4). 3. "ELECTRONIC AND DIGITAL DEVICE FOR ACTIVE CANCELING OF NOISES FOR REPLACING AUDIO CABINES FOR AUDIOMETRY AND RELATED EXAMS" according to claim 1, characterized by signals from the audiometer and part of the noise that reach the patient's ear - " if (t) "- pass through a microphone that will transduce the acoustic signals into electrical signals; These electrical signals then pass through an A / D analog to digital converter and are then identified by high frequency modulated digital pulses "s (t)" which vary according to the input signal "if (t)"; "ne (t)" external noises are picked up by external microphones (2), pass through a microphone and go to the A / D analog to digital converter and are then identified by high frequency modulated digital pulses "n (t) "and vary according to the input signal" ne (t) "; a derivation of the external noises "no (t)" is sampled by the sampler circuit σ, whose sampled signals are summed in the summing circuit Σ1, producing "so (t) + no (t)"; external noise "n (t)" provides reference to the actuation of the programmable digital filter AF, which seeks to generate symmetrical signals "-b (t)" to "no (t)" signals; iam summing circuit Σ2 adds "s (t)" and "no (t)" with the sign "-b (t)", obtaining "s (t) + no (t) - b (t)"; Ideally, the signals "no (t)" and b (t) "have identical dynamic behavior, have the same amplitude, but are 180 ° out of phase, so they do not cancel out immediately due to the dynamics of external noise; (t) + no (t) - b (t) "is sent to an estimator circuit ρ, which also receives the signals" n (t) "and which adjusts the programmable digital filter AF on a first interaction; occurs at the first interaction, the estimator ρ again acts, causing the second interaction, and thus consecutively until "no (t) is equivalent - ideally - symmetrical to the signal" -b (t) "; As soon as the noise of the signal "s (t)" is eliminated, it must be returned to its acoustic format via the D / A converter; Noise elimination interactions will be finite and should not introduce delays that disturb the progress of the audiological test; "if (t)" signals will not be altered due to digital processing, maintaining their integrity - frequency, phase and amplitude - throughout the processing; however, due to the dynamics of noise, it is not expected that noise will be completely eliminated, but a reduction of at least 80%, which forces some noise residue on the signal going to the ear, and the output signal is agreed by " if '(t) ".