DE19623871A1 - Statistical phase analysis of oto-acoustic emissions method, for acoustic screening - Google Patents

Abstract

The method detects the presence of oto-acoustic emissions at different, freely selectable frequencies, according to a statistical criterion of the signal and with a definable probability of error. The method can be designed for use with transiently aroused oto-acoustic emissions or with distortion product oto-acoustic emissions. The measurement result can be achieved without a fixed number of measurement cycles, with interim measurements continually calculated to minimise the measurement time, with automatic cessation of measurements when a specific probability of error is achieved.

Description

OAE are signals from the hair cells of a functional inner ear the non-linear properties of the cochlear amplifier due to acoustic stimuli be generated.

DPOAE's arise from the stimulation with two tones of different frequencies. The intermodulation products created on the cochlear are combined with a Microphone measured, amplified, using the Fourier transform to specific mix frequencies examined. This technology is already used in conventional devices a wide frequency range, but it is not an automatic evaluation of the results known.

The basis of the invention is a phase analysis described below, which is in contrast to the conventional methods of frequency and amplitude analysis offers for an automatic evaluation.

Two aspects are essential when measuring and evaluating OAE.

1. The separation of the stimulus from the signals to be measured

There are various ways to do this:

• - Time domain separation:
  If the stimulus is very short (transient stimulus), the measurement window can be selected so that the passive echo from the ear canal has already subsided when the response is recorded. This ensures that the measured acoustic signals only consist of stimulus-independent noises and possibly the OAE evoked by the stimulus and contain no components of the stimulus itself or its echo. The responses measured in this way are called transient evoked OAE (TEOAE).
• - Separation in the frequency domain:
  If continuous sinus tones are applied as the stimulus, the sound signals generated by the inner ear can be separated from the stimulus by examining the frequency ranges outside the tone frequencies of the stimuli. Since intermodulation products of the primary frequencies are generated by the nonlinearity of the functional inner ear, the presence of signals whose frequencies do not correspond to the stimulus signals ("clang") is crucial for the proof of the integrity of the inner ear. These signals are called otoacoustic distortion products (DPOAE).

2. Evidence of the answer

Evidence is essential for the interpretation of the measured acoustic signal for the fact that it is actually a signal from the inner ear and not Noise from the surroundings. All systems that are currently used for measurement take advantage of the fact that the responses generated by the stimulus in contrast to the noise are phase-synchronized with the stimulus. Usually through  an averaging technique (stimulus-synchronous averaging) the signal to be measured for so long towards the noise amplified until it is emitted by an experienced examiner is to be identified. A frequently used help is to measure the "rest noise "and to compare the averaged signal with this residual noise. If the difference between the two signals is high, it is stimulus-synchronous To accept activity.

Screening

For a filter examination (screening) the discovery of inner ear activity should be be possible automatically and without the judgment of an expert. This is a non parametric signal statistics required, in addition to the result "emission present" an exact measure of the probability of error. In this way precisely define the quality of the measurement in relation to the error rate.

Phase analysis

Each period of time for evaluation contains a mixture of different ones Signals of different frequency, amplitude and phase. These signals can be by a transformation into the frequency space (Fourier transformation) from each other separate.

B Captions

Fig. 1 noise - uniform distribution in the vector plane

Fig. 2 noise with a constant signal superimposed in the vector plane

Fig. 3 block diagram of a screening device for measuring, evaluating and evaluating DPOAE's by means of phase analysis

Fig. 4 block diagram of a screening device for measuring, evaluating and evaluating TEOAE's by means of phase analysis

C measuring device with phase analysis for distortion products (DPOAE)

An essential property when evaluating the distortion products is the fact that the frequencies at which an inner ear response is to be expected are known because it is the intermodulation products of the applied primary frequencies. Experience has shown that the answer with the highest amplitude arises at a frequency from 2f₁-f₂ (3rd order intermodulation product) if f₂ is approximately equal to 1.2 * f₁.

For this frequency (or other intermodulation products) the phase analysis carried out as follows:

• 1. Signal sections of fixed length are continuously formed for which the phases of the two primary signals must each have a constant value.
• 2. These sections are individually subjected to a Fourier transformation (discrete for the selected Frequency or FFT). Amount of the frequency to be analyzed and phase and thus the associated vector in the phase diagram.  
• 3. The statistical zero hypothesis is:
  "The phases of the vectors of all signal sections are evenly distributed over the entire angular range between 0 and 360 degrees."
  This uniform distribution corresponds to a purely random noise without reference to the phases of the primary signal. See Figure 1
• 4. If this null hypothesis succeeds at a defined level of significance with the corresponding probability of error, it can be assumed that at the frequency examined a phase-synchronous signal and thus a Answer from the inner ear is present. To do this, the coordinate plane of the vector is divided into two Halves divided. For these two halves is based on binomial statistics the significance test was carried out: each phase value is examined to determine whether it lies in one or the other half of the coordinate plane. In the first case the statistical reference value increased by 1, in the other case decreased by 1. By the root of the sum S divided from the number of individual experiments is fixed with the truth Probability correlates to the fact that it is only an equal distribution. For example, if the value S = 3.08 is reached, there is a residual probability of p = 0.001 for the fact that there is only no phase syn chronic noise.
• 5. Part of the analyzed sections is now used to obtain the angle in the phase diagram over which the uniform distribution is tested, ie by which the coordinate plane is divided. For this purpose, the vector sum of the individual frequency vectors is formed with these sections. The phase angle of the sum vector + 90 degrees (mod 360 degrees) is the angle of the division line through the coordinate origin. See Figure 2
  The sections used to calculate the phase angle must not be included in the statistics described under point 4 for reasons of signal statistics. However, since the analysis should be carried out continuously to enable automatic termination when the specified significance criterion is reached, the following route is proposed.
• 6. The signal sections alternately serve to form the sum for defining the angle and testing for equal distribution. Because the defined angle is after each second section changes, the angle values used for testing must be saved remain constant and constantly compared with the current reference angle division to be tested.
• 7. The measurement is aborted
• - when the significance criterion is reached, i.e. when the null hypothesis "no stimulus syn chronic signal present "rejected with the previously defined significance can be or
• - If the always recalculated reference phase angle does not fall within the specified one Boundaries converge  or
• - if after a predetermined number of examined signal sections the significance a predetermined value for the rejection of the null hypothesis was not reached.

In the last two cases, the measurement is aborted with z. B. "fail" (that is, a signal could not be detected from the inner ear), in the first of the three cases with e.g. B. "pass" (positive signal detection).

A basic circuit diagram is shown in Fig. 3. Such a device consists of 2 stimulus generators ( 1 ) with associated sound transmitters ( 2 ). The frequency product generated by the cochlea is measured using the microphone ( 3 ) and fed to an input amplifier ( 4 ). The mixed products are examined for their frequency components with the aid of a frequency analyzer ( 5 ). The phase analyzer ( 6 ) described above enables statistical evaluation. The result is shown on a display ( 7 ) and / or output or processed on a printer or PC.

D Measuring device with phase analysis for transient evoked emissions (TEOAE)

A broad frequency band is emitted at TEOAE; so that is an investigation of the Phase statistics possible for any frequency. The process of statistical testing can therefore be the same as for the detection of DPOAE. Is sent ahead a measuring section in which the frequencies to be examined are determined.

This is possible, for example, as follows:
Several intervals are formed in the frequency range (for example 500-1000 Hz, 1000-2000 Hz, 2000-4000 Hz). The signal sections to be processed are alternately written into two buffers (memory) A and B. Now for each frequency according to paragraph C5. the vector of the sum of A and B is formed. The vector for the difference between A and B is also calculated as the reference quantity. The frequencies in each predetermined interval at which the greatest difference exists between the vector of the buffer sum and that of the buffer difference are used for the analysis. After that, the further procedure is completely identical to that described for the DPOAE.

To abort the measurement by e.g. B. "pass" is required for each of the above Given frequency intervals, at least one value meets the specified significance criterion reached.

A basic circuit diagram is shown in Fig. 4. Such a device consists of 1 stimulus generator ( 9 ) with associated sound transmitter ( 10 ). The frequency mixture generated by the cochlea is measured with the aid of the microphone ( 11 ) and fed to an input amplifier ( 12 ) and downstream filter ( 13 ) and then alternately stored in different memories ( 14 ). In the vector analyzer ( 15 ) an automatic evaluation takes place through the formation of sums and differences. The result is shown on a display ( 16 ) and / or output or processed on a printer or PC.

Claims (15)

1. A method for automatic frequency-specific hearing test with the help of otoacoustic emissions (OAE), characterized in that the presence of OAE at different freely selectable frequencies according to a signal statistical criterion with a definable error probability can be demonstrated. 2. The method according to claim 1, characterized in that it is for use is configured for transiently evoked otoacoustic emissions. 3. The method according to claim 1, characterized in that it is for use is configured for distortion product OAE. 4. The method according to claim 1, characterized in that to achieve a fixed number of measurement cycles is not specified for a measurement result, Instead, intermediate results are continuously calculated to minimize the measuring time and when a predetermined error probability is reached Measurement is aborted automatically. 5. The method according to claim 1, characterized in that freely selectable Components of the complex spectrum determined by Fourier transformation a predetermined time interval on the basis of a signal statistical Analysis to be made. 6. The method according to claim 5, characterized in that at freely selectable Frequencies the sum of the vectors of the spectral components in the complex Space is determined in order to formulate a statistical null hypothesis and determine a preferred direction in complex space. 7. The method according to claim 5, characterized in that corresponding to the preferred direction of the complex calculated according to the method in claim 6 Space is divided into 2 disjoint areas. 8. The method according to claim 5, characterized in that the phase vectors the Fourier transform of the individual signal sections each one of the are assigned to two areas determined according to claim 7 and be analyzed using the mathematical means of binomial statistics. 9. The method according to claim 1, characterized in that each after one Method calculated in claim 5 component of a certain quality class is assigned. 10. The method according to claim 8, characterized in that the mathematical Statistics separately for those formed by the method in claim 9 Quality classes is carried out.   11. The method according to claim 1, characterized in that the evaluation automatically with the help a microprocessor. 12. The method according to claim 1, characterized in that for evaluating the results none on the screen displayed results and waveforms must be interpreted and the Results display with "noticeable" and "not noticeable" is executed. 13. The method according to claim 1, characterized in that the device as a hand-held, portable (without PC screen), network-independent device. 14. The method according to claim 1, characterized in that the results via a printer interface can be documented. 15. The method according to claim 1, characterized in that for further evaluation of results an interface a PC can be connected.