FR2752321A1 - METHOD AND DEVICE FOR TEACHING LANGUAGES - Google Patents

Abstract

The invention concerns a method and a device for teaching a language to a subject in which: a sound transmission is transformed into a first electric signal representing said transmission; a first filter (14) produces a second electric signal modified according to parameters representative of the language to be taught; a second filter (15) produces a third electric signal modified according to parameters representative of the language to be taught and parameters representative of the sound transmission; vibrations produced from the first, second or third signals are selectively applied to the subject's auditory organs. The selective application depends on the sound transmission envelope and on the (right- left) side of the auditory organs.

Description

 The invention relates to a method and a device for teaching a language to a subject.

 It has long been shown that language teaching can be facilitated by the use of methods and devices modifying a sound emission to produce modified vibrations applied to the subject.

 These vibrations can be either aerial vibrations such as those produced by loudspeakers and headphones, or bone vibrations such as those produced by a vibrator in contact with the skull of the subject. It is possible and advantageous to subject the subject simultaneously to bone vibrations and to aerial vibrations.

 The applicant himself has published numerous works on this subject and with regard to language teaching, his patent FR-A-2,546,323 proposes to make the comparison between a reference sound and the sound pronounced by the subject and to emit a signal when the difference between these two sounds is greater than an adjustable threshold.

 Furthermore, by its patent FR-A-2,672,412, he proposed to subject the sound emission of the subject to two separate treatments, the first treatment being a function of the bandwidth of the language to be learned, the second treatment being a function both of this same bandwidth and of the language and harmonic content of the subject's broadcast. Depending on the amplitude of the signal emitted by the subject, one or other of the signals resulting respectively from the first treatment or from the second treatment was applied, by air conduction, and possibly by bone conduction to the subject.

 In this known process, the two signals are applied concomitantly to the hearing organs of the subject via two channels and flip-flops, without taking into account the morphological faculty of the individual linked to the process of operation of the two hemispheres cerebral.

 These methods and devices of the prior art give satisfactory results and have enabled individuals to learn one or more foreign languages under good conditions.

 However, the object of the present invention is to further improve the conditions for learning foreign languages.

 This is what the invention proposes.

 Thus, the invention relates to a method for teaching a language to a subject in which a sound emission is transformed into a first electrical signal representing said emission, a first processing produces a second electrical signal from the first electrical signal, the latter being modified as a function of the parameters representative of the language to be taught, a second processing produces a third electrical signal from the first electrical signal, the latter being modified as a function of the parameters representative of the sound emission, selectively applied to the subject's hearing organs vibrations produced from the first, second or third signals.

 According to the invention, the selective application depends on the level of an envelope of the sound emission and on the side (right-left) of the hearing organs.

 The sound emission can come from the subject himself, from a teacher or from a recording.

 This process takes into account the mechanisms of auditory perception and at the same time the operating processes of the two cerebral hemispheres.

 When the ears are about to listen, one of them dominates the other and selects the sounds contained in the vibrations. This mechanism is analogous to that encountered in the mechanism of vision. A predominant eye in the observation of a scene; however, the other eye does not remain inactive, it is about to see. Two eyes therefore contribute to vision, but only one aims.

 It is the same for the ears, the two hear, but only one of them listens. In the generality of the cases, it is the right ear which is registered like active element of aiming of the sounds, it thus becomes the directing ear. The second ear, generally the left, remains operational but it does not force itself to focus. The sounds are in a way focused, therefore perceived by the right ear and felt as a whole by the left ear.

 These differentiated activities of the two ears correspond to those of the two brains. The left brain plays the role of the performer, receiving information and sending it back, while the right brain supervises the proper execution of the activities of the left brain. The right brain controls the execution of the orders it transmits to the left brain and ensures that they comply with its wishes.

 It is known that the modification of the vibrations to which the auditory organs are subjected causes a modification of the subject's vocal expression. To ensure control of the various parameters of vocal expression, such as the pitch, the timbre, the semantic flow of speech which ensure a good command of the language, the information provided to the right brain must be wide. Thus, it acts on the entire hearing of the left ear, which, when listening, benefits from a transition from a state of relaxation to a state of total listening. Everything happens as if the left ear abandoned itself to an infinite hearing (or punctum remotum) to reach in a second step, after accommodation or close point or (punctum proximum).

 The right ear, that of aiming, The directing ear therefore, has a similar gait, but different from that of the left ear, insofar as it too passes from a non-listening, fixed state at the punum remotum, at a specific listening, that chosen for languages.

In different embodiments, each presenting their specific advantages, the method of the invention includes the following characteristics, possibly taken in combination:
- The sound emission is the voice of the subject himself.

 - The sound program is the voice of a teacher.

 - The parameters representative of the language to be taught are its spectral distribution and its envelope curve.

 - The first signal is used to apply vibrations to both the right and left side of the subject when the envelope of this first signal has a level below a reference level and the second and third signals are used to apply vibrations respectively on the right side and on the left side when the envelope of the first signal is greater than said reference level.

 - When the level of the envelope of the first signal rises, beyond the reference level, a delay is introduced before the vibration applied to the subject changes.

 - The excitation of the auditory organs includes a bone excitation and an air excitation.

 - A precession is introduced between the changes in vibrations applied respectively to bone excitation and to air excitation.

 The invention also relates to a device for teaching a language allowing the implementation of the method of the invention.

 This device comprises means for transforming a sound emission into a first electrical signal representing said emission, a first filter producing a second electrical signal from the first electrical signal, the transfer function of this filter depending on parameters representative of the language. to teach, a second filter producing a third electrical signal, the transfer function of this filter depending on the parameters of the sound emission produced by a processing unit, means for the selective application of vibrations to a subject.

 According to the invention, flip-flops make it possible to apply vibrations depending on the level of an envelope of the sound emission and on the side (right-left) of the hearing organs.

According to different embodiments, each presenting their specific advantages, the device of the invention has the following characteristics, possibly taken in combination:
- It includes vibrators and headphones,
- It comprises delay means introducing a delay between the moment when the envelope of the sound emission passes a reference level and the change in vibrations.

 - It comprises precession means introducing a delay between the change of the vibrations emitted by the bone vibrators and the change of the vibrations emitted by the aerial vibrators.

 - The first filter is associated with a memory allowing to vary its characteristics according to the language to be studied.

An embodiment of the invention will be described in more detail with reference to the drawings in which:
Figure 1 shows a flow diagram of the device of the invention.

 Figure 2 represents a particular case of sound envelope and the functioning of the flip-flops produced.

 Figure 3 shows a particular example of a transfer function for the first filter.

 Figure 4 shows a particular example of the transfer function of the second filter.

 Figure 5 shows a flowchart of the device of the invention in a second embodiment.

 As shown in Figure 1 a first electrical signal flows through the conductor 1. It is produced either by a microphone 2 receiving a sound message emitted by the subject 3 or by a teacher, or by a tape recorder or any other source of recording 4. The signals, whether emitted by the microphone 2 or by the recording source 4, are then amplified by an amplifier 5 to provide the first electrical signal.

 Thus, this first electrical signal can correspond either to the sound emission of the subject himself, or to another sound emission such as that of a teacher for example.

 This first electrical signal is used to produce vibrations applied to the hearing organs of the subject 3 via the speakers or headphones 6, 7 producing aerial vibrations or by vibrators 8, 9 producing bone excitations.

 Air excitation is produced by the flip-flop 10 for the right ear, by flip-flop II for the left ear. Bone excitations are produced respectively by rocker 12 for right excitation and by rocker 13 for left excitation.

 Each of the flip-flops receives two different signals as input. These inputs are referenced respectively 101, 102 for the flip-flop 10,111,112 for the flip-flop 11,121,122 for the flip-flop 12, 131, 132 for the flip-flop 13. The outputs of the flip-flops respectively 103, 113, 123 and 133 receive the signals coming from one or the other of the two inputs as a function of a control signal received by the controls 104, 114, 124 and 134. Amplifiers 105, 115, 125 and 135 adapt the intensity of the signal leaving the flip-flops 10, 11, 12, 13 to the headphones or vibrators 6 to 9.

 The signals at the input of flip-flops 10 to 13 have three different origins, either directly the line 1 carrying the first electrical signal, or the output 141 of a filter 14, or the output 151 of a filter 15.

 Filters 14 and 15 receive the first signal as input on line 1 and respectively produce a second electrical signal for filter 14 and a third electrical signal for filter 15.

 These second and third electrical signals depend on the transfer function of the filters 14 and 15.

 The transfer function of the filter 14 depends on the parameters representative of the language to be taught. These parameters are stored in a memory 142 provided for this purpose and controlling the transfer function of the filter 14. The transfer function of the filter 15 depends on the parameters representative of the sound emission represented by the electrical signal 1.

 To this end, the electrical signal 1 is analyzed by an electronic module 16 which extracts its envelope and its spectral distribution.

These parameters are transmitted to the processing unit 17 which addresses them to the memory 153 of the filter 15. The memory 153 of the filter 15 determines its bandwidth.

 One of the inputs 132, 122, 112, 102 of each of the flip-flops 10 to 13 directly receives the first electrical signal supplied by the line 1.

 The second inputs of flip-flops 10 and 12, connected respectively to the vibrator and listener 6 and 8 intended for the excitation of the subject's left hearing organs, receive the third signals modified from the first signals by the transfer function of the filter 15.

 The second inputs of flip-flops II and 13, whose output signals control the excitation of the subject's right hearing organs receive the second signal produced from the first electrical signal 1 by the transfer function of the filter 14.

 The commands 104, 114, 124, 134 are activated by the delay 18 and precession 19 modules respectively.

 These modules 18 and 19 control the flip-flops at a determined time from the moment when the envelope of the electrical signal 1 as produced by the module 16 exceeds an adjustable reference threshold.

 The comparison between the level of the envelope and the reference threshold is carried out by a comparator 17a which includes in a memory 171 the reference level. This reference level is adjustable from an external control 172 of the device.

 From this moment, when the envelope of the electrical signal 1 exceeds the reference level, the delay module 18 applies a first delay controllable from the outside by the potentiometer 181 and the module 19 adds to this first delay a controllable precession from the outside by potentiometer 191.

 The delay module 18 controls the flip-flops 12 and 13 and the precession module 19 controls the flip-flops 10 and 11.

 The operation of the device described above is therefore as follows. The envelope of the curve of the first electrical signal has been shown in Figure 2, the abscissa axis represents time and the ordinate axis an amplitude. At the start of the transmission, in zone 32, the level of the envelope 31 is lower than the reference level Ao. The flip-flops 10 to 13 are then in their starting state and the first electrical signals received on their respective inputs 102, 112, 122 and 132 are then sent after amplification by the amplifiers 105, 115, 125 and 135 to the sound excitation means 6 to 9. The subject therefore receives a signal directly representing the sound signal emitted without transformation.

 When the amplitude of the sound signal emitted increases and its envelope exceeds the reference level, Ao corresponds to the entry into the time zone 33, after a delay At predetermined by the command 181 of the delay 18, this delay 18 controls the flip-flops 12 and 13 and therefore during the time period 34, the bone vibrators 8 and 9 are excited by the transformed signals, respectively the second signal transformed by the filter 14 for the right bone vibrator 8 and the third signal transformed by the filter 15 for the left bone vibrator 9.

During this period 34, the aerial vibrators 6 and 7 always receive the first unprocessed electrical signal transmitted by the line 1. After the complementary delay or precession p defined by the delay 19 commanded by the command 191, that is to say in period 35, the flip-flops 10 and 11 controlled by the delay 1 9 having changed state, the aerial vibrators 6 and 7 also receive the signals modified by the filter 15 for the right aerial vibrator 6 and by the filter 14 for the vibrator left aerial 7.

 In FIG. 2, the state of flip-flops 12 and 13 controlled by the delay 18 has been represented at 37 and the state of flip-flops 10 and 11, controlled by the precession delay 19 has been represented at 38.

 When the envelope 31 of the first electrical signal decreases, as soon as this amplitude is less than the reference amplitude Ao, the comparison unit 17 addresses the delay 18 and 19 the signals implying the return of the flip-flops 10 to 13 in their resting state. This is what happens during the time period 36.

 As an indication, an example of bandwidth 201 of a filter 15 acting on the left part of the subject and corresponding to the normal ear obtained by a Fleichner-Munsen filter has been shown in FIG. 3 and of bandwidth 202 of a filter corresponding to a particular language for the filter 14 acting on the right side of the subject, has been represented in FIG. 4.

 In each of these Figures 3 and 4, the frequencies have been represented on the abscissa and the amplitude on the ordinate.

 The Fleichner-Munsen filter is conventionally defined in relation to the minimum perception threshold, either of individuals taken as reference, the results being averaged, or of the subject himself. The curve of the minimum perception threshold as a function of frequency is established. It is then inverted to obtain the bandwidth of the filter. Thus, the frequencies for which the perception threshold is low are more attenuated than those for which it is high.

 This device and this process therefore allow the subject to perceive either directly the sound emission that he is studying, or a transformed emission, this transformation being different on the right and on the left. This functioning is in harmony with the functioning of the brain and makes it possible to optimize the teaching of languages.

 In certain embodiments of the invention, when using the device, the subject observes an image produced on a screen. This image can be either his own image, that of a professor or both. Observation of the face and more particularly the movements of the lips then facilitates learning.

For some applications, it is desirable to apply different delays and precessions to the right and left auditory organs. The corresponding device has been represented on the
Figure 5. The elements of this device identical to those of the
Figure 1 are represented in the same way and use the same numbering. The delay modules 58 and 59, placed in parallel on the delay 18 and precession modules 19, receive the signal leaving the processing unit 17.

 The delay module 18 and the precession module 19 respectively control the flip-flops 10 and 12 and they alone.

The delay 58 and precession 59 modules controllable by potentiometers 581 and 591 control the flip-flops II and 13.

 Thus, delays and precessions are independently adjustable for the right and left hearing organs.

Claims (13)

 1. Method for teaching a language to a subject in which:  a sound emission (2) is transformed into a first electrical signal representing said emission,  a first processing produces a second electrical signal from the first electrical signal, the latter being modified as a function of parameters representative of the language to be taught,  a second processing produces a third electrical signal from the first electrical signal, the latter being modified as a function of the parameters representative of the sound emission,  - vibrations produced from the first, second or third signals are selectively applied to the hearing organs of the subject,  characterized in that the selective application depends on the level of an envelope of the sound emission and on the side (right-left) of the hearing organs.  2. Method for teaching a language to a subject according to claim 1, characterized in that the sound emission is the voice of the subject himself.  3. Method for teaching a language to a subject according to claim 1, characterized in that the sound emission is the voice of a teacher.  4. Method for teaching a language to a subject according to any one of claims 1 to 3, characterized in that the parameters representative of the language to be taught are its spectral distribution and its envelope curve.  5. Method for teaching a language to a subject according to any one of claims 1 to 4, characterized in that the first signal is used to apply vibrations to both the right side and the left side of the subject when the envelope of this first signal has a level below a reference level and the second and third signals are used to apply vibrations respectively to the right side and to the left side when the envelope of the first signal is greater than said reference level .  6. Method for teaching a language to a subject according to claim 5, characterized in that when the level of the envelope of the first signal rises, beyond the reference level, a delay is introduced before changing the vibrations applied to the subject.  7. Method for teaching a language to a subject according to any one of claims 5 and 6, characterized in that the excitation of the auditory organs comprises a bone excitation and an air excitation.  8. A method for teaching a language to a subject according to claim 7, characterized in that a precession is introduced between the changes in the vibrations applied respectively to the bone excitation and to the air excitation.  9. Device for teaching a language comprising:  means (4, 2) for transforming a sound emission into a first electrical signal representing said emission,  - a first filter (14) producing a second electrical signal from the first electrical signal, the transfer function of this filter depending on parameters representative of the language to be taught,  - a second filter (15) producing a third electrical signal, the transfer function of this filter depending on parameters representative of the sound emission produced by a processing unit  - means (6, 9) for selective application of vibrations to a subject,  characterized in that rockers allow (10, 13) to apply vibrations depending on the level of an envelope of the sound emission and on the side (right-left) of the hearing organs.  10. Device for teaching a language according to claim 9, characterized in that it comprises headphones (6, 7) and vibrators (8, 9).  11. Device for teaching a language according to Any one of claims 9 and 10, characterized in that it comprises delay means (18) introducing a delay between the moment when the envelope of the sound emission passes a reference level and the change in vibrations.  12. Device for teaching a language according to claim 11, characterized in that it comprises precession means (19) introducing a delay between the change of the vibrations emitted by the bone vibrators and the change of the vibrations emitted by aerial vibrators.  13. Device for teaching a language according to any one of claims 9 to 12, characterized in that the first filter (14, 15) is associated with a memory (142) making it possible to vary its characteristics as a function of the language to be studied.