IL147735A - Method and apparatus for signal processing for electroacoustic transducer - Google Patents

Description

147735/2 METHOD AND APPARATUS FOR SIGNAL PROCESSING FOR ELECTROACOUSTIC TRANSDUCER ittiitt naj) ΛΙΛΙΝ *ni wm> Pearl Cohen Zedek Latzer Advocates, Patent Attorneys & Notaries P-4793-IL ELECTRIC SIGNAL PROCESSING FOR ELECTRO-ACOUSTIC TRANSDUCER It is common to use electric current filters for electro-acoustic transducers. These filters are usually frequency attenuators the equalizing slope of which -is 6 dB, 12 dB, 18 dB. Mixers use these more or less -sophisticated filters order to modify the audio bandwave frequencies. On the other hand, it is common to have curves of the electric signal as perfect as possible, i.e. to obtain square wave responses as perfect as possible.

It is found in the current technology used that the audio electric signals have excellent pulse response and frequency control quality. With regard to electro-acoustic transducers, the transformation of the electric signal is incorrectly executed by the transducer(s).

In fact, the electric pulses are sent at the speed of the electrons whereas the diaphragm and its motor make up an electro-mechanical assembly of a given weight. The weight of this mobile assembly has mechanical inertia preventing an instant response to the electric stresses of the audio signal, thereby creating distortions, even absences of sound as the diaphragm cannot respond simultaneously to all the electrical values.

This process enables the original electric pulse to be modified into at least modulation, pulses, micro electric phase shifts shifting the instant electric pulse into delayed electric micro-pulses. Thus, the starting driving force of the movement on the diaphragm is distributed into a very short time interval so as not to saturate the coil with current, with the motor of the mechanical assembly in movement which can thus absorb, once the acceleration factor is acquired, the rest of the pulse of the original current. These micro-currents are generated by the impedances which crossed by the original electric signal, generate electric oscillations by their counter-electro-driving forces.

The components are parallel mounted over at least two levels.

The components, mounted on three parallel levels respond better to electric phase shifting for the electric absorption of the transducers.

The process is therefore the positioning of a self-supplied oscillator, activated by the original audio signal crossing the components making it up to obtain an oscillated signal of a very low amplitude, of oscillations of very big frequencies. (Fig. 1). This new signal (2) keeps the general aspect of the original signal (1) which is continuously modulated. This parallel mounting process of components of the same type but of different values thus enables a modification of the audio, digital, electro-acoustic transducer supply signal, of at least one acoustic transducer or one acoustiG speaker. In fact, this process is placed between an amplifier and ah acoustic speaker or a transducer, on the supply line.

This process creates micro interference on the original electric signal which does not change the general curve of the signal at all but which gives an apparently parasitic aspect of the original signal. The components of this process can be electric passive or active components, micro processors, integrated circuits or future technology.

This process is represented by the (Fig. 1) of which the curve 1 of the electric audio signal is modified into curve 2 according to this process which modifies the perfectly smooth signal into at least one rippled signal.

This process has also a unit made up (Fig. 2) of several electric components, in this case wound resistors, parallel mounted. The first channel (1) is made up of at least one component, the second parallel channel (2) is made up of at least one component, in this case, two serial-mounted components. The third channel (3) is also made by at least one electric component, in this case two serial-mounted components. The assembly thus made up is an interface module, energised by the original electric signal, mounted between the amplifier (4) and the acoustic speaker (5). The supply wire (6) of the + taking the interface module of this process. This non-limiting example is made by a person skilled in the art. This unit made up of components of the same type with different values, is mounted on any electric power supply of an acoustic speaker or of at least one electro-acoustic transducer.

This process (fig. 3) is an alternative of the process made up on channel (1) of at least one electric component, on channel (2) of at least one electric component, being in this case two different ' wound resistors (4,6), respectively 3.3 Ohms and 8.2 Ohms. The channel (3) is made up of a self-inductance coil (5) of 18 turns. All the components in parallel are mounted on the supply of at least one electro-acoustic transducer (8) of a television , linked to its audio generator (7). The set of values of the components is such that the original, analog or digital audio signal is not altered in its whole by an attenuation of frequency but is subject to micro-oscillations resembling a slight steady interference due to the electric phase shift caused by the components which intervene directly due to their type on the supply current of the electric signal.

This module is an interface unit between an analog or digital audio signal and an electro-acoustic transducer so that it can absorb the electric pulses to b e transformed into a mechanical movement more easily (Fig. 3).

It is to be pointed out that the module must never make up an attenuation frequency filter of 6 dB or more.

This process and unit are aimed at improving the comfort conditions of electro-acoustic reproduction and the quality of acoustic reproduction which can be used in the sound, audio and audiovisual reproduction field.

Claims (10)

1. Method in the sound reproduction field comprising the step of placing an oscillator on the analog or digital electric audio signal feed (6) to at least one electro-acoustic transducer (5, 28), said oscillator modifying the original electric signal (1 1) to at least one very low amplitude and high frequency oscillating electric signal (12) while not modifying the general aspect of the original signal, said oscillator being self-powered by the original signal which upon passing through the oscillator, modifies the original electric pulse into at least one electric micro-phase-shifted pulse.

2. The method of claim 1 , wherein the oscillator comprises at least one electric component (24, 25, 26) per channel on at least two channels (1 , 2, 3; 21 , 22, 23) in parallel.

3. Method according to claim 2, wherein said electric components (24, 25, 26) have different values.

4. Method according to claim 2, wherein said electric components (24, 25, 26) comprise passive components.

5. Method according to claim 2 or 3, wherein said electric components (24, 25, 26) comprise active components.

6. Method according to claim 2 or 3 wherein said electric components (24, 25, 26) comprise microprocessors.

7. Apparatus for the reproduction of sound in digital or analog, comprising an oscillator with at least one electric component (24, 25, 26) per channel on at least two channels (1 , 2, 3; 21 , 22, 23) in parallel, said oscillator being mounted on any electric feed to at least one electro-acoustic transducer (28), or acoustic speaker (5), said oscillator creating at least one electric micro-phase shift modulation of the original electric pulse (1 1).

8. Apparatus according to claim 7, wherein said electric components (24, 25, 26) have different values.

9. Apparatus according to claim 7 or 8 wherein said electric components (24, 25, 26) comprise active components.

10. Apparatus according to claim 7 or 8 wherein said electric components (24, 25, 26) comprise passive components. 1 1. Apparatus according to claim 7 or 8 wherein said electric components (24, 25, 26) comprise microprocessors. For the Applicant PearLCoheiy edek Latzer Advocates Notaries & Patent Attorneys / P 793-IL