NO316560B1 - Microphone with rangefinder - Google Patents

Description

The present invention relates to a microphone which comprises a microphone housing, an acoustoelectric transducer in a front part of the housing for receiving sound from a sound emitter, as well as equipment for transmitting sound representative signals from the transducer, out of the microphone and to external sound signal processing equipment, and where the microphone is equipped with an element for measuring the distance to the sound emitter From German publication DE 36 38 480 C2 a microphone is known which contains an element for measuring the distance to a sound emitter This known microphone, however, appears to be a relatively large device with a separately arranged microphone transducer and distance measuring element, and preferably relates to measuring the distance to a person, for example on a stage, in relation to a fixed microphone

Microphones, especially singing microphones, often have the problem that the distance from the microphone to the sound emitter itself, for example an artist's mouth, influences the sound resulting from the microphone recording Microphones have different types of directivity characteristics and different types of distance response, and an optimization is often carried out with regard to special parameters when a microphone is manufactured Thus, for example, it will be intended that a special microphone should be used very close, while another microphone may be designed to pick up sound from a greater distance A microphone that is optimized for a certain type of use will be able to give poor result when the use deviates somewhat from the originally intended use, and the result may be exaggerated S-sounds, incorrect frequency response, etc.

There is therefore a need for a microphone of a more flexible type, i.e. a microphone that can easily adjust to optimize parameters for different distances to a sound emitter. The present invention aims to solve this problem, and according to the invention, a microphone as indicated at the outset, and which is characterized by the fact that the element for measuring distance is included in the acoustoelectric transducer

In an important embodiment of the invention, the transducer consists of elastic, piezoelectric foils suspended in a surrounding frame and with a massive central body, the central body containing the distance measuring element

The distance measuring element can be an ultrasound echo meter The ultrasound echo meter can comprise two piezoelectric elements, one for sending a narrow ultrasound beam forward towards the sound emitter, and one for receiving ultrasound echoes from the sound emitter

Alternatively, the element for measuring distance can be a laser distance meter

The internal space of the microphone housing may contain circuits for the generation, or interpretation, of signals to, or from, the element for measuring distance. Parts of these circuits may be arranged for the generation of ultrasonic oscillations for the excitation of a piezoelectric ultrasonic transmitter element, and other parts of the circuits may be arranged for receiving and interpreting received signals from a piezoelectric ultrasound receiver element

Alternatively, parts of the circuits can be arranged for generating control signals for sending light from a laser element in the rangefinder, and other parts of the circuits can be arranged for receiving and interpreting received reflex signals from a light detector in the rangefinder 1, an embodiment of the microphone according to the invention the microphone includes a circuit arrangement for the utilization of measured distance, which circuit arrangement has at least one function in a group of functions which includes shutting off the transmission of sound representative signals from the microphone,

adjusting a gain factor as a function of the measured distance, and

adjustment of an equalizer setting as a function of the measured distance

In a further embodiment of the microphone according to the invention, the distance measuring element and circuits associated therewith are also arranged for sound detection by demodulation of a reflex signal from the sound emitter, which reflex signal, which is high-frequency, is superimposed with sound modulation from the sound emitter and from ambient noise

In what follows, the invention will be explained in more detail with reference to examples of execution, and reference is made in this context to the attached drawings, where

Fig 1 shows a microphone according to the invention, in an embodiment with a cord, Fig 2 shows a microphone according to the invention with a wireless transmission system, Fig 3 shows the same microphone as in Fig 1, but without a surrounding microphone housing, Fig 4 shows the upper parts that appear in Fig 3 in more detail, and

Fig 5 shows the microphone's sound transducer

It should first be pointed out that the embodiments mentioned in the following are only intended as examples of how the microphone according to the invention can be realized, as the limitations only appear from the attached independent patent claim. Thus, the microphone according to the invention is not specified with regard to how the captured sound is processed in the microphone itself or of equipment for processing signals transmitted from the microphone, nor with regard to how electrical, sound-representing signals are transmitted from the microphone, for example via a connected wire or via a wireless transmission system Thus in fig 1 and fig 2 are shown two versions of the microphone 1 according to the invention, with transmission through signal line 2 (fig. 1) or via radio transmitter 3 and antenna 4 (fig. 2) Otherwise, only external details appear from figs. 1 and 2, while the details that are decisive for the present invention appear of the following figures 3, 4 and 5

In Fig. 3, a similar microphone is seen as in Fig. 1, but without outer microphone housing 5 (Fig. 1, Fig. 2) The same microphone top 6 as in Fig. 1 and Fig. 2 also appears in Fig. 3 and Fig. 4, but in these figures it appears also an acoustoelectric transducer 7, which is shown in more detail in Fig. 5 The primary function of the transducer 7 is, of course, to pick up sound vibrations transmitted through the air from a sound emitter, for example an artist's mouth, and through the grating-shaped microphone tip 6 The shown transducer 7 has an outer frame 8, and rigidly suspended in this via beams 9, an inner frame 10 Inside the frame 10 there are a number of sector-shaped piezoelectric membrane foils and small radial slits 12 between the sectors. Centrally, the foil pieces 11 are fixed in a central body 13 When sound waves hit the sector-shaped foil membranes, they are set into oscillations, and the movements cause voltages to be generated in the piezoelectric foils. These voltages are carried out on wires 14, as each individual foil piece 11 is fo rsynth with separate signal lines Such a transducer, which in a preferred embodiment is intended to be used in the microphone according to the invention, is described in the applicant's previous US patent application with serial number 09/788,607, filed on 21 February 2001. In the said US application, the following variants appear which are required priority for in this invention

In the center body 13 itself, piezo elements 15,16 are inserted, i.e. a piezo element 15 for sending out vibrations, and a piezo element 16 for receiving reflected vibrations Signa I conductors to/from the center body's piezo elements are not shown in Fig. 5, but they follow paths on the sectors 11 from the central body 16 and out to the signal lines 17 shown. The piezo elements 15 and 16 are here embedded "crescents" of piezo material. this area), to carry out an echo distance measurement, possibly an echo Doppler survey for more accurate investigation of the sound emitter's mode of movement

Reflected vibrations are picked up by the element 16. Such an ultrasound beam emitted from the central body can be very narrow and directed, and will for example pass centrally out through the microphone top 6, i.e. through a special central hole. The two "crescent-shaped" piezo elements 15 and 16 can otherwise, parabolic or nearly parabolic curvature is provided to achieve the emission of a narrow beam and for corresponding directional reception

The different sectors of the sound receiving element with piezo foils 11 can also be used both for sending and receiving, but this is of somewhat less interest in a microphone embodiment. Mainly, the separate sectors provide opportunities for combining signals electronically to be able to cancel noise

Another feature of the transducer element is the tensioning system on the underside of the central frame 10. A system of struts 18 provides support for a tensioning screw 19 which, when operated, can pull the central body 13 somewhat downwards, so that the foot sectors 11 within the central frame 10 are given a downward sloping position towards the central body 13, so that the entire active part of the transducer takes on a somewhat more "parabolic" shape, and thus becomes more directional If the center screw 19 forms a rigid connection all the way up to the center body 13 on the underside, only with the possibility of recording rotation, the center body 13 is locked against vibration in a vertical direction, and the foil sectors 11 will then only be able to vibrate between such a fixed central body 13 and a fixed manner frame 10, but if a transition between the tightening screw 19 and the central body 13 is provided with an elastic joint, the entire system of foil sectors and the central body will still have a mode of vibration in the vertical direction, but modified by the influence of the elastic coupling kning

Signals to/from the active elements 11,15,16 in the transducer are carried as mentioned along signal lines 14, 17 (fig 5) and on to/from the base unit 20 shown in fig 3 This base unit 20 can contain signal processing equipment, for example A/ D-converter, controllable/programmable equalizer, amplifier and other On the other hand, it is also possible to route the signals to/from the active elements directly out on wire 2 if the microphone is of a type with a wire connection But with regard to the distance measurement system which the microphone is equipped with, it is of particular interest to have internal circuits, contained in the bottom part 20, for generating an ultrasound signal to the piezo element 15, and circuits for receiving and interpreting received reflex signals from the piezo element 16. The bottom part 20 will preferably contain a power source in the form of a battery, which is also necessary for the operation of any other circuits as mentioned above, and in the case of wireless transmission to external equipment (fig 2), is also for the operation of r audio transmitter/receiver in unit 3 (fig 2) The circuits for interpreting distance measurement signals will also be designed to utilize the measurement result, for example by blocking the transmission of sound representing signals from the microphone if the distance to the sound emitter exceeds a certain preset limit Similarly, the distance meter will -the result could be used to adjust an amplification factor for the amplifier that is built in, possibly for an amplifier in the external equipment, and then so that a short distance would lead to attenuation, while a longer measured distance would lead to increased amplification. a frequency curve, i.e. an equalizer setting, as a function of the measured distance, for example based on known relationships between the distance to the sound emitter and the occurrence of special, unwanted frequency response or frequency dip in the sound result

When it comes to removing noise, the center body with the distance measuring system also has a double function. Namely, the high-frequency ultrasound signal that is emitted from the element 15 and is reflected from the sound emitter, after the reflection will also have a slower vibration superimposed, namely the sound in question from the sound emitter, possibly also noise from the surroundings These slow sound vibrations (i.e. slow in relation to the high frequency used in the distance measurement itself) can be separated from the high-frequency oscillations by signal processing, and used as a basis for signal processing for the sound oscillations which are otherwise recorded through the fohe sectors 11, especially with regard to the removal of noise and unwanted sounds from the audio signals. The circuits in the bottom element 20 can therefore also be designed for such a function

Another type of distance meter that is known in and of itself is a device that uses a laser beam, and it is possible to build a small laser diode, possibly with micro-optics, into the same place as the device shown in fig 5, namely in the center body itself 13 A laser beam, preferably with infrared light, is then sent out through a corresponding opening in the microphone top 6, to be reflected from the sound emitter and back to a light detector placed together with the laser

In conclusion, it should be mentioned that the present invention is one of several inventions relating to a complete microphone, all of which are being patented at the same time, and reference is made to Norwegian patent application no. 2001 5983 regarding "singing microphone with signal processing equipment", Norwegian patent application no. airing", and Norwegian patent application no 2001 5984 regarding "microphone with replaceable parts"

Claims (10)

1 Microphone, comprising a microphone housing, an acoustoelectric transducer in a front part of the housing for receiving sound from a sound emitter, as well as equipment for transmitting sound representative signals from the transducer, out of the microphone and to external audio signal processing equipment, and where the microphone is equipped with an element for measuring the distance to the sound emitter, characterized in that the element for measuring distance is included in the acoustoelectric transducer 2 Microphone according to claim 1, characterized in that the transducer consists of elastic, piezoelectric foils suspended in a surrounding frame and with a massive central body, where the central body contains the distance measuring element 3 Microphone according to claim 1, or 2, characterized in that the distance measuring element is an ultrasound echometer 4 Microphone according to claim 3, characterized in that the ultrasound echo meter comprises two piezoelectric elements, one for sending a narrow ultrasound beam forward towards the sound emitter, and one for receiving ultrasound echoes from the sound emitter 5 Microphone according to claim 1, characterized in that the element for measuring distance is a laser distance meter 6 Microphone according to claim 1, characterized in that the interior of the house contains circuits for generating or interpreting signals to or from the element for measuring distance 7 Microphone according to claim 6, characterized in that parts of the circuits are arranged for the generation of ultrasonic oscillations for the excitation of a piezoelectric ultrasound transmitter element, and other parts of the circuits are arranged for receiving and interpreting received signals from a piezoelectric ultrasound receiver element 8 Microphone according to claim 6, characterized in that parts of the circuits are arranged for generating control signals for sending out light from a laser element in the rangefinder, and other parts of the circuits are arranged for receiving and interpreting received reflex signals from a light detector in the rangefinder 9 Microphone according to claim 1, characterized in that it includes a circuit device for utilizing measured distance, which circuit device has at least one function in a group of functions that includes shutting off the transmission of sound representative signals from the microphone, adjusting a gain factor as a function of the measured distance, and adjusting an equalizer setting as a function of the measured distance 10 Microphone according to claim 1, characterized in that the element for measuring distance and circuits associated therewith are also arranged for sound detection by demodulating a reflex signal from the sound emitter, which reflex signal, which is high-frequency, is superimposed with sound modulation from the sound emitter and from ambient noise