DE3406180A1 - Device for the measurement of the position of at least one measurement point by means of ultrasound - Google Patents

Abstract

Published without abstract.

Description

description

The invention relates to a device for measuring the position at least of a measuring point and, if applicable, its movement and the measured variables derived from it, especially for medical diagnostics and rehabilitation, physical education and for measuring surfaces, with an ultrasonic transmitter attached to each measuring point or -receiver and with at least three spatially fixed arranged ultrasonic receivers or transmitters, wherein the ultrasonic transmitters emit ultrasonic signals that according to a certain transit time are received by the ultrasonic receivers, also with a computer system, which is based on the coordinates of the fixed ultrasound receiver entered in it or sender and the current location of the relevant from the respective transit times Determines the measuring point in the room, stores it and takes the measurement at short intervals often repeated and from this a change in location that may have taken place in the meantime of the measuring point in time, and with a display and possibly with a Memory for the measured values.

The invention also relates to an ultrasonic transmitter for use in such a device.

Such a device is described in the article by Schumpe among others with the title "Gait examinations and functional spinal column measurements using a newly developed real-time ultrasound topometer "in the journal "Functional diagnostics in orthopedics", Enke, Stuttgart, 1979, p. 69 ff. Details on the circuit arrangement used there, with which one can get from the running times of the Ultrasonic signals that measure distances as well as about the ultrasonic transmitters used there are not given in this article. Also there is suggested to stimulate the ultrasonic transmitter to generate shock waves. Shock waves are characterized by a high energy, but they always contain several wave trains. This suffers but the measuring accuracy, because possibly also the vibrations after the first, increasing impulse can be measured by the ultrasonic receivers. this leads to either to incorrect measurements or it must be due to a suitable programming of the EDP system it is ensured that these wave trains, which have a lower amplitude, are not taken into account when evaluating the measurement.

This can possibly lead to increased computer times and thus again to a certain delay in the display of the measured values, which interferes with some applications.

The invention is therefore based on the object of a circuit arrangement to propose with which the device of the type mentioned is satisfactory works in such a way that the measured values are available with great accuracy and speed stand and can be displayed. In addition, a new type of ultrasonic transmitter is to be used be proposed for use in such a device, the short measurement times and enables practically error-free measurements.

The device according to the invention is thereby able to achieve this object characterized in that circuitry is provided which has a timer has, which via a transmitter amplifier the ultrasonic transmitter with a shock pulse applied and at the same time emits a start pulse to a counter that is acted upon by an HF oscillator with counting pulses that the Output of the counter connected to a receiver-side memory for the counting pulses whose input is also to the ultrasonic receiver via a receiving amplifier is connected and to whose output the display is connected.

As soon as the timer emits a pulse, the relevant ultrasonic transmitter becomes excited to a shock pulse, which is by a high amplitude and thus by a high energy content as well as only short-term excitement with it immediately subsequent drop to zero. The shock pulse has preferably only a single leading leading edge and then immediately goes to zero intensity back, or at least essentially to zero. This means that incorrect measurements are largely eliminated locked out. Simultaneously with the transmission of the start pulse via the timer if the counter is set to zero, the oscillations that are now continuously fed to it are set to zero of the RF oscillator counts. This number is transferred to the receiver's memory, as soon as this receives the receive pulse.

The number in memory is therefore a direct measure of that Time interval between the emission of the shock pulse and its reception in the receiver. Due to the known speed of propagation of the sound in the relevant Medium, generally in air, can be used to directly display the distance between Sender and receiver are displayed.

It is also possible to make the circuit arrangement so that the Constantly counter the impulses sent to it by the HF oscillator to the receiver Memory forwards, which then the number in question displays as soon as he receives the corresponding receive pulse.

In the manner described, all impulses are between one Transmitter and at least three receivers processed, with the help of mentioned computer system including its program.

With the device described, it is easily possible to the Location of the measuring point within a sphere with a diameter smaller than 1 mm to determine.

These measurements are repeated in quick succession, the repetition frequency being is determined by the frequency of the timer. This is therefore preferably adjustable, for example between values of 1 and 100 Hz. Depending on the one used Measuring arrangement, in particular the number of transmitters and receivers used in each case The software program used to evaluate the signals also plays a role and of course the smoothness of the computer used, one becomes the frequency of the timer to a suitable value, which of course depends on the respective Good temporal resolution adapted to the circumstances should result. Tests have shown that at frequencies around 40 Hz with a not too large number of transmitters and receivers good measurement results can be achieved.

The oscillation frequency of the RF oscillator is set to advantage so that the number appearing in the display, as explained, is proportional is the duration of the shock pulse and therefore also proportional to the distance between Transmitter and receiver, a direct display for the respective measured distance in the system of measurement in question, generally in the metric system. after the Speed of sound in air at a temperature of 200 C is known 343.8 m / sec.

is, it therefore adds to the circuit complexity and the display Advantages of setting the frequency of the RF oscillator to a numerical value, which corresponds to this numerical value, multiplied by 10n, where n is a number = i, 2, 3 ... is. Preferably n = 4, in which case those appearing on the display Numbers reflect the distance measured in each case directly in a tenth of a millimeter. The same considerations naturally also apply to displays in other systems of measurement, for example in the customs system.

Since the speed of sound in air is temperature-dependent, The frequency of the RF oscillator can also be adjustable in order to achieve a still improved measurement accuracy also temperature fluctuations or deviations from the mentioned room temperature of 200 ° C must be taken into account.

It has already been mentioned that there are significant advantages when the ultrasonic transmitter emits shock pulses. There are several to achieve this constructive possibilities. A piezo-ceramic ultrasonic transmitter has particular advantages Material, although other principles can be used as below will be explained in more detail.

Such an ultrasonic transmitter is preferably characterized by that he has two plates of the same size, placed one on top of the other and glued together made of piezoceramic material, which are polarized so that they are when applied a voltage of predetermined polarity on their metallized outer surfaces spherical shell-shaped deflected in one direction and, if the voltage is reversed, in the other direction and the vibration damped on their underside in the area of their edges are attached to a housing. This ultrasonic transmitter emits an almost ideal Spherical wave of the zeroth or first order, connected with a high, jerky one increasing amplitude, i.e. in other words the desired shock pulse. Even this is explained in more detail below.

It is preferred if the diameter of the platelets is small Comparison to the wavelength of the sound to be emitted in the piezoceramic Material.

Under these conditions, a zero order spherical emitter is achieved.

Tests have shown that particularly good results can be achieved if the platelets are square and only attached to the housing at their corners are.

In many applications it is advantageous if the ultrasonic transmitter radiate the shock pulses in as large a solid angle as possible in order to ensure that that every shock pulse is received and evaluated by at least three receivers, namely independently of the respective movements and also pivoting of the measuring point including the ultrasonic transmitter attached to it. On the other hand, the radiation has in a large solid angle the disadvantage of a feasibly reduced reception power. A compromise will therefore be sought in between.

In order to achieve that the shock pulse in as large an angle as possible If it is radiated in the room, it is preferred if a pinhole is close in front of the sound-radiating surface of the platelets is arranged. On the edge of the aperture the shock pulse is bent and thus achieves the desired room radiation. Of the The diameter of the hole in the pinhole diaphragm should be in the order of magnitude of the wavelength, in order to prevent excessive energy losses through the diaphragm. Good results have been with pinhole diaphragms with a diameter of about 4 mm at a sound wavelength of 7 mm achieved.

The pinhole is preferably very close, for example in one Distance of about 0.1 mm, placed in front of the vibrating surface of the platelets. Through this the acoustic short circuit that the back of the membrane (= oscillating plate arrangement) with its front side has, for the most part, blocked and the energy radiation further improved. It serves the same purpose when on the sound radiating A bell is placed on the surface of the plate.

It should be mentioned that ultrasonic transmitters with the same format and with each other glued and appropriately polarized piezoceramic plates with a such horns are known per se. The well-known ultrasonic transmitters are but not electrically biased, and they are suspended in their vibration node, so that they vibrate in resonance. Let with these well-known ultrasonic transmitters therefore no shock pulses are emitted.

The invention is illustrated below using an exemplary embodiment explained in more detail, from which other important features result. It shows: figure 1 schematically shows the principle of a one-dimensional measuring section on the basis of a block diagram to explain the essential features of the circuit arrangement according to the invention; FIG. 2 shows, in perspective and also schematically, the essential components of a ultrasonic transmitter according to the invention; FIG. 3 shows a likewise schematic cross section by the ultrasound transmitter according to Fig. 2 in the resting state, i.e. without touching its platelets applied voltage; FIG. 4 shows the situation of FIG. 3 in the pretensioned state of Membrane; FIG. 5 shows the situation according to FIGS. 3 and 4 at the moment of the emission of a Shock pulse, i.e. when the polarity of the voltage on the membrane is reversed.

With regard to the basic structure of the device described refer to the above-mentioned article by Schumpe et al. referenced. Figure 1 shows the block diagram of such a measuring section between a single transmitter 1 and a single receiver 2, i.e. in the case of a one-dimensional measuring section. It will preferred, especially with regard to a simplification of the software if the sender is attached to the measuring point and is therefore movable and the receiver - at least three receivers are provided - are fixed in space. But it is basically The reverse arrangement is also possible, i.e. with transmitters fixed in space and at the measuring points attached receivers, although this involves a greater effort in terms of software brings with it. The principle of the one-dimensional measuring section described below remains the same for all these test sections between each transmitter and each receiver. The EDP system can use its software to send the received impulses to every recipient and everybody Assign transmitter, which is not the subject of this invention.

A timer 3 is on a certain frequency, preferably between 1 and 100 Hz, set, preferably to a frequency of about 25 Hz. In this case Timer 3, which is a free-running oscillator, gives all settings 40 milliseconds from a start pulse to a transmitter amplifier 4, whereupon the ultrasonic transmitter 1 then emits an ultrasonic shock pulse.

At the same time a counter 5 is set to zero. For this purpose, for example a five-digit counter is used. The counter 5 now starts the counting pulses of an RF oscillator 6 which is a crystal oscillator and which has a high frequency oscillates from 3.438 MHz.

As soon as a receiver amplifier 9 via the ultrasonic receiver 2 the Receives shock pulse, this sends a takeover signal to a buffer 7 (latch), which then shows the current count of the counter 5 takes over and saves until the corresponding pulse in the next individual measurement. The content of the memory 7, i.e. the count, is forwarded to a display 10 directed and made visible and / or saved there. The ad is for example a screen display, a writer, a printer or also a direct digital display of the relevant measured value. Can also be measured from the Coordinates of the transmitter i whose movements are derived because the measurements, as mentioned, can be carried out in quick succession. From this measurement data can also all other data of interest are derived, for example the Acceleration and, if there are at least three measuring points, the angle between the three measuring points, the angular velocity, the angular acceleration, Symmetry deviations and other interesting data.

The counting pulses are sent from the counter 5 to the memory 7 via a line 8 forwarded.

The ultrasonic transmitter shown in Figures 2 to 4 consists of his essential components from a housing 11 in which a vibrating membrane is housed is. This consists of two of the same format, one on top of the other and opposite one another polarized piezoceramic plates 12, 13 which are glued together. An electrical potential can be applied to the metallized via a connecting conductor 14 Surface of the upper plate 13 are applied and via a further connecting conductor 15 an electrical potential on the metallized underside of the lower plate 12 can be created.

In the embodiment shown, the two plates 12, 13 square with edge lengths of about 8 mm. The consisting of the plates 12, 13 vibrating At its four corners, the membrane is attached to the housing 11 by means of a body 16 made of silicone rubber attached. In the middle of the top of the membrane is still a sound radiating Funnel 17, preferably made of plastic material, placed there and with the membrane glued.

The housing ii encloses the membrane with its components on all sides. Only at the top, that is the sound-emitting side, is a hole 18 a cover is attached in the housing.

Figures 3 to 5 explain the mode of operation of this ultrasonic transmitter. FIG. 3 shows the idle state, in which there is no voltage across the connecting conductors 14, 15 rests against the membrane. In Figure 4 the membrane is down, i.e. towards the bottom of the housing 11 towards, biased. This is done by creating an appropriate Tension achieved on the membrane.

If a shock pulse is to be delivered now, the polarity of the voltage is reversed and about the piezoceramic effect described above, which is known per se is, the membrane takes the shape shown in Figure 5 and the shock pulse becomes released via the perforated diaphragm with the hole 18, as indicated at item 19. From it it can also be seen that a good spatial characteristic is achieved.

The suspension of the membrane at the edges or corners has the advantage an increased amplitude with it, because, as a comparison of FIGS. 4 and 5 in particular clearly shows, then the middle area of the membrane from the pretensioned position according to Figure 4 over the high Position according to Figure 3 in the radiation position goes according to Figure 5, and within a very short time. The suspension of the membrane About the small body made of silicone rubber or some other sound-absorbing Material dampens the oscillation very well, so that it actually has an impulse character receives. The horn 17 amplifies the sound radiation, and the pinhole with the hole 18 is dimensioned so that it is on the one hand over the inflection at the edge of the Hole 18 increases the angle of radiation of the shock pulse in space and on the other hand but sufficient sound energy can still pass through the hole 18.

In principle, other ultrasonic transmitters can also be used with the inventive Device are used, although this compared to the current state of knowledge the described ultrasonic transmitter are disadvantageous.

A good omnidirectional characteristic is, for example, one from a small one A volume of air consisting of a vibrating sphere that expands through sudden heating. Such a vibrating ball has the advantage that an optimal matching of the impedances exists between the sound emitter and sound conductor because both are air. Basically such a sound emitter is constructed like an ion tweeter of a modern one Loudspeaker with a metal tip with an extremely small radius of curvature emits amplitude-modulated high frequency caused by the strong field strength gradient Air molecules ionized and caused to vibrate by the amplitude modulation. The efficiency of such a converter system is very good up to about 100 KHz, see above that it is basically suitable for the purpose according to the invention. The great and heavy housing and the relatively rigid high-frequency lead, however, leave the use such a sound emitter for the measurement of fine movement structures, which also should be influenced as little as possible by the measuring device, appear to be disadvantageous.

Such an air-ball sound emitter that only emits a pressure wave can basically also be achieved by a briefly ignited arc produce.

However, such arc transmitters do not work very reliably and must also operated with a voltage on the order of several kilovolts which in turn brings with it security problems, in particular when using the device according to the invention on patients, athletes and other people. Also, such a transmitter would be relatively unwieldy and heavy while the described ultrasonic transmitter according to FIGS. 2 to 5 is characterized by very small dimensions and is characterized by a low weight and a relatively low weight to be fed to it Tensions that do not require any special safety precautions.

The ultrasonic transmitter described can not only work together with the The device according to the invention can be used, as described in the article mentioned has been described, but also, and advantageously, together with the circuit arrangement according to Figure 1.

Experiments have shown that the time resolution of the described Device with the use of six ultrasonic transmitters approximately equal to one-thirtieth Second is. This value is even improved if fewer transmitters are used.

Compared to other, previously known measuring systems, the preferred Working optically over film recordings, the device according to the invention is distinguished due to an approximately thirty to one hundredfold improved spatial resolution. Ever according to the number of transmitters and receivers used and also the computer speed results in a measurement and analysis time of a few minutes down to about one Hundredths of a second.

Such a short period of time between the event (movement) and its Representation opens up new areas of application, for example in medicine Rehabilitation and for physical education, in which case the person concerned himself, if necessary, together with a doctor or sports teacher, the movements concerned can see and control practically at the moment. - blank page -

Claims (12)

Claims device for measuring the position of at least one measuring point and, if applicable, its movement and measured variables derived therefrom, in particular for medical diagnostics and rehabilitation, physical education and for the measurement of surfaces, with an ultrasonic transmitter attached to each measuring point or receivers and receivers with at least three space-fixedly arranged ultrasound or transmitters, the ultrasonic transmitters emitting ultrasonic signals that are after a certain transit time are received by the ultrasonic receivers, also with a computer system, which is based on the coordinates of the fixed ultrasound receiver entered in it or sender and the current location of the relevant from the respective transit times Determines the measuring point in the room, stores it and takes the measurement at short intervals often repeated, resulting in a change of location that may have taken place in the meantime of the measuring point in time, and with a display and possibly with a Memory for the measured values, characterized in that a circuit arrangement is provided which has a timer (3) via a transmitter amplifier (4) the ultrasonic transmitter (1) is subjected to a shock pulse and that at the same time emits a start pulse to a counter (5), which is fed by an HF oscillator (6) Counting pulses are applied to the output of the counter (5) with a receiver-side Memory (7) for the counting pulses is connected, the input of which is via a receiver amplifier (9) is also connected to the ultrasonic receiver (2) and to its output the display (10) is connected. 2. Apparatus according to claim 1, characterized in that the frequency of the timer (3) is adjustable. 3. Apparatus according to claim 2, characterized in that the frequency of the timer (3) can be set between 1 Hz and 100 Hz. 4. Device according to one of claims 1 to 3, characterized in that that the numerical value of the frequency of the HF oscillator measured in oscillations per second (6) divided by the numerical value of the speed of sound measured in meters per second in air at the measuring temperature of the air has the value 10n with n = a whole positive Number. 5. Apparatus according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the frequency of the RF oscillator (6) is approximately = 3.438 MHz. 6. Apparatus according to claim 4 or claim 5, d a d u r c h g e It is not indicated that the frequency of the HF oscillator (6) can be adjusted. 7. Ultrasonic transmitter for use in a device according to Preamble of claim 1, d a d u r c h e k e n n n z e i c h n e t that he emits a shock pulse when he is excited. 8. Ultrasonic transmitter according to claim 7, characterized in that the ultrasonic transmitter is two identical format, one on top of the other and one with the other has glued platelets (12, 13) made of piezoceramic material, which polarizes in this way are that they are metallized when a voltage of predetermined polarity is applied to their Outer surfaces spherical shell-shaped in one direction and, if the voltage is reversed, in the other direction are deflected and those on their underside in the area of their Edges are attached to a housing (11) in a vibration-damped manner (body 16). 9. Ultrasonic transmitter according to claim 8, characterized in that the diameter of the platelets (12, 13) is small compared to the wavelength of the sound to be emitted in the piezoceramic material. 10. Ultrasonic transmitter according to claim 8 or claim 9, characterized in that that the plates (12, 13) are square and only at their corners on the housing (11) are attached. 11. Ultrasonic transmitter according to one of claims 8 to 10, d a d u r c h g e k e n nn n z e i c h n e t that a perforated screen (18) close in front of the sound radiating Surface of the plate (12, 13) is arranged. 12. Ultrasonic transmitter according to one of claims 8 to ii, d a d u r c h e k e k e n n n n e i n e t that on the sound-radiating surface of the platelets (12, 13) a horn (17) is attached.