DE690350C - Oscillograph - Google Patents

Description

Oscillograph In the known arrangements for recording quickly One strives for variable pleriodic and aperiodic processes (oscilograph) afterwards to give the oscillatory system the highest possible natural oscillation, so that it can follow fast movements as faithfully as possible. This causes a Decrease in sensitivity. Otherwise it is only possible through special aids possible to obtain a distortion-free recording. There are special measures required to have fidelity amplitude and phase fidelity for the different in delm too investigating process to achieve contained frequencies.

Awch for turning off unwanted wafer waves, for the Adaptation in the broader sense to the measuring circuit to be examined are special measures necessary. The investigation of the proportion of the harmonic and, if necessary, the phase days this harmonic to the fundamental is only possible in a cumbersome way.

According to the invention, the oscilloscope production takes place in such a way that that the process to be recorded is broken down into fundamental and harmonics, each frequency separately is picked up by an organ that is tuned to resonance and so individually The values found can be combined to form a resulting curve. object of the invention is therefore an oscilloscope having a number of resonance systems of which one on the fundamental and the other on one of the harmonics of the one to be examined Vibration are matched and which are coupled to one another in such a way that a summation the individual displays of these systems is achieved so that the display organ shows the resultant, d. H. shows the actual course of the process to be examined.

The use of Rtesonanz-! Systems is the greatest possible Sensitivity guaranteed. In addition, such arrangements are simple and cheap, as none of the difficulties mentioned need to be taken into account, as long as the resonance condition is met. Should this arrangement still be for vibrations be useful whose basic frequency differs slightly from the nominal value, the The damping does not fall below a certain value.

The phase of the recorded oscillation is then resonance for all systems shifted by 9c ° against that of the exciting force.

So z. B. the resonance systems as in an ordinary oscilloscope loop provided with mirrors whose axes of rotation are all parallel to each other, so wind The arrangement is made so that a single beam of light shines one after the other on the individual Mirror falls, experiences an overall deflection that is equal to the resultant the deflections the single mirror is. This -not then the instantaneous value of the quantity to be measured.

For electrical display systems that work in the field of magnets, the individual systems can be arranged in a common field. From it In addition to saving space, there is the advantage that by changing the excitation an electromagnetic field, the natural oscillation of all individual systems at the same time can be modified so that the device can be used to study vibrations with others Base frequency becomes usable. If any partial wave is not to be measured, so only the system corresponding to this wave needs to be switched off.

In a known way, by means of a rotating mirror or the like, the synchronous is driven with the fundamental wave, a still image of the oscillation is recorded , which then gives a picture of the actual waveform. Also non-periodic Processes can in principle be recorded in the same way, since the individual resonance systems also analyze these harmoniously.

Claims (5)

P A T E N T A N S P R Ü C H E: I. Oscillograph, characterized by a number of resonance systems, one of which is the fundamental and the other depending are matched to one of the harmonics of the oscillation to be examined, and the are coupled to one another in such a way that a summation of the individual displays of these Systems is achieved so that the display organ the resultant, i. H. the actual The course of the process to be investigated. 2. Oscillograph according to Claim I, characterized in that the Resonance systems are equipped with mirrors whose axes of rotation are all parallel to each other are, so that or total deflection of the light beam in each case the instantaneous value of size to be measured. 3. Oscillograph according to claim I and 2, characterized by a indicator moving synchronously with the base frequency, e.g. B. a rotating mirror to generate a stationary image of the process to be examined. 4. Oscillograph according to claim 1 to 3, characterized in that all resonance systems are arranged in a common magnetic field. 5. Oscillograph according to claim I to 4, characterized in that To record processes with a different fundamental frequency, the tuning of the resonance systems is adjusted at the same time, e.g. B. the oscilloscope according to claim 4, by changing the common magnetic excitation.