DE1473259B2 - METHOD AND EQUIPMENT FOR MEASURING ELECTROMAGNETIC RADIATION IN PARTICULAR TEMPERATURE RADIATION - Google Patents

Description

1 4 15 ZbV
1 2

The invention relates to a method for measuring signal can be achieved with the help of an electrical reference electromagnetic radiation, in particular temperature signal, which is generated by the electromechanical moduratur radiation, in which a transducer element is generated via lator and thus the frequency and phase of the an electromechanical modulator alternately with this caused difference signal again the radiation to be measured and the radiation 5 reflects.

applied to a comparison source and from both the one device for carrying out the invention

Difference is formed. according to the method is in claims 4 to 6 ge

Such arrangements are already known (one marked.

compare for example Euler - Ludwig The drawing shows a block diagram of an output

"Working methods of optical pyrometry", 1960, ίο leadership example of an arrangement for implementation p. 102 and 103). The method according to the invention is shown in the case of such alternating light measuring arrangements. Obviously, this voltage depends on the achievable measurement embodiment, in addition to the accuracy of the accuracy of the constancy of the radiation of the method according to the invention, the implementation of the same source. Should now - as is the case, for example, with further simplified radiation measurement methods,
during the cooling of a glass melt for optical 15 An important part of the arrangement is a self-glasses according to a precisely maintained, predetermined, excited, position-independent rotary pendulum D, which temperature-time scheme is often required - at one end as a modulator of conventional design, temperatures of about 1000 ° C is still temperature; That is, with a perforated diaphragm B for chopping, differences of about 0.1 ° C can be measured which can be directly transmitted to a photoelectric converter. 1 ⁰ C a mirror through which the radiation to be measured poses an extremely difficult problem, which is directed with the transducer and chopped up in the process. The help of the thermostat only with considerable effort rotary pendulum D is associated with a pulse generator V, can be solved. Furthermore, the rotary pendulum D has a suitable organ

Radiation measuring arrangements of the above-mentioned 25, with which it is possible to use the pulse generator th type, should preferably be used in different applications according to the oscillations of the rotary pendulum and may for this purpose control so that this is a constant, not too large and not too large for the jet be bulky and, in addition, the coherent electrical reference signal S ₄ does not consume too much electrical power. The manufacture of such a rotary pendulum must be designed so that it does not offer any difficulties independently of a power supply, and there are also sufficient circuits for generating or driving voltage from the power network with a battery. These requirements can be tied to voltage-modulating self-excited systems, however, with extremely constant thermostatted systems, so that a detailed discussion of the sources of the same in the case of alternating light radiation measuring devices is superfluous.
practically not meet these requirements. 35 The rotary pendulum D acts as a mechanical oscillator

The object of the present invention is known to have a high circular quality, so that the known alternating light radiation measuring device can be designed with simple means to achieve very good constancy so that the frequency of both the modulated radiation and the frequency of the modulated radiation are accurate if the comparison source is not kept constant, the generated reference signal can also be achieved. On the basis of this frequency constancy, which can and accordingly operate according to this method, it is possible to build very systems that are much smaller and simpler, and to use narrow-band amplifiers through which there are. In order to achieve this object, according to the present invention, an excellent interference limitation can be achieved in a method which is mentioned at the beginning. The use of this rotary pendulum as a modulator provided that for compensation of the further has the advantage that it can be kept smaller in its fluctuations in the comparison radiation, the deviation of the comparison radiation from a desired previously common rotating diaphragm. In addition, the level is determined and that the deviation and its power consumption are small, so that this oscilloscope difference signal can be amplified to the same extent and easily fed from a battery in lator, corresponding phase position to a resulting, which in many cases is a not insignificant advantage are added ^ / which represents after aus- 50. -i; '-'; x: ^ ü, ';., ,, y _; ;

sufficient gain is brought to the display. -M; c ^; , .λ The measured value from the radiation source O

The constancy achieved up to now by keeping the reference value constant and chopped up by the rotary pendulum D ... source, which becomes the reference radiation. ._ lung S ₀ . falls on a _ .. converter.ivin ... which. In this case, therefore, it electrically achieves an electrical signal · S ₂ proportional to its energy by converting the difference signal from the to 55. At the transducer E is a narrow measuring radiation and the _; relative; Constant band selective amplifier V _{1 is} connected, in wel radiation from the reference source behind the transducer, the signal S _{2 is} amplified and _{a correspondingly amplified signal S 3} element is fed to a mixer M ₁ . A further narrowband selective ver signal is superimposed in the correct phase _{on the electrical stage Af 1} representing the mixes of the comparison source. This leads to 60 more strongly connected V ₂ , the output of which clearly leads to the same effect as with an exactly second mixer stage M ₂ . The mixer M ₂ is a constant reference source, but the effort is electrically connected to a phase-sensitive rectifier LJ with a suitable display element Z for measuring the fluctuations of the reference source and its in-phase supply to the alternating design.

light difference signal significantly smaller than the exact 65. With this arrangement, a number of measuring sensors are thermostatted for the reference source. The phases can be carried out, which are described in more detail below, correct supply of the deviation of the comparison. In the simplest case, the radiation from a desired level to the differential reference signal S ₄ generated by the signal generator V is the

Mixing stage Af ₂ supplied. In this case, it is expedient _{to feed the reference signal S 4} to an amplifier A before it is fed into the mixer stage Af ₂ , in which its amplitude can be set to a desired value. The reference signal S ₈ adjusted in its amplitude is in the mixer M ₂ with the generated in the converter E and via the amplifier F ₁ , the mixer M ₁ and the amplifier F _{2 of} the mixer M ₂ electrical signal S _{7 of} the radiation to be measured in the The correct phase position is mixed so that a difference signal S ₉ arises from the two, so that S ₉ -S ₇ = S ₈ .

Since the amplitude of the reference signal S _{8 is} adjustable and known, it can be used to compensate for any input level without reducing the measurement accuracy. Each signal change can thus be measured independently of the level of the given basic signal level with maximum sensitivity, or, transferred to the application example presented at the beginning, the smallest temperature differences can be measured independently of the. The temperature can be determined. ,

As has already been stated, a phase-sensitive rectifier is connected between the mixer Af _{2 and the display element.}

In a second measuring method, the reference signal S ₄ is now used to control this phase-sensitive rectifier LJ . A display with the correct sign and low-noise is thus obtained on the display element Z, which is extremely important for many measurement problems.

Are supplied AS - If a compensation arrangement used to measure the radiation, so the transducer must alternately the radiation to be measured S ₀ and the coming from a reference source radiation R _S1. The alternating supply takes place, for example, by means of a mirror attached to the rotary pendulum D. As has already been stated, keeping the reference radiation source R constant generally requires a high expenditure of power from all associated devices, which can only be covered by batteries, which is unfavorable. By means of the reference signal S ₄ , the generation of a constant reference beam level can now be significantly facilitated and simplified by electrical compensation of the fluctuations. As can be seen from the drawing, the signal appearing at converter E AC signal S ₂ is proportional to the difference of the radiation to be measured S ₀ and the radiation S ₁ -AS the reference source R. herein is intended to S _1, a constant desired signal level of the reference source R and - AS mean the current deviation from this desired level. Behind the converter E is therefore obtained

S ₂ ~ S ₀ - S ₁ -f- A p.

ity constant should correspond to the gain of the amplifier V ₁ , so that

S ₅ = KAS = V ₁ AS

(3) is.

In the mixer TIf ₁ , the difference is formed from the two signals S ₃ and S _{8. The signal S 6} appears at its output, which corresponds to the previous considerations

= S ₃ -S ₅ = V ₁ (S ₀ - S ₁ + AS) -V ₁ AS,

That means

is.

= V ₁ (S ₀ - S ₁ )

This signal S ₂ is amplified in amplifier V ₁ , for the sake of simplicity the symbol V _{1 should be used} at the same time for its degree of amplification. The amplified signal S ₂ V ₁ is fed as signal S _{3 to} the mixer Af _1:

With (1) we get S _{3 for this input signal}

S ₃ = F ₁ S ₂ = F ₁ (S ₀ - S ₁ + AS) . (2)

The deviation AS of the reference source from the desired level S ₁ is now measured and fed into the mixer Af ₁ as a proportional signal S _{5 via the second input.} The proportionali-The difference signal S ₆ is thus independent of the changes in the. Reference beam source. With this new method, it is no longer necessary to keep the reference radiation source exactly constant. Of course, with this method too, one variable must be kept constant, namely the signal level S ₁ , from which the fluctuations of the reference source are measured. However, since in very many cases the reference source will be a thermal radiator with a very high expenditure of power, there are considerable advantages in practice if the signal level S ₁ and not the reference source must be kept constant. It goes without saying that for any task no

; all parts must always be used. A simple arrangement can e.g. B. from the rotary pendulum, the pulse generator F, the converter E, the narrow-band amplifier F ₂ , the mixer Af ₂ , the amplifier A and the display element Z. For other purposes it will suffice that the phase sensitive rectifier LJ is added to this assembly. The entire arrangement can also be produced as a unit, in which the respectively required measuring method is carried out by appropriately coupling the reference signal S ₄ . Since all electrical parts are of conventional design and are commercially available, the result is a device that is simple and easy to manufacture, but by means of which the deficiencies and difficulties mentioned at the beginning are nevertheless eliminated.

Claims (6)

Patent claims: 1. Method for measuring electromagnetic radiation, in particular thermal radiation, at to which a transducer element alternates with the to via an electromechanical modulator measuring radiation and the radiation of a reference source applied and from both the Difference is formed, characterized in that that to compensate for the fluctuations in the reference radiation, the deviation of the reference radiation from a desired one Level determined and that the deviation and the difference signal amplified to the same extent and in matching phase position are added to a resulting difference signal, which is brought to the display after sufficient amplification. 2. The method according to claim 1, characterized in that the electromechanical modulator an electrical reference signal corresponding to the modulator frequency is generated, which after corresponding Amplification with the beam to be measured received via the transducer element lungs energy proportional electrical signal in matching phase position mixed to a resulting difference signal and that from it resulting difference signal is fed to a display element after sufficient amplification. 3. The method according to claim 2, characterized in that for the correct sign display the difference signal to be displayed via a phase-sensitive, controlled by the reference signal Rectifier is supplied to the display element. 4. Apparatus for performing the method according to claim 3, characterized by a self-excited, position-independent rotary pendulum (D) which is designed at one end as a modulator (B) for modulating the radiation to be measured (SO) and which controls a pulse generator (F) in this way that from this a constant electrical reference signal (■ SJ coherent to the radiation signal is produced, and through a mixer stage (M ₂ ) known per se, of which one input for feeding in the electrical reference signal (S ₄ ) via an amplifier (A) is connected to the output of the pulse generator (F) and the other input for receiving the radiation-proportional signal via a narrowband selective amplifier (F ₁ ) leads to the output of the converter (E) and the output of the mixer (M ₂ ) leads to a display element (Z ) conventional design for displaying the resulting difference signal (S ₉ ) is connected. 5. Apparatus according to claim 4, characterized in that a phase-sensitive rectifier (LJ) is _{connected between the mixer (M 2} ) and display element (Z), which is electrically connected to the output of the pulse generator (F) for modulation by the reference signal (S ₄₎ connected is. 6. Device according to claims 4 and 5, characterized in that between the mixer (M ₂ ) and amplifier (F ₁ ) a further mixer (M ₁ ) with a subsequent narrow-band selective _{amplifier (F 2} ) is connected, one input of which is connected to the output of the amplifier (F ₁ ) and its second input for feeding in an error signal (S ₅ ) with the output of an. known arrangement (R) is connected, in which arrangement (R) the error signal (S ₅ ) is formed as the difference between the signal of a reference radiation source and the appropriately amplified reference signal (S ₄ ) . 1 sheet of drawings