DE911577C - Process for the production of low-noise sound films - Google Patents

Description

Method for producing sound films with low background noise It is known that every sound film has a certain basic noise which is particularly disturbing at those points in the recording where small amplitudes are recorded. According to the previous view, the noise of a film is essentially determined by the grain diameter of the emulsion. For example, below an average transparency of 0.5 , the larger the grain diameter, the greater the noise. It is also known that the gamma value and the density value of the blackening curve also have a certain influence on the noise.

Extensive research into this problem has led to new ideas about the noise and thus also to a new teaching on how to reduce the noise or can eliminate. According to these investigations, the noise is a transparency fluctuation, not only on the grain size of the emulsion, but also on the steepness of the Transparency exposure curve (T-E curve) is dependent.

The T-E curve for each film emulsion can be derived from the associated Determine the blackening curve by not using the logarithm of the exposure as the abscissa, but rather the exposure itself and chosen in place of the blackening due to the Formula S = - log T the transparency is set. In Fig. Z there are three blackening curves i, 2 and 3 shown for three different footage.

The associated T-E curves are shown in Fig. 2 and are marked with the corresponding Numbers denoted. The blackening curves shown in Fig. Z are essentially straight forward assumed. These curves can also be more curvilinear get lost. In the latter case, the corresponding T-E curves can become rectilinear.

The found dependence of the noise on the grain size and the steepness of the TE curve can be expressed by the formula R = cd-ZIT! DE. In this formula, R denotes the absolute noise, the transparency difference that a comparison strip (of about 800 Hz) has, which produces the same deflection on a measuring instrument as the noise strip, d the grain diameter of the emulsion in microns, dTAE the steepness of the TE curve , c is a constant that represents the noise that is present with a grain diameter of i u. and a steepness of dT / dE = i.

In the transparency-exposure curve T = f (E) , the transparency T is plotted on the ordinate in percent and the exposure E on the abscissa in lux-seconds. These curves are different for different film emulsions. The steepness d T /, d E of such a curve represents a measure of the possible fluctuation in transparency at the respective point of the curve. In the case of different film materials, the transparency fluctuation 4 T at the corresponding point of the curve, with the same exposure fluctuation AE, is greater, the steeper the TE curve belonging to the film material is.

The noise is therefore a fluctuation in transparency, ie: # with large Grain diameter and small slope of the T-E curve has the same size as with small Grain diameter and correspondingly greater steepness.

Based on these considerations, the patent proprietor suggests avoidance or elimination of the noise before, by choosing the emulsion or the photographic one Treatment, e.g. B. Exposure to achieve such a T-E curve that the mean Transparency lies in an area with the lowest possible slope, or to ensure that that the product of the grain diameter and the steepness of the T-E curve is possible is small. The grain size can be taken into account accordingly. Becomes a Film with a large grain is used in the emulsion, so will the noise that is caused by the enlarged grain, by a corresponding reduction in the The steepness of the T-E curve is reduced or canceled, and vice versa.

The above considerations have been confirmed by experiments Investigations carried out on various film emulsions. That The result of these investigations should be on two commercially available films I and II, for example be set out.

The average grain size for film I was 2.9 and that for film II o, 8. The absolute noise R was in film I with 7 io-3 and in film II with 4.6 - io-3 measured for a mean transparency of o; 65. The absolute noise is related to the maximum possible difference in transparency of i. The ones about the movies Corresponding T-E curves are derived from the corresponding blackening curves for which the blackening as a function of the logarithm of the exposure E is shown is determined in such a way that the starting points of both blackening curves for Coincidence were brought, otherwise with the same steepness of the blackening curves different steepnesses of the T-E curves would result. For the film I arose for the steepness d T / A E # 0.4 and thus according to the rule given for film 1I i, o.

If the values obtained in this way are used in the output equation, so one gets in good agreement for the constant in Fiten I the value o, oo6o and for film II the value o; 0058. This knowledge confirms the previous theoretical Considerations; in addition, a further lesson for reduction can be derived from this derive the noise, which is that the product of grain size (in microns) and slope (reciprocal lux-seconds) is less than 0.8.

The following procedure can be used to measure the grain size: A unit area of the developed emulsion is viewed under a microscope, and the grains present in the unit area become in diameter and number certainly. The mean grain diameter is calculated by averaging.

Claims (1)

Claim: A process for the production of low-noise photographic sound recordings on granular light-sensitive layers, characterized in that the choice of the emulsion or the photographic treatment, e.g. B. Exposure, a transparency-exposure curve is obtained; in which the mean transparency is in a range so low that the product of d (grain diameter in microns) and d T / AE (in reciprocal lux seconds) is as small as possible, preferably less than 0.8.