JPH0786652B2 - Color film reader - Google Patents

Description

The present invention relates to a color film reader for reading a photographed color film to obtain an electric image signal,
In particular, it is possible to realize optimum gradation and color reproducibility according to various photographing conditions such as an exposure amount at the time of photographing.

(Prior Art) Conventionally, in the field of photographic transmission, a device for obtaining a video signal by electrically reading a photographic film has been put into practical use. Such a device was dated November 21, 1985. It is described in detail in the published technical report of the Television Society of Japan such as "Direct photographic transmission from 35mm film".

(Problems to be Solved by the Invention) By the way, the above-mentioned device is intended for a black-and-white film, and it is not possible to read a color film to obtain an electric color video signal.

On the other hand, it is possible to extract the video signal from this color film by shooting the color film with a color video camera equipped with a negative / positive reversal function, but to obtain the optimum shot video signal according to various conditions at the time of shooting. Was difficult.

(Means for Solving Problems) The present invention has been made in view of the above-mentioned actual circumstances,
It is an object of the present invention to provide a color film reading device capable of reading a color film and obtaining a video signal having good gradation and color reproducibility.

In order to achieve this object, the present invention photoelectrically converts the transmitted light from the color film 1 obtained by the main scan and the pre-scan performed before the main scan, as shown in FIG. video signal corresponding to each color of S _R, S _G, and the imaging element 2 for outputting respectively S _B, each video signal obtained by the above main scan S _R, S _G,
A video signal processing circuit 3 to output the respective converted based on S _B to the predetermined conversion data, by the pre-scan to generate the conversion data, control to write the converted data this generated in the video signal processing circuit 3 The circuit 4 and the memory means 5 in which the light transmittance characteristic data for each color with respect to the exposure amount of various color films obtained by measurement in advance are stored.
And each of the video signals S _R , S _G , S _B obtained by the above prescan.
Of the color film 1 and the light transmittance characteristic data of the color film 1 in the memory means 5, the exposure range at the time of photographing is determined, the determined exposure range corresponds to the gradation, and the main scan is performed. When the levels of the obtained video signals S _R , S _G , and S _B are made to correspond to the light transmittance characteristic data, the exposure amount determined according to the level of each of the video signals is set to each of the video signals S _R , S.
_The gradation characteristic conversion data is obtained for each of _G and S _B , the gradation characteristic conversion data is written as the conversion data in the video signal processing circuit 3, and each video signal S _R , S _G , obtained by the main scan is obtained. the S _B is intended to provide a color film reading apparatus characterized by converting gradation characteristics based on gradation characteristic conversion data written above.

(Operation) According to the color film reading apparatus having the above-mentioned configuration,
Optimal gradation characteristic conversion data and color correction data are set for each color film 1, and video signals S _R , S _G , S _B corresponding to the color film 1 are set based on these gradation characteristic conversion data and color correction data. Can be converted to obtain video signals S _R , S _G , and S _B with good gradation and color reproducibility.

(Embodiment) A preferred embodiment of the present invention will be described in detail below with reference to FIGS. 1 to 7.

In the color film reading apparatus according to this embodiment, the color film 1 is supported by a film holder 6 as shown in FIG.

Then, the color film 1 is irradiated with light from a light source 8 using a halogen lamp or the like via a projection system lens 7, and this light passes through the color film 1 and then passes through an iris 9 and a focusing system lens 10. An image is formed on the image plane of the line sensor 2 using a CCD (charge coupled device) which is an image pickup device in the present embodiment.

In this line sensor 2, red R, green G, and blue B color filters are masked by one pixel each, so that the line sensor 2 has a video signal S _R corresponding to each color of R, G, B. , S _G , S _B are sequentially output.

In this line sensor 2, the main scanning is performed electrically and the sub-scanning is performed mechanically.

The video signals S _R , S _G and S _B output from the line sensor 2 are digitized by an AD (analog-digital) converter 11 and supplied to a digital clamp circuit 12.

As shown in FIG. 2, the digital clamp circuit 12 includes a shield pixel signal averaging circuit 13 and a hold circuit 14, and a plurality of shield pixel signal S _B as shown in FIG. The pixel signal is averaged by the shield pixel signal averaging circuit 13,
The value is held by the hold circuit 14 until the start of the next averaging after one main scanning period, and the averaged value is the effective pixel signal, that is, the video signal.
S _R, S _G, the video signal S _R by subtracting the S _B, S _G, thereby performing the determination of the black level of the S _B for each main scan.

Thus, by averaging a plurality of shielded pixel signals, it is possible to realize a clamp with a good SN.

Also, when analog clamp is performed, if the video signal period (effective pixel signal period) becomes long, it becomes necessary to increase the CR time constant of the circuit, and it becomes difficult to realize a stable clamp circuit without sag. On the other hand, according to the digital clamp circuit 12 as described above, stable clamping can be performed regardless of the length of the video signal period.

The shield pixel signal means the line sensor 2
Is a signal obtained by optically shielding a predetermined number (for example, 16) of the pixels, and is a shadow (black) level signal. In the present embodiment, the video signals S _R , S
_G and S _B are obtained from 1000 effective pixels.

Each video signal S _R , S _G , S _B output from the digital clamp circuit 12 is stored in a memory circuit 15 using a RAM (Random Access Memory) or the like, and this memory circuit 15 uses a microcomputer. It is designed to be accessed by the control circuit 4.

The control circuit 4 holds the transmittance characteristic data with respect to the exposure amount of various color films in the disk drive device 5 as shown in FIG. A code signal corresponding to the type is input.

The control circuit 4 controls the video signals S _R , S _G , S
_The exposure condition is determined based on the comparison between _B and the transmittance characteristic data of the color film designated by the code signal.

Further, the control circuit 4 generates gradation characteristic conversion data according to the determined exposure condition, and this gradation characteristic conversion data together with a predetermined address is combined with the gradation characteristic conversion circuit 17 of the video signal processing circuit 3 described later. It is designed to be supplied to.

Further, the control circuit 4 supplies predetermined color correction data together with an address to a matrix circuit 18 of the video signal processing circuit 3 described later according to the type of color film.

Further, the control circuit 4 sets the iris 9 to an aperture value according to the exposure condition.

On the other hand, the video signals S _R , S _G , and S _B output from the digital clamp circuit 12 include a gradation characteristic conversion circuit 17 that converts gradation characteristics, a matrix circuit 18 that performs color correction, and a color address generator 19 Video signal processing circuit 3 including
To be supplied to.

Here, the gradation characteristic conversion circuit 17, as shown in FIG.
Address selector 20, conversion circuit 21, and data selector 22
And the color address data supplied from the address generator 19 is added to the video signals S _R , S _G , and S _B serially output from the digital clamp circuit 12, and the color address selector 20 is connected. Through conversion circuit 21
Is supplied to.

In addition, the gradation characteristic conversion data supplied from the control circuit 4 is written in the conversion circuit 21 in advance for each address corresponding to the address data, and the supplied video signals S _R , S. _G and S _B are subjected to gradation conversion based on this gradation characteristic conversion data and output.

Then, the converted video signals S _R , S _G , S _B are output in parallel via the data selector 22.

As described above, the gradation characteristic conversion circuit 17 in the present embodiment is
Since each of the video signals S _R , S _G , and S _B corresponding to each color of _R , _G , and _B is serially processed, the number of bus lines can be reduced as compared with the case where parallel processing is performed.

By writing various kinds of appropriate conversion data into each address of the conversion circuit 21, not only gradation conversion but also negative / positive inversion, gamma characteristic conversion in the output mechanism, white balance adjustment, etc., as necessary. All data conversions can be done.

Further, the matrix circuit 18, as shown in FIG. 5, includes memory circuits 23, 24 and 25 for coefficient conversion corresponding to the respective video signals S _R , S _G and S _B , an adder 40 and a multiplexer 26. Each of the memory circuits 23, 24, and 25 is provided with three address spaces in which predetermined color correction data a to i are written.

Then, the color address data supplied from the color address generator 19 is added to the video signals S _R , S _G , and S _B output in parallel from the gradation characteristic conversion circuit 17, and the memory circuits are added. Supplied to 23, 24, 25.

These memory circuits 23, 24, 25 determine the level and polarity of each of the video signals S _R , S _G , S _B based on the conversion formulas (1) to (3) below and perform color correction. After conversion, each video signal after conversion
Output R, G, B respectively.

_{R = aS R + dS G +} gS B ... (1) G = bS R + eS G + hS B ... (2) B = cS R + fS G + iS B ... (3) Then, the output of the respective memory circuits 23, 24, and 25 It is supplied to the multiplexer 26, converted to serial and output.

The color correction data a to i are rewritten by the control circuit 4 as appropriate. For example, the coefficient data a to i are rewritten according to the type of the color film 1 as described above. There is.

As described above, since the matrix circuit 18 in this embodiment can perform color correction only by rewriting the color correction data a to i, it is unnecessary to make a hardware change when changing the data, and the coefficient multiplier is also used. Unnecessary.

Then, the video signals R, G, B output from the video signal processing circuit 3 having the above-described configuration are supplied to the output device conversion circuit 27 as needed, and if the output device is a display device, a predetermined gamma signal is output. It corrects it, and if it is a printer, it performs log conversion and outputs it.

It should be noted that the conversion in the output device conversion circuit 27 is performed by the gradation characteristic conversion circuit 17, and the output device conversion circuit 27
27 can be omitted.

The output of the video signal processing circuit 27 is output as a digital signal as it is through the output terminal 28 as needed, but is converted into an analog signal by the OA (digital-analog) converter 29 and output terminal 30. It is designed to be output via.

Next, the operation of the color film reading apparatus having the above-mentioned structure will be described with reference to the flow chart shown in FIG.

First, the aperture is set to the initial state, the first prescan is performed, and the image signals S _R , S _G , and S _B of the color film 1 to be read are taken into the memory circuit 15 (step 1).

Next, the level distribution of the captured video signals S _R , S _G , and S _B is examined, and the transmittance characteristic data with respect to the exposure amount of the film corresponding to the code input from the input terminal 16 is referred to. The exposure range when the color film 1 is photographed is determined (step 2).

Then, the aperture value of the iris 19 is set so that the output signal of the line sensor 2 can be obtained in a large range without being saturated according to the exposure range (step 3).

Next, the second prescan is performed (step 4), 1
The aperture change rate (how many times the aperture has changed with respect to the initial value) is calculated by comparing the data captured by the second and second prescans (step 5).

Using the exposure range, aperture change rate and film transmittance characteristic data obtained from the above results, the gradation characteristic conversion having the conversion characteristic as shown in FIG. 7 for canceling the nonlinearity of the film transmittance characteristic is performed. Create an expression (step 6). That is, when the exposure range H _{1 to} H ₂ in FIG. 7 is associated with the gradation degree of 0% to 100% and the level of each video signal (input of the gradation characteristic conversion circuit) is associated with the transmittance of the transmittance characteristic data, The exposure amount is determined with respect to the level of each video signal, and the gradation degree (output of the gradation characteristic conversion circuit) is determined corresponding to this exposure amount. The gradation characteristic conversion formula is created so that the gradation degree for each video signal can be obtained by such an operation.

Then, based on this conversion formula, the gradation characteristic conversion circuit 17
Conversion data for the input of the gradation characteristic conversion data is obtained, and this data is used as the conversion circuit of the gradation characteristic conversion circuit 3.
Write to 21 (step 7).

The color correction data is stored in each of the memory circuits 23, 2 of the matrix circuit 18 using a predetermined coefficient according to the type of film.
Write to 4,25 (step 8).

This completes the preparations for the main scan.

Next, a main scan is performed (step 9), and the video signals S _R , S _G , S _B obtained by this main scan are converted by the gradation characteristic conversion circuit 17 so as to have a predetermined gradation characteristic (step). Ten).

Thereafter, matrix conversion is performed by the matrix circuit 18 (step 11), and the output device conversion circuit is used.
Gamma correction or log conversion is performed by 27 and output (step 12).

As described above, the color film reading apparatus according to the present embodiment can electrically read the color film by the operations from step 1 to step 12 of the flowchart shown in FIG. 6 and obtain a video signal with good color reproducibility. it can.

Furthermore, by preparing conversion data corresponding to various output devices, one color film reader can support various output devices.

As a result, it is possible to record the contents of the color film, which may be aged over time, without deterioration.

Further, particularly in the present embodiment, since the conversion formula for obtaining the gradation characteristic conversion data is corrected according to the brightness of the subject, the standard exposure is used for the underexposure or overexposure film. A video signal as described above can be obtained.

(Effect of the invention) As is apparent from the above description, the present invention determines the exposure condition based on the video signal corresponding to each color obtained by the prescan, and the determination result and the light transmittance characteristic data of the color film. By converting the gradation characteristics of the video signal obtained by the main scan based on the gradation characteristics conversion data obtained using You can

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a color film reading apparatus according to the present invention, FIG. 2 is a block diagram showing the same digital clamp circuit, and FIG. 3 is an operation state of the digital clamp circuit shown in FIG. Waveform diagram, FIG. 4 is a block diagram showing the gradation characteristic conversion circuit of the embodiment shown in FIG. 1, FIG. 5 is a block diagram showing the same matrix circuit, FIG. 6 is a flowchart showing the same operation, and FIG. 3 is a graph showing transmittance characteristic data and gradation characteristic conversion data. 1 ... Color film, 2 ... Image sensor (line sensor), 3 ... Video signal processing circuit, 4 ... Control circuit.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification number Reference number within the agency FI Technical indication location H04N 1/46 H04N 1/40 101 E (72) Inventor Hiromitsu Kurokawa Moriyacho, Kanagawa-ku, Yokohama-shi, Kanagawa 3-12, Ritsumasa Kobashi, Examiner, Victor Company of Japan, Ltd.

Claims (1)

[Claims] 1. An image sensor for photoelectrically converting transmitted light from a color film obtained by a main scan and a pre-scan performed before the main scan, and outputting video signals corresponding to respective predetermined colors. A video signal processing circuit for converting and outputting each of the video signals obtained by the main scan based on predetermined conversion data, and generating the conversion data by the pre-scan, and converting the generated conversion data into the video. A control circuit for writing in the signal processing circuit and a memory means for storing the light transmittance characteristic data for each color with respect to the exposure amount of various color films obtained by measurement in advance are provided, and each video signal obtained by the prescan is Determine the exposure range at the time of shooting using the level distribution and the light transmittance characteristic data of the color film in the memory means, When the determined exposure range is made to correspond to the gradation and the level of each video signal obtained by the main scan is made to correspond to the light transmittance characteristic data, the exposure amount determined in accordance with the level of each video signal is determined. Gradation characteristic conversion data is obtained for each video signal, the gradation characteristic conversion data is written as the conversion data in the video signal processing circuit, and each video signal obtained by the main scan is the written gradation characteristic. A color film reading device characterized in that gradation characteristics are converted based on conversion data.