Illuminator having brightness compensation

Illumination – Plural light sources – With modifier

Reexamination Certificate

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Details

C362S242000, C362S297000, C362S260000, C362S097200, C362S247000, C362S225000, C362S234000

Reexamination Certificate

active

06364505

ABSTRACT:

BACKGROUND OF THE INVENTION
This invention relates to an illuminator suited for radiology use, and is especially directed to a illuminators and light boxes for viewing radiographs (x-rays) or for viewing photographic negatives or transparencies. The invention is more specifically concerned with an x-ray illuminator that provides even lighting over its surface without bright or dark areas to facilitate film-based studies by radiologists or other professionals.
At present, where the radiologist is working with traditional film images a lighted illuminator is required, which typically is a light box having lamps contained inside it and a flat glass diffuser or screen on the front face for back lighting the radiographs. Illuminators are frequently used in hospitals and clinics for analysis and study of a patient's internal tissues.
Where soft tissues are involved, an extremely even lighting is required. However, in a traditional back-lighted unit there is considerable variance in light intensity over the area of the diffuser screen, depending on the relative position of the bulb or tube behind it. Where soft tissues are the subject of the radiograph, even a small variation in illumination intensity can mask rather faint details in the images. For certain applications, these variations can obscure changes from one image to another, such as x-rays taken of the same patient at two different times.
The typical illuminator is generally in the form of a light box, containing a number of fluorescent tubes, and a glass plate on the front wall serving as diffuser screen. A reflector, usually in the form of a metal sheet coated with high-reflectance white paint, is positioned behind the tubes. There are also ballasts and other electrical drive elements inside the light box for providing the appropriate electric power to the tubes. Because the tubes are individual light emitters, the light emanating through the front diffuser screen tends to be more concentrated at the tube positions. Also, even the most carefully engineered fluorescent tubes tend to be measurably brighter at the center of the tube than near the ends, and so the illumination likewise varies from bright to dim between screen positions over the center and ends of the tubes.
The current international standards for x-ray illuminators, which have been proposed for the United States, include the need for uniformity of light output across the entire viewing surface of the front diffuser screen. There are also certain minimum light output standards established in this country for mammography illuminators. The illuminator industry has faced a problem in attaining these two goals with existing fluorescent tubes, as these tubes exhibit a high degree of non-uniformity over the length of the lamp. For instance, a standard 4-foot-long or 5-four-long fluorescent tube may have a center portion that is 50% brighter or more than the regions near the two ends of the same tube. However, uniformity of light output is necessary in comparing radiograph findings within regions of the same radiograph image, and also when comparing current film records with older sequential studies. Even, uniform light output across the illuminator aids in delineation of significant findings which could potentially be masked by non-uniformities in the illumination.
The industry is aware of this problem, and there have been several attempts made at correcting non-uniformity of light distribution.
One prior attempt has involved using an array of smaller, i.e., 18-inch, bulbs or tubes aligned vertically, rather than having a smaller number of long tubes arranged horizontally. These usually require the array to be linear, although a hatched or herringbone pattern is possible. Neon bulbs can be included at certain places in the grid to try to improve uniformity. However, it has been found that the light output from the array of smaller tubes cannot match the light output that can be attained by using the larger tubes. Other factors also disturb the attempts to obtain uniformity. There can be light output variation of 10% or more between fluorescent tubes, even when coming from the same manufacturing batch. There can also be variances from ballasts, even if the ballasts are considered “matching,” and from paint variations in different reflector sections. In addition, the shorter fluorescent tubes have been found to have reduced lamp life as compared with longer tubes.
Prior attempts have been made to improve the reflector to better distribute the light around both ends of the tubes, that is, to try to direct more light into these “dead” areas. These reflectors can be designed in a parabolic curve or a shape simulating a parabolic curve over the lengthwise direction, with the bulb centered longitudinally across it, in an attempt to distribute more light into the area between bulbs. Additional angled reflectors may be used, usually with only limited success, in an attempt to bolster light output at the tube-end portions of the illuminator, i.e., at the “dead” areas.
Other attempt have included increasing the box depth to increase light diffusion. Again this has had only limited success, and the larger box size also creates additional inconvenience.
OBJECTS AND SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide an x-ray illuminator that avoids the drawbacks of the prior art.
It is another object to provide an illuminator that compensates for any unevenness in illumination due to the lamps and reflectors, to permit more reliable analysis of radiographic images.
It is a further object to provide an illuminator that attains even illumination without the need for additional lamps or additional reflectors.
In accordance with an aspect of the present invention, an x-ray illuminator comprises a housing having a front side; a plurality of fluorescent tubes or the equivalent within the housing; an internal reflector situated behind the fluorescent tubes for directing light from the tubes towards the front side of the housing; a transparent diffuser plate at the front side of the housing on which radiographs or transparencies are placed for viewing; and circuitry for driving the fluorescent tubes. To obtain uniform illumination the reflectance of the reflector can be varied over its surface, the transmissivity of the screen can be varied over its extent, or both. For example, the internal reflector can have a reflectance that is reduced at positions directly behind centers of the fluorescent tubes and which gradually increases to maximum reflectance at positions at ends of the tubes and at positions away from centerlines of the tubes. Alternatively, the diffuser plate has a transmissivity that is reduced at a position directly in front of the centers of said fluorescent tubes and gradually increases to a maximum transmissivity at positions towards the ends of. the tubes and at positions away from the centerlines of the tubes.
Correction of non-uniformity of light output can be carried out by using the following procedure: a. Surveying the light output of the viewing surface at multiple points; b. From the survey, creating a “topographical” map of light output for the entire viewing surface, with contour lines of equal luminance being displayed; and c. From this topographical map of light output, designing a reflector or absorber which is painted with a gradient of increasingly absorptive paint at regions of increased light output. This generally means there is a higher concentration of photo-absorbent of dark pigments in the center, and progressively lower concentrations of dark pigments towards the ends of the fluorescent tubes and other reduced-output regions. This is generally the opposite of what is currently done, where the reflector is coated throughout with as reflective a medium as possible. In contrast to the prior art, the technique of this invention intentionally reduces light output in the brightest areas of the illuminator to equal that of the areas of lowest illumination.
The result of this process is a reflector and/or absorbe

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