BACKGROUND OF THE INVENTION

This invention relates to electro-optic sensing of voltage, and more particularly, electro-optic sensing of voltage as a function of position of a large plurality of voltage sources on a surface.

There is a growing need to be able to test and extract voltage information from a voltage-producing surface such as a printed circuit board, an integrated circuit wafer (with or without a package) or a liquid crystal display panel in order to diagnose the integrity of the structure. The present electronic test systems have a technology capable of testing circuit boards or panels (a panel under test or PUT) having a node density not exceeding approximately 100 nodes per square inch.

Certain applications, such as the testing of liquid crystal display panels are best practiced with non-contact sensing techniques such as electro-optic techniques. However, these panels have conductive pixels such as transparent indium tin oxide (ITO) , with a thin-film transistor deposited directly on the glass surface and are therefore, considered very fragile. Such panels also may have an additional insulating layer covering the deposited structure, rendering it impossible to place voltage probes at selected positions on the panel. It is therefore impractical to impose contact testing on such panels. Nevertheless, current and projected production methods and strategies demand that each pixel of such a panel be tested for its ability to change voltage state as well an ability to measure voltage under various conditions

relative to their voltages. The current state of the art does not provide a test technique for such structures.

It is known to use electro-optic devices for serially testing selected nodes of a voltage producing device. Reference is made to U.S. Patent Nos. 4,875,006 and 4,862,075. The subject matter of those patents is incorporated herein and made a part hereof. Therein, the use of a single light beam is described to serially access individual sensor nodes using a unique sensor/laser arrangement giving control over a beam of light whereby a Pockels Cell Modulator employs the electro- optic Pockels effect to sense local electric fields produced by voltage on a surface. Such known devices require control of a beam by scanning technology such as an acoustic-optic deflector or an x-y stage. Known systems are thus limited to single beam, serial data extraction.

SUMMARY OF THE INVENTION According to the invention, a two-dimensional image of — the voltage distribution across a surface at a large plurality of voltage test points of a panel under test is extracted by illuminating the surface with an input beam of optical energy through an electro-optic light modulating means such as an NCAP modulator or other liquid dispersed polymer-based devices, wherein the light modulator is disposed to allow longitudinal probing geometries such that a voltage on the surface of the panel under test causes a power modulation in the optical energy which can be observed through an area optical sensor (such as a camera) for use to directly produce a two-dimensional spatially-dependent power modulation image directly representative of the spatially corresponding voltage state on the surface of the panel under test. Surface cross¬ talk is minimized by placing the face of the light modulator closer to the panel under test than the spacing of voltage sites in the panel under test. The device may operate in a pass-through mode or in a reflective mode. In a pass-through mode, the image is sensed through a transparent panel under test. In a reflective mode, light power is observed upon two-

pass reflection through the electro-optic light modulator. A camera or other imaging sensor can be used as an instrument to detect the spatial image.

An apparatus operating in accordance with the method of the invention includes an optical energy source, such as a laser, an electro-optic sensor (light modulator) exhibiting an electro-optic effect, such as the light scattering effect present in NCAP (nematic curvilinear aligned phase) or PDLC (polymer dispersed liquid crystal) films, when placed in close proximity to the panel under test, and means for spatially observing a spatially-modulated light beam.

The invention has particular application to noninvasive testing of high-density integrated circuits and testing liquid crystal display (LCD) panels prior to connection with electrical interfaces.

The invention will be better understood by reference to the following detailed description in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a block diagram of a first embodiment of the invention.

Figure 2 is a block diagram of a second embodiment of the invention. Figure 3 is a side cross-sectional view of an electro- optic crystal adjacent a panel under test.

Figure 4 is a graph of an illustrative voltage spatial distribution in connection with Figure 3.

DESCRIPTION OF SPECIFIC EMBODIMENTS

Figures 1 and 2 illustrate two embodiments of a voltage imaging system 10 or 10' for observing voltage at a large plurality of positions 12 on a surface 14 of a panel under test (PUT) 14 or 16. Figure 3 illustrates a detail of a portion of the system 10. The PUT 14 is a panel transparent to optical energy at the wavelengths of interest and the PUT 16 is a panel which may be opaque to optical energy. The PUT

14 may be a silicon chip or the like and the PUT 16 may be a liquid crystal display (LCD) panel. In any case, the PUT 14 or 16 may be connected in some way to a source of power (not shown) in order to produce voltages at selected sites on the surface 14 of the panel 14 or 16.

In order to probe the voltage, there is first a source 20 of optical energy, such as a xenon, sodium, or quartz halogen lamp, a pulsed or continuous laser or the like. The source optical energy is channeled into a source beam 22 and processed to produce an optical input beam 24 which may expanded and colli ated with a beam expander 28. For this purpose, there may be provided a lens, mirror or fiber optic system 28 to expand and collimate the source beam into the input beam 24. The collimated input beam preferably has a constant or at least known power density cross-section.

The input beam is directed into an electro-optic modulator means 30 or 31 of a specific type, structure and possibly atomic or molecular axis orientation. A suitable modulator 30 may be a modulator fabricated with an NCAP or PCLD film. This power modulator 30 utilizes the light scattering properties of liquid crystal droplets encapsulated in a polymer matrix. The encapsulation structure produces a curvilinear alignment of the liquid crystal molecules, and this aligned phase can be optically switched by a controlled electric field as desired. The device is therefore switching from a highly light scattering state to a highly transmissive state. Biasing the device between the two states allows the modulator to exhibit a roughly linear light to voltage transfer function. The electro-optic modulator means 30 has a first face 32 and an opposing second face 34 to allow longitudinal probing geometries, as explained hereinafter. The first face 32 has a conductive coating 36 which is transparent, such as indium tin oxide (ITO) , and which is electrically coupled to a voltage common 38, such as ground. The second face 34 of modulator means 30 (Figure 1) is transparent to permit transmission of the input beam through the PUT 16. The second face 34 of modulator means 31 (Figure

2) has a highly-reflective noncόnductive coating 33, which produces a retro-reflection of the input beam 24. The second face 34 is disposed to be adjacent an area 40 of the surface 14 of the PUT 16 or 18. The modulator means 30 is oriented to intercept at least a portion of the input beam 24 directed into the modulator through the first face 32 to impinge on the second face 34 at a position of the modulator means 30 or 31 closely adjacent the area 40 of the surface 14 of the PUT 16 or 18. The voltages at positions 12 at or near the surface 14 interact with the modulator means 30 to cause changes in the optical power transmission of the input beam 24 in alignment with positions 12 of voltages. This is observable as a spatially-dependent change in collimated alignment of an output beam 42 with the input beam 24, the changes being proportional to voltages at the positions 12 on the surface

14.

Figure 4 illustrates the interaction between a PUT 18 and a modulator means 31 of a type having a reflective coating 33 on the second face 34. The reflective coating may be a dielectric coating or stack of dielectric material, and an air, solid or liquid gap is presumed to exist between the second face 34 and the surface 14. In operation, the electric field (E-field) of each position 12 penetrates the modulator means 31 causing a change in the scattering or absorption properties of the light beam, preferably in collimated alignment with every point 12 in direct and accurate proportion to the voltage at the point 12. Voltage VI causes a positive change in power modulation. Voltage V2 causes a negative change in power modulation. Voltage V3 causes a positive and extreme change in power modulation. The power modulation is a function of position and is directly proportional to the voltage differential between the surface 14 and the grounded conductive coating 36 on the first face of the modulator 31. The beam exiting the modulator 31, which in this example has made two passes through the modulator, therefore contains spatially modulated light power which

carries information regarding the voltage at each point 12 relative to the reference of coating 36.

The separation between the second face 34 and the surface 14 are controlled, preferably being as close as practical without causing side effects, such as shorts, thermal transfer or mechanical distortion due to stress. The selection of the spacing is made to maximize the ratio of signal to noise, particularly noise attributable to cross¬ talk from electric fields produced by adjacent points of voltage. A working rule, applicable particularly to LCD panels wherein the source of voltage is an area defined as a pixel area (112 in Figure 4), is to place the second face 34 of the modulator relative to the surface 14 at less than the distance between positions 12 and preferably no more than 30% of the diameter of the pixel area. The separation may be controlled by a mechanical positioner, such as a movable table arrangement (not shown) .

In order to extract that information, means are — provided for detecting the change in modulation in the image across the output beam 42 to analyze the voltages. Referring to Figures 1 and 2, the detectors may comprise means such as a sensitive camera 48 receiving light through for example a focussing lens 46, which intercepts the spatially-dependent power modulation for producing, as seen by the camera, an observable map in two dimensions having features corresponding to voltage magnitude. Additionally, image processing can be used to enhance the ratio of signal to noise through manipulation in digitized format of the image captured by the camera 48. (Digital image manipulation is a known technique.) In a single pass system, as shown in Figure 1, imaging is in line. In a multiple pass system, as shown in Figure 2, sensitivity may be enhanced by passing the beam through the modulator twice. The output beam 42 is separated from the collinear input beam 24 by means of a beam splitter 50. As a still further alternative, the input beam and the output beam can be separated by orienting the reflective surface 33 of the phase modulator 31 so that it is not perpendicular to

the incident radiation. The output beam 42 is thus separated upon reflection, and a beam splitter is not needed.

The invention has now been described with reference to specific embodiments. Other embodiments will be apparent to those of ordinary skill in the art. For example, multi- quantum well electro-absorption modulators may be used. It is therefore not intended that this invention be limited, except as indicated in the appended claims.