Abstract:
A universal diagnostic platform (UDP) is described which incorporates several measurement modules for testing a device under test (DUT). Users can switch between measurement modules without removing the DUT. The UDP employs a common fixturing and software system for all the modules.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]    This application is a continuation of, and claims priority from, Provisional Patent Application Serial No. 60/361,406, filed Mar. 5, 2002. 
     
    
     
       BACKGROUND OF THE INVENTION  
         [0002]    1. Field of the Invention  
           [0003]    The invention relates to systems for testing and diagnostics of semiconductor wafers and integrated circuits.  
           [0004]    2. Discussion of Related Art  
           [0005]    It is well known in the art to use various analysis tools to test and debug integrated circuits (IC) during the design, development, and manufacturing phases. Various tools are used to check the operating speed of the devices on the IC, to characterize its response to various inputs, and to investigate areas susceptible to failure. Many of these devices use light, either reflected or omitted from the IC to perform the analysis.  
           [0006]    Since various testing equipment have various requirements, it is conventional in the prior art to build each testing apparatus as a separate tool/platform. This increases the cost of each tool, requires more floor space to house all the needed tools, and slows the testing, as the IC needs to be moved from tool to tool. Additionally, each tool requires different adapter in order to place the IC on its specially designed IC holder.  
           [0007]    Examples of such prior art stand-alone system include diagnostic systems for performing laser probing of changing electric fields and free carrier distributions inside integrated circuits; emission systems for performing static emission analysis; systems for performing thermal mapping of IC&#39;s; systems for performing picosecond imaging circuit analysis (PICA); systems for performing measurements of resistive shorts using laser scanning techniques. However, users often need to perform a number of analyses on a particular packaged part or wafer, so they need to have all of the stand-alone tools at their disposal and need to move the IC from tool to tool to perform these various tests.  
           [0008]    For example, a user might look at a device using static emission to find sites on the device which are drawing excessive power. Once the sites are located the user might wish to use a separate time-resolved photon emission tool to probe dynamic activity in a net near the location of the excessive emission. However, Fixturing the IC in each of the diagnostic machines typically takes an hour or more. Moreover, in each individual tool electrical connections, cooling apparatus for the device under test, etc. are provided independently, thereby increasing the cost of each tool. Furthermore, once the IC has been mounted on the second tool, the area of interest on the IC needs to be identified and located again. Thus, performing more than one type of testing on an IC is a cumbersome operation.  
           [0009]    A user may also switch among several tools as he performs a variety of measurements while trying to discover the root cause of the problem. However, settling time for the device, if it requires cooling before moving it to the next tool, can take several hours. In most cases the tester is required during device setup. Tester time is expensive and often difficult to obtain.  
           [0010]    Therefore, there is a need in the industry for a simplified process for enabling more than one type of testing on an IC without transferring the IC among various testers.  
         SUMMARY  
         [0011]    The present invention solves the above noted disadvantages of stand-alone tools by providing a universal platform for performing variety of measurements without requiring removal and transfer of the device under test.  
           [0012]    In one aspect of the invention, a universal diagnostic platform (UDP) is provided for performing a variety of device analysis and measurements. The UDP is intended to be extendible, flexible, and upgradeable. The user mounts the device once in the platform and leaves the device, electrical stimulus, cooling, and other components of the fixturing in place. The platform incorporates provisions for moving collection optics to a desired location on the IC to be measured. The UDP support a number of modules, e.g., one, two, or three modules for different analysis and measurements.  
           [0013]    According to another aspect of the invention, various modules can be added and removed with or without the DUT in place. The user can switch between installed modules using a software interface.  
           [0014]    According to yet another aspect of the invention, the software interface is common to the platforms and may incorporate control and monitoring of the UDP, optical image navigation, CAD navigation linked to image, simulation extraction and comparison, data analysis.  
           [0015]    According to a further aspect of the invention, a UDP is provided, which includes a vibration-isolated platform having IC mounting fixture provided thereupon. A multiple-modules loading plate is provided in registration/alignment with the platform for mounting thereupon testing modules. A collection optics arrangement is mounted on a movable stage. A plurality of movable mirrors is provided in registration/alignment with the collection optics arrangement. The movable mirrors are arranged so as to selectively provide optical path to at least one of the testing modules. A controller provides motion signals to control the movement of the movable stage and the movable mirrors. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0016]    [0016]FIG. 1 is a block diagram depicting the general architecture of an embodiment of the invention.  
         [0017]    [0017]FIG. 2 is a general schematic showing a side view of an embodiment of the invention.  
         [0018]    [0018]FIG. 3 is a perspective view showing an embodiment of the invention.  
         [0019]    [0019]FIG. 4 is a perspective view of an optical collection arrangement according to an embodiment of the invention.  
         [0020]    [0020]FIG. 5 depicts yet another embodiment of the mirror servo and lens system, which may be used in any of the embodiments of the inventive universal platform.  
         [0021]    [0021]FIG. 6 depicts yet another embodiment of the mirror servo and lens system, which may be used in any of the embodiments of the inventive universal platform. 
     
    
     DETAILED DESCRIPTION  
       [0022]    [0022]FIG. 1 is a block diagram showing a high level layout of an embodiment of the inventive platform. The platform comprises integral system components, generally  110 , and removable modules, generally  120 . The integral system components  110  are fixed to the universal platform  100 , while the removable modules  120  are interchangeable and may be any testing module having provisions for mounting onto the platform  100 . The mounting is accomplished via a common interface  130 , which may be hardware only, or hardware and software interface.  
         [0023]    The integral system components  110  may include an imaging system  140  (or just collection optics for imaging), a navigation system  145 , a specimen mounting  150  (such as DUT fixturing), and system control  155 . The various interchangeable modules may be any of various testing systems conventionally available only as stand-alone tools. These may be static emission module  160 , time-resolved emission module  165 , thermal mapping module  170 , resistive shorts measurement (TIVA) module  175 , etc.  
         [0024]    [0024]FIG. 2 depicts a side view of an embodiment of the inventive platform. The platform generally comprises a vibration isolation bench  200 , isolated from ground vibration by isolators  205 . Affixed on top of the bench  200  is a fixture table  210  having opening  215 . A specimen mounting board  220  is secured to the fixture table  210 , and a specimen to be inspected  225 , e.g., an integrated circuit or a semiconductor wafer, is mounted to the mounting board  220  and is situated in the opening  215 .  
         [0025]    A movable stage  230 , e.g., an x-y-z stage, is provided on top of the bench  200 , and collection optics  235  is mounted onto the movable stage  230 . Thus, using the movable stage, one can aim the collection optics at any particular region of the specimen  225 . The underside of bench  200  includes a plurality of mounting bays  240 , so that various modules can be attached to the bench  200 . A switchable mirror  245  can be controlled to establish an optical path with mirror  260 , so as to engage the left module  240 ; establish an optical path with mirror  265 , so as to engage the right module  240 ; or withdrawn from the light path, so as to engage the center module  240 .  
         [0026]    The modules that may be mounted in the module bays  240  may be any of the testing modules, such as those noted above. Additionally, if the inspected object is a semiconductor wafer, the modules may be inspection and/or metrology modules, such as Atomic Force Microscope (AFM), Optical CD (OCD), particles monitor, and the like, conventionally available as stand-alone tools. Any of these individual diagnostic modules can be added or removed while the inspected object  225  is left mounted onto mounting board  220 .  
         [0027]    The individual modules may or may not require some alignment with the rest of the system, depending on the mechanical tolerances that can be achieved. For example, 110 μrn blind mechanical repeatability without any alignment may be sufficient. If more accuracy is required, then a manual or automatic alignment procedure will be required. Such techniques are known to those skilled in the art and may include optical pattern matching or using a mechanical sensor to detect the misalignment. The bench  200  will support N modules at any one time; wherein N depends on the final size of the modules and may, for example, be 1, 2, 3, or more.  
         [0028]    The specific modules  240  will depend on the workflow specified by the user. The user will be able to select between the installed modules using a software interface, which will reside on a computer  250 , such as a general purpose computer pre-programmed to perform the specific task required. The computer  250  communicates with the platform hardware and with modules  240  using an electrical communication method. For some modules, minor switching to that module may require manual intervention. For example, a static emission module with a macro mode (greater than 1:3 imaging) may require manual insertion of a lens element in the collection optics  235 . Alternatively, collection optics  235  may include provisions, such as a turret, for handling multiple objectives and/or additional lenses.  
         [0029]    Computer  250  may optionally be provided with communication link to the specimen  225  to be inspected, especially if the object is an active device, such as an IC chip. This is depicted by the broken line connection from the computer  250  to specimen  225 . In such a case, computer  250  may communicate with the specimen  225 , for example providing test signals to stimulate the specimen  225 . On the other hand, a conventional Automated Testing Equipment (ATE)  255  may be used to provide the test signals and communicate with the specimen  225 . In such a case, a synchronization signal may be provided from the ATE  255  to the computer  250 .  
         [0030]    As can be understood from the above two embodiments, one set of collection optics is provided and is shared by the various modules. Optionally, an imaging system may also be incorporated into the system and shared by the various modules. Of course, each module may incorporate its own optimized imaging system, used either in conjunction with or separate from the imaging system residing in the platform. For example, the TIVA module may incorporate laser-scanning imaging. The imaging system is used to locate the region of the DUT to be probed. The imaging system may be used in conjunction with CAD or other layout-assisted navigation to locate the region of the DUT to be measured. However, advantageously, a central collection optics  235  is provided for establishing optical path to any of the modules. Consequently, once an area of interest is found using one module, the area can be immediately tested with a second module by simply flipping the switchable mirror  245  so as to establish an optical path to another module. In this manner, there&#39;s no need to move the specimen  225  and re-acquire the location of interest. That is, the collection optics  235  can remain aimed of the same area of interest and the switchable mirror is simply flipped in order to engage various testers to probe the same area of interest.  
         [0031]    The relevant modules are activated to perform the associated measurement. Imaging and measurement may be performed any number of times in order to identify the source of the failure or problem, or make the appropriate measurement. A means for analyzing, storing, and retrieving the data associated with each of the measurements may be included in the software interface. The common hardware residing in the platform may be shared by the installed modules. Such common hardware may include an imaging system (as already mentioned), a mechanical stage for navigation, a device cooling subsystem, a vibration isolation subsystem, a computer with display and user input devices, a safety interlock system, and so on. Thereby, the cost of each individual module is drastically reduced.  
         [0032]    Computer  250  is pre-programmed with software that may also be modular in design. That is, common core software will control shared hardware components. Data processing, computer-aided design (CAD) navigation, data storage, etc. will also be common. Software particular to a specific hardware module will be loaded or unloaded as needed.  
         [0033]    [0033]FIG. 3 is a perspective schematics of a universal platform according to an embodiment of the invention. The mechanical frame consists of a tabletop  300 , held up by four support legs  315 , which may include conventional vibration isolation mechanism therein (not shown). A fixture table  310  is mounted on top of the tabletop  300 . A movable stage  330 , such as an x-y-z stage, is situated on the tabletop  300 . An optical mirror servo arrangement  335  is mounted onto the stage  330 . An object to be inspected  325 , such as an IC Device Under Test (DUT), is attached to a load plate  320 , and this fixture arrangement is mounted onto the fixture table  310 . The mechanical assembly is designed to be mechanically stable and thermally compensated.  
         [0034]    The DUT  325  is mounted onto the load plate  320  and is stationary. In order to investigate various locations on the DUT, the movable stage  330  is manipulated so as to bring a collection lens to image the appropriate portions of the DUT. The mirror system  335  compensates for the motion of the lens and directs the beam through the same location in the aperture  360  on the tabletop  300 .  
         [0035]    The measurement modules  340  are stationary within the mechanical frame. They may be removable or fixed within the frame. If they are removable, they are located in the frame by some repeatable mechanical system, such as a ball, groove, and plate system well known to those skilled in mechanical design. There may be one or more modules. Three modules are shown in this embodiment as an example. A switchable mirror  370  is provided above the middle measurement module, and allows the light from the collection optics to be sent to the left or the right module  340 , or if the mirror is remove the light can be passed to the middle module  340 .  
         [0036]    [0036]FIG. 4 depicts the mirror servo and lens system  335  in more detail according to a specific embodiment. Collection lens arrangement  400 , such as an objective lens, is movable in X, Y, and Z directions; while the system compensates for the motion of the lens with a plurality of mirrors M 1 -M 5 . Ideally, the mirror servo system  335  will adjust so that the path length from the tip of the lens  400  to the mirror M 5  is constant, and the position of the beam on mirror M 5  is constant. However, if the beam is collimated after the collection lens  400 , compensation to adjust path length is of secondary importance.  
         [0037]    This particular embodiment describes a system that maintains both path length and beam position on the mirror M 5 . The DUT (not shown) is stationary above the collection lens  400 . The lens may be moved in X by moving stage  410 , in the Z direction by moving stage  430 , and in the Y direction by moving stage  420 . Collection lens  400  and mirror M 1  are mounted onto stage  410 . Mirrors M 2  and M 3  are mounted on stage  420 . Mirror M 4 , stage  410 , and stage  420  are mounted on stage  430 . Mirror M 5  may be stationary (for collimated light), or may be movable in the Z-direction by stage  450 .  
         [0038]    If collection lens  400  is moved distance dX in X by stage  410 , mirrors M 2  and M 3  move dX/2 by stage  420  to compensate. If collection lens  400  is moved dY in Y direction by stage  440 , then mirrors M 2  and M 3  are moved dY/2 in Y direction to compensate. If collection lens  400  is moved dZ by stage  430  then M 5  is moved dZ to compensate.  
         [0039]    By the above described means, the beam position and path length at M 5  is unchanged as the lens position in X, Y, and Z is changed, thus allowing different portions of the DUT to be imaged and the optical system to be focused.  
         [0040]    [0040]FIG. 5 depicts yet another embodiment of the mirror servo and lens system, which may be used in any of the embodiments described above. According to this particular embodiment, the collection optics  500 , such as an objective lens, is rigidly mounted onto an x-y-z stage, wherein stage  540  provides x-motion, stage  530  provides y-motion, and stage  510  provides z-motion. Each of mirrors M 1 -M 5  is provided with an independently controlled servo motions S 1 -S 5 . Each of servo motion S 1 -S 5  provides independent transnational and/or rotational motion for a single one of mirrors M 1 -M 5 . Thus, when the controller provides motion signal to the stage in order to place the collection optics at a location of interest, the controller also provides motion signals to each of the servos S 1 -S 5 , so as to position each of the mirrors in a situation what would together compensate for the motion of the collection optics.  
         [0041]    Another feature depicted in FIG. 5 is the provision of a solid immersion lens  590 . That is, as is well known, photon emission testing is performed under very low photon emission count. Accordingly, means for efficiently collecting photons are highly desirable. Therefore, when one of the testing modules performs photon emission detection, a solid immersion lens  590  may be provided in the collection optics  500 .  
         [0042]    [0042]FIG. 6 provides yet another embodiment of the mirror servo and lens system, which may be used in any of the embodiments described above. This embodiment is similar to that depicted in FIG. 5, except that a plurality (in this example—two) of collection optics arrangement is provided. Notably, a provision  670 , such as a turret or servo mechanism, can be manually or automatically controlled to select between collection optics  600  and  680 . For example, the two or more collection optics may have different magnifications; or one arrangement may have an immersion lens  690  while the other not. Thus, depending on the test to be performed, the user may select the appropriate collection optics proper for the test.  
         [0043]    An example of a general operation procedure is as follows. The user selects and installs modules that will be used during device diagnosis session. The device under test (DUT) is mounted in the DUT fixture. The appropriate cooling, electrical stimulus, etc. are provided and connected. The user applies power to the device using a power supply and stimulates the device using an electrical stimulus of some kind. This may be done using the computer of the inventive platform, or using a conventional tester equipment, e. g., an ATE. The user selects the appropriate optics for imaging. The user prepares the system by navigating to the location of interest using the integrated mechanical stage. The navigation system may include navigation with integrated imaging (LSM, SEM, flood illumination, etc.), CAD-assisted navigation with integrated netlist, etc. The goal of the navigation is to located regions of interest to be analyzed by the various modules. Various structures on the DUT may be used to assist in navigation.  
         [0044]    With the DUT in the desired condition, i.e., the optics aimed at the appropriate location on the DUT, as the DUT is stationary, the user uses one or more of the modules to perform a measurement. Data is acquired, stored, and analyzed using a computer. The user repeats the process of selecting modules and performing measurements until the problem is solved.  
         [0045]    The various modules may include static emission (for example, silicon CCD camera, MCT 2D array, or InGaAs 2D array); dynamic emission (for example, time-resolved imaging or non-imaging photon counting detector); thermal mapping (for example Si bolometric array); LSM incorporating LJVA, TIVA, or other laser-based circuit analysis technique. Modules may include non-invasive methods for measuring current-voltage curves (IV) curves inside a device, or absolute voltage levels within a device. Modules may also include focussed ion beam (FIB), atomic force microscope (AFM), scanning electron microscope (SEM), etc. Other modules may be incorporated as they are identified and developed.  
         [0046]    While the invention has been described with reference to particular embodiments thereof, these embodiments are not intended as limiting the invention, but rather as an aid for understanding the full scope of the invention, as defined by the appended claims. While various modifications and changes may be readily recognized by those of ordinary skill in the art, any such modifications and changes that are encompass by the spirit and scope of the invention should be considered as part of the invention.