Abstract: The invention is directed to a system and method for analyzing an integrated circuit having silicon on insulator (SOI) structure. According to one example embodiment of the present invention, an optical beam arrangement is adapted to direct a modulated beam at a selected portion of the integrated circuit. The beam is sufficiently modulated to inhibit optical beam intrusion on the structure and operation of the integrated circuit. A reflected optical waveform response is obtained from the SOI selected portion. The inhibition of optical beam intrusion enhances the ability to analyze integrated circuits using an optical beam, making possible the use of analysis methods that otherwise would be difficult or even impossible to use.

Abstract: Analysis of a semiconductor die is enhanced by the stimulation the die and the detection of a response to the stimulation. According to an example embodiment of the present invention, a semiconductor die is analyzed using indirect stimulation of a portion of the die, and detecting a response therefrom. First, selected portion of circuitry within the die is stimulated. The stimulation of the selected portion induces a second portion of circuitry within the die to generate an external emission. The emission is detected and the die is analyzed therefrom. In one particular implementation, a response from the selected portion is inhibited from interfering with the detection of the emission from the second portion of circuitry.

Abstract: The present invention is directed analysis of a flip-chip integrated circuit die having SOI structure that improves the ability to image and analyze selected portions of circuitry in the die. According to an example embodiment of the present invention, a lens is formed in a back side of a flip-chip die and over the insulator portion of SOI structure in the die. Light is directed at the lens and the lens is used to focus the light to target circuitry in the die. A reflection from the circuitry is detected and used to analyze the die, such as by imaging the circuitry in the die and identifying defects therein. The lens formed in the die enhances the ability to focus light to selected circuitry in the die and improves the ability to analyze dies having SOI structure through the insulator.

Abstract: Semiconductor analysis is improved via the use of fiber optic communications. According to an example embodiment of the present invention, a stimulation device is adapted to stimulate an integrated circuit die, and the die generates a response to the stimulation. An optical signal generator, either incorporated into the die or coupled to the die, detects the response, converts the response to an optical signal and transmits the optical signal. The optical signal is received at a testing arrangement adapted to analyze the die therefrom. The optical signal is used to analyze the die, improving signal quality and the ability to perform high-speed analysis of the die.

Abstract: The operability of light-based semiconductor die analysis is enhanced using a method and arrangement that directs light between a light source and a die. In one example embodiment of the present invention, a light source is directed to a die in a semiconductor analysis arrangement using a fiber optic cable. The analysis arrangement is adapted to use light received via the fiber optic cable to analyze the die. The analysis includes one or more light-based applications, such as stimulating a selected portion of the die with the light and detecting a response therefrom. In this manner, light can be directed to a die in a variety of analysis implementations, such as for analyzing a die in a test chamber.

Abstract: According to an example embodiment of the present invention, a portion of substrate in the back side of a semiconductor chip is removed as a function of photons emitted through substrate remaining at the back side. The use of emitted photons is used to control the substrate removal process.

Abstract: Post-manufacturing analysis of a semiconductor chip is enhanced via a method and system for viewing emissions through substrate in the back side of the chip. According to an example embodiment of the present invention, a portion of circuitry in a semiconductor chip is excited, and an emission is generated. An optical microscope is directed at the backside of the chip, and an image of the emission is obtained. The optical microscope is coupled to an indium-gallium-arsenic (InGaAs) camera that is used to detect the emission. In this manner, emissions can be detected through substrate in a semiconductor chip.

Abstract: The operability of light-based semiconductor die analysis is enhanced using a method and arrangement that can detect light leakage between a light source and a die. In one example embodiment of the present invention, a light source is directed to a semiconductor analysis arrangement using, for example, a fiber optic cable. The analysis arrangement is adapted to use light from the light source for analyzing the die. A light detection arrangement detects a condition of light leakage from the system and generates a signal representing the condition of light leakage. The generated signal can then be used to control the semiconductor analysis arrangement, such as by deactivating the light source in response to a detected leak, or by allowing the light source to function in response to not detecting a leak.

Abstract: According to an example embodiment of the present invention, a defect detection approach involves detecting the existence of defects in an integrated circuit as a function of at least one applied energy source. In response to energy that is applied to the integrated circuit, response signals are detected. A parameter including information such as amplitude, frequency, phase, or a spectrum is developed for a reference integrated circuit device and then compared to the detected response signal. The deviation in the response and reference signals, and the type of energy source used, are correlated to a particular defect in the device.

Abstract: Semiconductor die analysis is enhanced using a system that is adapted to perturb a die in a test chamber and to detect a response from the die to the perturbation. According to an example embodiment of the present invention, a semiconductor die analysis system includes a test chamber and a docking arrangement adapted to dock with the test chamber. A die is held in the docking arrangement and is presented inside of the test chamber when the docking arrangement is docked with the chamber. Two or more perturbation devices are used to perturb the die, and controller is adapted to control the perturbation. A data acquisition arrangement receives data from the die in response to the perturbation, and the data is used for analyzing the die.

Abstract: Analysis of a semiconductor die having silicon-on-insulator (SOI) structure is enhanced by accessing the circuitry within die from the back side without breaching the thin insulator layer of the SOI structure. According to an example embodiment, a portion of substrate is removed from the back side of a semiconductor die having a SOI structure and a backside opposite circuitry in a circuit side. Electrical connection is made to a portion of the circuitry within the die via a capacitive coupling arrangement. The electrical connection is used to obtain an electrical measurement correlated with circuitry logic states of the die that is used for analysis.

Abstract: Semiconductor analysis is enhanced using a system and method for improving the heat-dissipation characteristics of a semiconductor die. According to an example embodiment of the present invention, a flip-chip integrated circuit die having circuitry in a circuit side opposite a back side is formed having a back side including a thermal conductivity enhancing material. The thermal conductivity enhancing material improves the heat dissipating characteristics of the die during operation and testing and helps to reduce or prevent overheating. An epitaxial layer of silicon is formed in the back side, and circuitry is constructed in the epitaxial layer. Pre-existing circuitry on the circuit side and the newly formed circuitry in the back side are electrically coupled.

Abstract: A method for detecting substrate damage in a flip chip die, having a back side and a circuit side, that uses magnetic resonance imaging. The back side of the die is first globally thinned down and a region for examination is selected. A magnetic field is applied to the selected region and then the region is scanned with a magnetic resonance imaging arrangement. A plurality of perturbations are measured to generate an array of perturbation signals, which are then converted to a local susceptibility map of the selected region of the die. The susceptibility map of the selected region is then examined to determine if there is any substrate damage.

Abstract: According to an example embodiment of the present invention, a semiconductor die having a buried insulator layer between a circuit side and a back side is selectively thinned. During thinning, a selected portion of the bulk silicon layer on the back side is removed and a void created. A circuit is formed in the void and is coupled to the existing circuitry on the circuit side of the die. The new circuit is used to analyze the die during operation, testing, or other conditions. The newly formed circuit enhances the ability to analyze the semiconductor die by adding flexibility to the traditional analysis methods used for integrated circuit dice. The newly formed circuit enables many new ways of interactively using the existing circuitry some of which include replacement of defective circuitry, modification of existing circuit operations, and stimulation of existing circuitry for testing.

Abstract: According to one aspect of the disclosure, the present invention provides methods and arrangements for testing a flip chip SOI semiconductor device after the back side of the chip has been thinned to expose a selected region in the substrate. For some chips, thinning removes substrate material useful for drawing heat away from the internal circuitry when the circuitry is running at high speeds. To compensate for this material loss, a special test fixture having a passive, corrosion-resistant heat-dissipating device is arranged to draw heat from the device.

Abstract: A method and system providing spatial and timing resolution for photoemission microscopy of an integrated circuit. A microscope having an objective lens forming a focal plane is arranged to view the integrated circuit, and an aperture element having an aperture is optically aligned in the back focal plane of the microscope. The aperture element is positioned for viewing a selected area of the integrated circuit. A position-sensitive avalanche photo-diode is optically aligned with the aperture to detect photoemissions when test signals are applied to the integrated circuit.

Abstract: The present invention is directed to enhancing the analysis and modification of a flip chip integrated circuit die having silicon on insulator (SOI) structure. According to one example embodiment, an optical nanomachining arrangement is adapted to direct an optical beam, such as a laser, at a selected portion of the flip chip SOI structure. The optical beam performs device edits to modify the circuitry contained in the SOI selected portion without necessarily damaging surrounding circuitry. The ability to make such device edits is advantageous for various applications, such as in dies of complex, circuitry containing multiple stacked layers of components, and for dies having densely packed circuitry.

Abstract: The ability to monitor virtually any portion of semiconductor device is enhanced via a grid formed for analyzing circuitry in the semiconductor device. According to an example embodiment of the present invention, a grid having a plurality of narrow probe points is formed extending over target circuitry in a semiconductor device. The grid is accessed and used for monitoring various target circuitry within the device by accessing the part of the grid that corresponds to the portion of the target circuitry to which access is desired.

Abstract: According to one aspect of the disclosure, a method for detecting a degree of substrate damage in an integrated circuit die is provided. In one example embodiment, the back side of the die is thinned and an examination region is exposed. An electron beam is used to scan the region, and backscattered electrons are detected in response. The detected backscattered electrons are used to provide an electron channeling pattern for the scanned region. The electron channeling pattern is then compared to a reference pattern and used to determine a degree of substrate damage.

Abstract: Analysis of a semiconductor die having silicon-on-insulator (SOI) structure is enhanced by accessing the circuitry within the die from the back side without necessarily breaching the insulator layer of the SOI structure. According to an example embodiment of the present invention, a semiconductor die having a SOI structure and a backside opposite circuitry in a circuit side is analyzed. An atomic force microscope is scanned across a thinned portion of the back side. The microscope responds to an electrical characteristic, such as a logic state, coupled from circuitry via the insulator portion of the die over which the microscope is being scanned. The response of the microscope to the die is detected and used to detect an electrical characteristic of the die.