Abstract: The present invention is an efficient system and method for cascading optical switches in architectures that enable three dimensional multi-plane optical signal beam steering to be performed with two dimensional steering devices. A plurality of cascaded optical switches form a cascaded multi-plane optical switch fabric and direct an optical signal beam from one of the plurality of optical switches to another of the plurality of optical switches in a different plane. In addition, a multi-plane directional device directs an optical signal beam from a first optical switch stage to a second optical switch stage oriented in a different plane. Furthermore, a fixed incidence corrective device directs an optical signal beam in a shallow angle to an optical switch located in a relatively close proximity on the optical switch fabric and a optical signal beam spread correction device provides for refocusing of spreading optical signal beams and mitigation of signal loss.

Abstract: A light modulator comprises a series of ribbons divided by a series of gaps. Sequences of consecutive ribbons and gaps are grouped together to form a plurality of pixels that are configured to process a respective plurality of wavelengths. The spacing from center-line to center-line of adjacent pixels is progressively increased from a reference pixel to align component pixels with their assigned wavelengths. The widths of ribbons and gaps within a particular pixel affect the polarization dependent loss of a pixel, and affect the first order diffraction angle. Ribbon widths and gap widths within successive pixels are altered to normalize polarization dependent loss and first order diffraction angles against the values associated with a reference pixel.

Abstract: A light modulator includes elongated elements arranged parallel to each other. Each elongated element includes a light reflective planar surface with the light reflective planar surfaces configured in a first grating plane. A support structure is coupled to the elongated elements to maintain a position of the elongated elements relative to each other and to enable movement of each elongated element in a direction normal to the first grating plane. The support structure enables movement between a first modulator configuration and a second modulator configuration. In the first modulator configuration, the elongated elements act to reflect an incident light as a plane mirror. In the second modulator configuration, the elongated elements form a stepped blaze configuration along a second grating plane lying at a grating angle to the first grating plane and act to diffract the incident light into at least two diffraction orders.

Abstract: A MEMS device such as a grating light valve™ light modulator is athermalized such that the force required to deflect the movable portion of the MEMS device remains constant over a range of temperatures. In MEMS embodiments directed to a grating light valve™ light modulator, a ribbon is suspended over a substrate, and the ribbon tension is kept constant over a temperature range by adjusting the aggregate thermal coefficient of expansion of the ribbon to match the aggregate thermal coefficient of expansion of the substrate. Various opposition materials have an opposite thermal coefficient of expansion as the aluminum layer of a grating light valve™ light modulator ribbon, using the thermal coefficient of expansion of the substrate as a zero coefficient reference.

Abstract: A modulator for modulating an incident beam of light. The modulator includes a plurality of elements, each element including a first end, a second end, a first non-linear side, a second non-linear side, and a light reflective planar surface. The light reflective planar surfaces of the plurality of elements lie in one or more parallel planes. The elements are preferably arranged parallel to each other. The modulator also includes a support structure to maintain a position of each element relative to each other and to enable movement of selective ones of the plurality of elements in a direction normal to the one or more parallel planes of the plurality of elements. The plurality of elements are preferably moved between a first modulator configuration wherein the plurality of elements act to reflect the incident beam of light as a plane mirror, and a second modulator configuration wherein the plurality of elements act to diffract the incident beam of light.

Abstract: One embodiment disclosed relates to an apparatus for controlled diffraction of light. The apparatus includes a plurality of vertically movable reflective members and an arrangement of the reflective members along a grating plane. The grating plane is configured to be controllably tiltable. Another embodiment disclosed relates to a method for controlled diffraction of light. The method includes illuminating incident light upon an element, and controllably deflecting reflective members within the element to control a fraction of the incident light reflected by the element. The reflective members may be controllably deflected so as to be positioned along a tiltable grating plane.

Abstract: A light modulator includes elongated elements arranged parallel to each other. In a first diffraction mode, the light modulator operates to diffract an incident light into at least two diffraction orders. In a second diffraction mode, the light modulator operates to diffract the incident light into a single diffraction order. Each of the elongated elements comprises a blaze profile, which preferably comprises a reflective stepped profile across a width of each of the elongated elements and which produces an effective blaze at a blaze angle. Alternatively, the blaze profile comprises a reflective surface angled at the blaze angle. Each of selected ones of the elongated elements comprise a first conductive element. The elongated elements produce the first diffraction when a first electrical bias is applied between the first conductive elements and a substrate.

Abstract: The present invention cascaded optical switching system includes architectures that provide three dimensional optical signal beam steering utilizing two dimension optical signal beam steering devices. A plurality of cascaded optical switches form a cascaded multi-dimensional optical switch fabric and direct an optical signal beam from one of the plurality of optical switches to another of the plurality of optical switches in a different dimension. In one embodiment, an incidence corrective device is included in a cascaded optical switch fabric and directs an optical signal beam in a shallow angle so that it strikes the next optical switch at a corrected incidence angle. A corrected incidence angle permits an optical signal beam to be forwarded at a relatively shallow angle to an optical switch located in a relatively close proximity on the optical switch fabric. The present invention also provides for refocusing of spreading optical signal beams and mitigation of signal loss.

Abstract: The present invention is an efficient system and method for cascading optical switches. A plurality of cascaded optical switches form a cascaded optical switch fabric and direct an optical signal beam from one of the plurality of optical switches to another of the plurality of optical switches. In one embodiment of the present invention, a variable incidence corrective device is included in a cascaded optical switch fabric. The incidence corrective device directs an optical signal beam in a shallow angle so that it strikes the next optical switch at a corrected incidence angle. A corrected incidence angle permits an optical signal beam to be forwarded at a relatively shallow angle to an optical switch located in a relatively close proximity on the optical switch fabric. The present invention also provides for refocusing of spreading optical signal beams and mitigation of signal loss.

Abstract: The method of the present invention acquires delay, setup and hold values that appropriately reflect the timing characteristics of an integrated circuit represented by a cell file. A data and clock input slope pair is selected and the data setup time value is swept with respect to the clock. For each setup value a corresponding hold value is determined for functional failure. Then for each setup and hold value pair a delay value is ascertained. In one exemplary implementation optimal delay, setup and hold values are determined and utilized to facilitate higher frequency designs using the same physical cell layout library.

Abstract: A light modulator includes elongated elements and a support structure. The elongated elements are arranged in parallel. Each element includes a light reflective planar surface with the light reflective planar surfaces lying in one or more parallel planes. The support structure is coupled to the elongated elements to maintain a position of the elongated elements relative to each other and to enable movement of each elongated element between a first modulator configuration and a second modulator configuration. In the first modulator configuration, the elongated elements act to reflect an incident light as a plane mirror. In the second modulator configuration, selected groups of elements are deflected and act to diffract the incident light along one or more of a plurality of diffraction planes. The groups of elements are configured according to one of a plurality of selectable group configurations. Each group configuration corresponds to one of the plurality of diffraction planes.

Abstract: A light modulator includes elongated elements arranged parallel to each other. In a first diffraction mode, the light modulator operates to diffract an incident light into at least two diffraction orders. In a second diffraction mode, the light modulator operates to diffract the incident light into a single diffraction order. Each of the elongated elements comprises a blaze profile, which preferably comprises a reflective stepped profile across a width of each of the elongated elements and which produces an effective blaze at a blaze angle. Alternatively, the blaze profile comprises a reflective surface angled at the blaze angle. Each of selected ones of the elongated elements comprise a first conductive element. The elongated elements produce the first diffraction when a first electrical bias is applied between the first conductive elements and a substrate.

Abstract: A modulator for modulating an incident beam of light. The modulator includes a plurality of elements, each element including a first end, a second end, a first linear side, a second linear side, and a continuous or non-continuous light reflective planar surface plurality of elements are arranged parallel to each other and further wherein the light reflective planar surface of each of the plurality of elements includes a first non-linear side and a second non-linear side. The modulator also includes a support structure coupled to each end of the plurality of elements to enable movement between a first modulator configuration wherein the plurality of elements act to reflect the incident beam of light as a plane mirror, and a second modulator configuration wherein the plurality of elements act to diffract the incident beam of light.

Abstract: An apparatus for detecting wavelength change of a first light signal comprises an amplitude splitting interferometer and a detector. The amplitude splitting interferometer comprises first and second optical paths. The first optical path has a first index of refraction that varies with wavelength over a first wavelength band. The second optical path has a second index of refraction that is relatively constant over the first wavelength band. In operation the first light signal enters and exits the amplitude splitting interferometer forming interference light. The interference light couples to the detector which detects the wavelength change of the first light signal from the interference light. An interferometer comprises a first beam splitter, third and fourth optical paths, and a second beam splitter. The third optical path is optically coupled to the first beam splitter and has a third index of refraction that varies with wavelength over a second wavelength band.

Abstract: A method for determining the capacitance of an analog/mixed signal circuit, comprising the steps of (A) acquiring a capacitance at a plurality of different input slope rates, (B) verifying each acquired capacitance, (C) determining an average capacitance of said plurality of different input slope rates over a partial average range and (D) determining an accuracy of the capacitance.

Abstract: A memory resident circuit cell model for characterizing an integrated circuit cell. The present invention comprises a first aggregate value representing a best case corner and a second aggregate value representing a worst case corner. In the present embodiment, the first and second aggregate value comprise a first delay representation accounting for timing variations of the cell relative to cross-coupling within the cell and a second delay representation accounting for timing variations of the cell relative to over-the-cell-routing-coupling. The first and second aggregate value further comprise a third delay representation accounting for timing variations of the cell for pin-input-capacitance and a fourth delay representation accounting for timing variations of the cell relative to delays due to near simultaneous input switching.

Abstract: A light modulator includes elongated elements arranged parallel to each other. In a first diffraction mode, the light modulator operates to diffract an incident light into at least two diffraction orders. In a second diffraction mode, the light modulator operates to diffract the incident light into a single diffraction order. Each of the elongated elements comprises a blaze profile, which preferably comprises a reflective stepped profile across a width of each of the elongated elements and which produces an effective blaze at a blaze angle. Alternatively, the blaze profile comprises a reflective surface angled at the blaze angle. Each of selected ones of the elongated elements comprise a first conductive element. The elongated elements produce the first diffraction when a first electrical bias is applied between the first conductive elements and a substrate.

Abstract: An apparatus for detecting wavelength change of a first light signal comprises an amplitude splitting interferometer and a detector. The amplitude splitting interferometer comprises first and second optical paths. The first optical path has a first index of refraction that varies with wavelength over a first wavelength band. The second optical path has a second index of refraction that is relatively constant over the first wavelength band. In operation the first light signal enters and exits the amplitude splitting interferometer forming interference light. The interference light couples to the detector which detects the wavelength change of the first light signal from the interference light. An interferometer comprises a first beam splitter, third and fourth optical paths, and a second beam splitter. The third optical path is optically coupled to the first beam splitter and has a third index of refraction that varies with wavelength over a second wavelength band.

Abstract: A light modulator includes elongated elements arranged parallel to each other. In a first diffraction mode, the light modulator operates to diffract an incident light into at least two diffraction orders. In a second diffraction mode, the light modulator operates to diffract the incident light into a single diffraction order. Each of the elongated elements comprises a blaze profile, which preferably comprises a reflective stepped profile across a width of each of the elongated elements and which produces an effective blaze at a blaze angle. Alternatively, the blaze profile comprises a reflective surface angled at the blaze angle. Each of selected ones of the elongated elements comprise a first conductive element. The elongated elements produce the first diffraction when a first electrical bias is applied between the first conductive elements and a substrate.

Abstract: A cache memory system has a plurality of cache entries for storing memory items staged from a memory. The cache memory system locks entries so that memory items stored therein are prevented from being replaced by newly staged memory items. Entries can be locked globally whereby more than one entry is locked. Entries can also be locked locally whereby only selected ones of the entries are locked. The cache memory system can also set or clear a representation in an entry representing that such entry is not to be replaced upon being selectively activated or deactivated by an auto-lock (automatic lock) signal. The representation is memory-mapped and can be set or cleared directly by an integer unit.