Abstract: An actuating mechanism for a door includes a first antenna block having a first integrated microcontroller electrically connected to a first transceiver device and a first antenna. A second antenna block having a second integrated microcontroller is electrically connected to a second transceiver device and a second antenna. A processor device is electrically connected between the first and second microcontrollers and a first switch. The first and second antennas receive a first radio frequency signal from a third, mobile transceiver device. The processor device measures a time difference of arrival (TDOA) of the first radio frequency signal. The processor device computes a direction of arrival (DOA). The DOA measurement is compared against a predefined range of DOAs. The processor device sends a control signal to the first switch to actuate the door in the event of a match.

Abstract: Methods are disclosed for electrically connecting I/O bond-pads on a chip to corresponding I/O bond-pads on a substrate. In an exemplary method a respective stud-bump is formed on each I/O bond-pad on the substrate. The stud-bumps can be made of a fusible material, or a layer of fusible material can be formed on each I/O bond-pad on the chip. The chip is flipped and placed on the stud-bumps such that the I/O bond-pads on the chip are registered with the corresponding stud-bumps on the substrate. At each stud-bump, the fusible material is caused to fuse with and electrically connect the respective stud-bump to the respective I/O bond-pad on the chip. The method can include forming under-bump metallization (UBM) on each of the I/O bond-pads on the chip before placing the chip on the stud-bumps. The resulting structures provide robust I/O connections and can be fabricated using fewer process steps and using process steps that are compatible with other processes in wafer-fabrication and chip-assembly facilities.

Abstract: A semiconductor die has an insulating material disposed in a peripheral region around the die. A blind via is formed through the gap. A conductive material is deposited in the blind via to form a conductive via. A conductive layer is formed between the conductive via and contact pad on the semiconductor die. A protective layer is formed over the front side of the semiconductor die. A portion of the insulating material and conductive via is removed from a backside of the semiconductor die opposite the front side of the semiconductor die so that a thickness of the conductive via is less than a thickness of the semiconductor wafer. The insulating material and conductive via are tapered. The wafer is singulated through the gap to separate the semiconductor die. A plurality of semiconductor die can be stacked and electrically interconnected through the conductive vias.

Abstract: A wafer level semiconductor package has a substrate and an RF module and baseband module coupled to the substrate with solder bumps. An underfill material is disposed under the RF module and baseband module. A first shielding layer is applied to a first surface of the substrate. A seed layer is deposited on the substrate and RF module and baseband module. A second shielding layer is plated over the seed layer, except over the contact pads on the substrate. The second shielding layer can be made from copper, gold, nickel, or aluminum. The first and second shielding layers substantially cover the wafer level semiconductor package to isolate the baseband module from electromagnetic interference generated by the RF module. The first and second shielding layers are grounded through the substrate.

Abstract: A flip chip lead frame package includes a die and a lead frame having a die paddle and leads, and has interconnection between the active site of the die and the die paddle. Also, methods for making the package are disclosed.

Abstract: A semiconductor wafer contains a substrate having a plurality of active devices formed thereon. An analog circuit is formed on the substrate. The analog circuit can be an inductor, metal-insulator-metal capacitor, or resistor. The inductor is made with copper. A through substrate via (TSV) is formed in the substrate. A conductive material is deposited in the TSV in electrical contact with the analog circuit. An under bump metallization layer is formed on a backside of the substrate in electrical contact with the TSV. A solder material is deposited on the UBM layer. The solder material is reflowed to form a solder bump. A wire bond is formed on a top surface of the substrate. A redistribution layer is formed between the TSV and UBM. The analog circuit electrically connects through the TSV to the solder bump on the back side of the substrate.

Abstract: A die attach process employs a temperature gradient lead free soft solder metal sheet or thin film as the die attach material. The sheet or thin film is formed to a uniform thickness and has a heat vaporizable polymer adhesive layer on one surface, by which the thin film is laminated onto the back metal of the silicon wafer. The thin film is lead-free and composed of acceptably non-toxic materials. The thin film remains semi-molten (that is, not flowable) in reflow temperatures in the range about 260° C. to 280° C. The polymer adhesive layer is effectively vaporized at the high reflow temperatures during the die mount.

Abstract: A semiconductor package includes a leadframe having first and second level downset lead extensions, a quad flat nonleaded package (QFN) attached to the first level downset lead extension, and a flip chip die attached to the second level downset lead extension. Another embodiment of a semiconductor package includes a leadframe having a lead, a first quad flat nonleaded package (QFN) connected to the lead, and a second quad flat nonleaded package invertly connected to a top surface of the first quad flat nonleaded package, wherein the second quad flat nonleaded package is wirebonded to the lead. A third embodiment of a semiconductor package includes a leadframe having a lead with a first level downset lead extension, a quad flat nonleaded package (QFN) connected to the first level downset lead extension, and a first wirebondable die attached to a top or bottom surface of the quad flat nonleaded package.

Abstract: A semiconductor device is manufactured by, first, providing a wafer, designated with a saw street guide, and having a bond pad formed on an active surface of the wafer. The wafer is taped with a dicing tape. The wafer is singulated along the saw street guide into a plurality of dies having a plurality of gaps between each of the plurality of dies. The dicing tape is stretched to expand the plurality of gaps to a predetermined distance. An organic material is deposited into each of the plurality of gaps. A top surface of the organic material is substantially coplanar with a top surface of a first die of the plurality of dies. A redistribution layer is patterned over a portion of the organic material. An under bump metallization (UBM) is deposited over the organic material in electrical communication, through the redistribution layer, with the bond pad.

Abstract: A coil structure for a filter device includes a first metallization deposited over a substrate and oriented in a first coil. The first coil extends horizontally across the substrate while maintaining a substantially flat vertical profile. A second metallization is deposited over the substrate and oriented in a second coil. The second coil is magnetically coupled to the first coil. A portion of the second coil is oriented interiorly of the first coil. A third metallization is deposited over the substrate and oriented in a third coil. The third coil is magnetically coupled to the first and second coils. A portion of the third coil is oriented interiorly of the second coil.

Abstract: A solder bump is formed on a high-topography, electroplated copper pad integrating a first and second passivation layer. A sacrifice layer is deposited over the second passivation layer. The sacrifice layer is lithographically patterned. A via is etched in the sacrifice layer. A solder bump is formed in the via. A portion of the sacrifice layer is removed using the solder bump as a mask. A semiconductor device includes a substrate, an input/output (I/O) pad disposed over the substrate, a first passivation layer disposed over a portion of the I/O pad, a first conductive layer disposed over the first passivation layer, a second passivation layer disposed over the first conductive layer, a sacrifice layer disposed over the second passivation layer, the sacrifice layer having a via, and a solder bump formed in the via, the solder bump used as a mask to remove a portion of the sacrifice layer.

Abstract: A semiconductor spacer structure comprises in order a backgrinding tape layer, a spacer adhesive layer, a semiconductor spacer layer, an optional second spacer adhesive layer, a dicing tape layer. In a first method a spacer wafer having first and second sides, a backgrinding tape layer and a spacer adhesive layer between the first side and the backgrinding tape layer, is obtained. The second side is background and secured to a dicing tape. The backgrinding tape is removed and the resulting structure is diced to create spacer/adhesive die structures. A second method backgrinds the second side with the backgrinding tape layer at the first side. A protective cover layer is secured to the second side with a spacer adhesive layer therebetween. The backgrinding tape layer is removed and the remaining structure is secured to a dicing tape with the protective cover layer exposed. The protective cover layer is removed and the resulting structure is diced thereby creating spacer/adhesive die structures.

Abstract: A support for a body of a stringed instrument includes a brace structure having a plurality of legs radially disposed about a central body. The brace structure has a substantially flat first surface. A portion of the plurality of legs conforms to a soundhole opening which is integrated into the body of the stringed instrument. A brace for a body of a guitar includes a unitary structure adapted to mount to a soundboard of the guitar. The unitary structure has a plurality of arms radially disposed about a central body. A method of assembling a guitar includes mounting a brace structure to a soundboard of the guitar. Again, the brace structure has a plurality of legs radially disposed about a central body.

Abstract: An electronic module has an enclosure which is mechanically and electrically compatible with a plurality of receiving devices such as amplifiers, computers, mixer consoles, and musical instruments. The module has a programmable control panel and display on the enclosure and an electronic circuit disposed within the enclosure and receiving user commands from the control panel and displaying configuration information on the display. The electronic circuit performs a variety of functions for each of the receiving devices by way of a digital signal processor, synthesizer for generating a programmable audio signal in response to a data stream, storage device for storing musical information in a digital format, and playback device for retrieval and playback of the stored musical information. An audio output is coupled for transferring the programmable audio signal to or from the receiving device.

Abstract: A computer system models customer response using observable data. The observable data includes transaction, product, price, and promotion. The computer system receives data observable from customer responses. A set of factors including customer traffic within a store, selecting a product, and quantity of selected product is defined as expected values, each in terms of a set of parameters related to customer buying decision. A likelihood function is defined for each of the set of factors. The parameters are solved using the observable data and associated likelihood function. The customer response model is time series of unit sales defined by a product combination of the expected value of customer traffic and the expected value of selecting a product and the expected value of quantity of selected product. A linear relationship is given between different products which includes a constant of proportionality that determines affinity and cannibalization relationships between the products.

Abstract: A lighting assembly comprises a light fixture. The light fixture includes a trim formed by a stamping or die casting process. The trim has thermally conductive properties and includes a flange around a perimeter of the trim. The light fixture includes a light source mounted to a central portion of a front surface of the trim, and a heatsink formed by an extrusion or die casting process. The heatsink has thermally conductive properties and is mounted to a back surface of the trim. The light fixture includes an attachment mechanism connected to the light fixture. A recessed can housing mounted to a surface may be provided. The light fixture may be mounted to the recessed can housing by inserting the heatsink into the recessed can housing and engaging the attachment mechanism to an interior portion of the recessed can housing to brace the flange against the surface.

Abstract: A semiconductor package includes a leadframe. An upper lead is disposed above the leadframe. A first die is attached to a lower surface of the upper lead to provide electrical conductivity from the first die to the upper lead. A second die is attached to the first die. A method of manufacturing a semiconductor package includes providing a leadframe having an upper lead, lower lead, and an elevated die paddle. A first die, attached to a plurality of dies in a wafer form, is attached to a second die. The first die is singulated from the plurality of dies. The first and second dies are attached to the elevated die paddle structure. The first die is wire bonded to the lower lead. An encapsulant is formed over the first and second dies. The elevated die paddle is removed to expose a surface of the upper lead and second die.

Abstract: A semiconductor device has an adhesive layer depositing over a temporary carrier. A plurality of fiduciary patterns is formed over the adhesive layer. A repassivation layer is formed over semiconductor die. The repassivation layer may be a plurality of discrete regions. Alignment slots are formed in the repassivation layer. The fiducial patterns and alignment slots have slanted sidewalls. Leading with the repassivation layer, the semiconductor die is placed onto the carrier so that the alignment slots envelope and lock to the fiducial patterns. Alternatively, a die without the repassivation layer is placed between the fiducial patterns. An encapsulant is deposited over the semiconductor die while the die remain locked to the fiducial patterns. The carrier, adhesive layer, and fiducial patterns are removed after depositing the encapsulant. An interconnect structure is formed over the repassivation layer to electrically connect to contact pads on the semiconductor die.

Abstract: A semiconductor device is made by creating a gap between semiconductor die on a wafer. An insulating material is deposited in the gap. A first portion of the insulating material is removed from a first side of the semiconductor wafer to form a first notch. The first notch is less than a thickness of the semiconductor die. A conductive material is deposited into the first notch to form a first portion of the conductive via within the gap. A second portion of the insulating material is removed from a second side of the semiconductor wafer to form a second notch. The second notch extends through the insulating material to the first notch. A conductive material is deposited into the second notch to form a second portion of the conductive via within the gap. The semiconductor wafer is singulated through the gap to separate the semiconductor die.

Abstract: A flip chip style semiconductor package has a substrate with a plurality of active devices formed thereon. A contact pad is formed on the substrate. An under bump metallization (UBM) layer is in electrical contact with the contact pad. A passivation layer is formed over the substrate. In one case, the UBM layer is disposed above the passivation layer. Alternatively, the passivation layer is disposed above the UBM layer. A portion of the passivation layer is removed to create a passivation island. The passivation island is centered with respect to the contact pad with its top surface devoid of the UBM layer. A solder bump is formed over the passivation island in electrical contact with the UBM layer. The passivation island forms a void in the solder bump for stress relief. The UBM layer may include a redistribution layer such that the passivation island is offset from the contact pad.