Abstract: The embodiments disclose a new type of multi-function smart wristlets, in which a variety of electronic, optoelectronic, and thermal sensors are embedded. These sensors will collect data through various signals from both a person and the environment in order to perform many functions to help people improve their health; it also tells people of the environmental conditions in order for them to make the right decision about their outdoor activities. Also, this wristlet can be a sensor-key to open cars, house doors, garage doors, and so on. It also works as music player to play music in wireless headphones through Bluetooth function on the wristlet. In addition, at night it can also measure your steady heartbeat and blood flow rate along with breathing conditions through the detector sensors. This can monitor a person's health and sleeping quality. This function can also help to alert other family members through an app downloaded on family's phone if a condition appears in sleep or heart rate becomes irregular.

Abstract: The embodiments disclose a method of using a molecular self-assembly of a predetermined spherical or cylindrical block copolymer (BCP) to create a nano-scale dot array pattern, transferring the BCP pattern into a chromium (Cr) hard mask layer, and then into a substrate. The patterned substrate is chemically modified with a predetermined self-assembled monolayer (SAM) with a hydrophobic functional group to form a super-hydrophobic surface.

Abstract: The present disclosure relates to a semiconductor integrated circuit. The semiconductor integrated circuit includes a substrate, a first transistor and a first patterned conductive layer. The first transistor has a source region, a drain region in the substrate and a gate region on the substrate. The first patterned conductive layer is electrically connected to the drain region of the first transistor. The first patterned conductive layer includes a first section, a second section and a fusible device.

Abstract: A memory device is provided which comprises a memory array, a first scrambling circuit and a second scrambling circuit. The first scrambling circuit is configured to provide first scrambled data with a first scrambling pattern in response to input data. The second scrambling circuit is configured to provide second scrambled data with a second scrambling pattern in response to the first scrambled data.

Abstract: A semiconductor arrangement and a method of forming the same are described. A semiconductor arrangement includes a first layer including a first optical transceiver and a second layer including a second optical transceiver. A first serializer/deserializer (SerDes) is connected to the first optical transceiver and a second SerDes is connected to the second optical transceiver. The SerDes converts parallel data input into serial data output including a clock signal that the first transceiver transmits to the second transceiver. The semiconductor arrangement has a lower area penalty than traditional intra-layer communication arrangements that do not use optics for alignment, and mitigates alignment issues associated with conventional techniques.

Abstract: The present disclosure provides a method of fabricating a resistive memory array. In one embodiment, a method of fabricating a resistive memory array includes forming a plurality of insulators and a conductive structure on a first substrate, performing a resistor-forming process to transform the insulators into a plurality of resistors, polishing the conductive structure to expose a plurality of contact points respectively electrically connected to the resistors, providing a second substrate having a plurality of transistors and a plurality of interconnect pads, bonding respectively the interconnect pads and the contact points, and removing the first substrate from the resistors and the conductive structure.

Abstract: A semiconductor arrangement and a method of forming the same are described. A semiconductor arrangement includes a first layer including a first optical transceiver and a second layer including a second optical transceiver. A first serializer/deserializer (SerDes) is connected to the first optical transceiver and a second SerDes is connected to the second optical transceiver. The SerDes converts parallel data input into serial data output including a clock signal that the first transceiver transmits to the second transceiver. The semiconductor arrangement has a lower area penalty than traditional intra-layer communication arrangements that do not use optics for alignment, and mitigates alignment issues associated with conventional techniques.

Abstract: A trimming process for setting a reference current used in operating an MRAM module comprising an operational MRAM cell coupled to a bit line, multiple reference MRAM cells coupled to a reference bit line, and a sense amplifier coupled to the bit line and the reference bit line is disclosed in some embodiments. The process includes applying a bit line reference voltage to the reference bit line to provide a reference cell current formed by a sum of respective currents through the plurality of reference MRAM cells. The reference cell current is detected. A determination is made as to whether the detected reference cell current differs from a target reference cell current. The bit line reference voltage is varied, or a sensing ratio of the sense amplifier is varied, if it is determined that the detected reference cell current differs from the target reference cell current.

Abstract: A embodiment package includes a three dimensional integrated circuit (3D IC) with first input/output pads on a first side and second input/output pads on a second side, a first fan out structure electrically coupled to the first input/output pads on the first side of the three dimensional integrated circuit, and a second fan out structure electrically coupled to the second input/output pads on the second side of the three dimensional integrated circuit.

Abstract: A method of fabricating a resistive memory array includes forming a plurality of insulators and a conductive structure on a first substrate, performing a resistor-forming process to transform the insulators into a plurality of resistors, polishing the conductive structure to expose a plurality of contact points respectively electrically connected to the resistors, providing a second substrate having a plurality of transistors and a plurality of interconnect pads, bonding respectively the interconnect pads and the contact points, and removing the first substrate from the resistors and the conductive structure.

Abstract: A circuit that includes a current source module, a current sink module and a memory bank is disclosed. Each of the current source module, the current sink module and the memory bank is connected to the first bit/source line and the second bit/source line. The memory bank is bounded by the current source module and the current sink module. When the current source module and the current sink module receive a triggering pulse from the first bit/source line and a select signal with a first state, the current source module is activated to generate an operating current to the first bit/source line that transmits through a conducted memory cell of the memory bank and the current sink module is activated to drain the operating current from the second bit/source line.

Abstract: A embodiment package includes a three dimensional integrated circuit (3D IC) with first input/output pads on a first side and second input/output pads on a second side, a first fan out structure electrically coupled to the first input/output pads on the first side of the three dimensional integrated circuit, and a second fan out structure electrically coupled to the second input/output pads on the second side of the three dimensional integrated circuit.

Abstract: A trimming process for setting a reference current used in operating an MRAM module comprising an operational MRAM cell coupled to a bit line, multiple reference MRAM cells coupled to a reference bit line, and a sense amplifier coupled to the bit line and the reference bit line is disclosed in some embodiments. The process includes applying a bit line reference voltage to the reference bit line to provide a reference cell current formed by a sum of respective currents through the plurality of reference MRAM cells. The reference cell current is detected. A determination is made as to whether the detected reference cell current differs from a target reference cell current. The bit line reference voltage is varied, or a sensing ratio of the sense amplifier is varied, if it is determined that the detected reference cell current differs from the target reference cell current.

Abstract: Some embodiments relate to a system that includes write circuitry, read circuitry, and comparison circuitry. The write circuitry is configured to attempt to write an expected multi-bit word to a memory location in a memory device. The read circuitry is configured to read an actual multi-bit word from the memory location. The comparison circuitry is configured to compare the actual multi-bit word read from the memory location with the expected multi-bit word which was previously written to the memory location to distinguish between a number of erroneous bits in the actual multi-bit word and a number of correct bits in the actual multi-bit word. The write circuitry is further configured to re-write the number of erroneous bits to the memory location without attempting to re-write the number of correct bits to the memory location.

Abstract: A trimming process for setting a reference current used in operating an MRAM module comprising an operational MRAM cell coupled to a bit line, multiple reference MRAM cells coupled to a reference bit line, and a sense amplifier coupled to the bit line and the reference bit line is disclosed in some embodiments. The process includes applying a bit line reference voltage to the reference bit line to provide a reference cell current formed by a sum of respective currents through the plurality of reference MRAM cells. The reference cell current is detected. A determination is made as to whether the detected reference cell current differs from a target reference cell current. The bit line reference voltage is varied, or a sensing ratio of the sense amplifier is varied, if it is determined that the detected reference cell current differs from the target reference cell current.

Abstract: A stabilizing circuit is provided that is connected to a biased voltage. The stabilizing circuit is configured to inhibit a change in voltage of the biased voltage caused by a first change in voltage of one or more nodes that are connected to the biased voltage through a first parasitic capacitance. In some embodiments, the stabilizing circuit induces a voltage on the biased voltage through a second parasitic capacitance that changes from a first voltage level to a second voltage level during the first change in voltage such that a total change in parasitic voltage that is induced at the biased voltage during the first change in voltage is close to 0 V.

Abstract: A circuit that includes a current source module, a current sink module and a memory bank is disclosed. Each of the current source module, the current sink module and the memory bank is connected to the first bit/source line and the second bit/source line. The memory bank is bounded by the current source module and the current sink module. When the current source module and the current sink module receive a triggering pulse from the first bit/source line and a select signal with a first state, the current source module is activated to generate an operating current to the first bit/source line that transmits through a conducted memory cell of the memory bank and the current sink module is activated to drain the operating current from the second bit/source line.

Abstract: A low-dropout (LDO) regulator is provided. The LDO regulator comprises a first circuit operating as a closed loop control system. The first circuit is configured to control a voltage at a first node such that the voltage at the first node is substantially equal to a specified regulator output voltage. The LDO regulator comprises a second circuit operating as an open loop control system. The second circuit is configured to increase the voltage at the first node when a current flowing through a load changes from a first current to a second current. The first current is substantially equal to 0 amperes.

Abstract: Some aspects of the present disclosure relate a method. The method attempts to write an expected multi-bit word to a memory location in memory. After writing of the multi-bit word has been attempted, an actual multi-bit word is read from the memory location. The actual multi-bit word is then compared with the expected multi-bit word to identify a number of erroneous bits and a number of correct bits stored in the memory location. The number of erroneous bits is re-written to the memory location without attempting to re-write the correct bits to the memory location.

Abstract: A embodiment package includes a three dimensional integrated circuit (3D IC) with first input/output pads on a first side and second input/output pads on a second side, a first fan out structure electrically coupled to the first input/output pads on the first side of the three dimensional integrated circuit, and a second fan out structure electrically coupled to the second input/output pads on the second side of the three dimensional integrated circuit.