Abstract: A vertical type light emitting diode die and a method for fabricating the same is disclosed. A growth substrate is provided and an epitaxial layer is formed on the growth substrate. A metallic combined substrate is connected to the epitaxial layer. Then, the growth substrate is removed. Electrode units are formed on the top surface of the epitaxial layer. The epitaxial layer is divided into epitaxial dies according to the number of the plurality of electrode units. Each vertical type light emitting diode die formed in the abovementioned way includes the metallic combined substrate having a first metal layer and second metal layers. The first metal layer is combined with the two second metal layers by cutting, vacuum heating, and polishing, so as to enable the metallic combined substrate to have a high coefficient of thermal conductivity, a low coefficient of thermal expansion, and initial magnetic permeability.

Abstract: A chip reliability testing method includes mounting a first test chip on a test board, wherein the first test chip comprises a silicon device having a plurality of metallization layers configured to establish a plurality of test circuits, a conductive redistribution layer contacting at least one of the plurality of metallization layers, and contact pads on exposed portions of the conductive redistribution layer. The mounting includes bonding the contact pads of the first test chip to corresponding contact pads of the test board. The method further includes applying a test voltage to a first contact pad connected to a first test circuit of the plurality of test circuits and, while maintaining the test voltage, subjecting the first test circuit to a reliability test. The method further includes monitoring an output voltage at a second contact pad connected to the first test circuit during a test period during the reliability test.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: Disclosed is a chip reliability testing method that includes mounting a test chip on a test board whereby each test circuit of the test chip is connected to a different pair of input and output terminals. The reliability test can include applying a test voltage to a first (input) bump and measuring an output voltage on a second (output) bump connected to the same test circuit. The first and second bumps are, in turn, electrically connected to each other through a series of conductive materials to define the test circuit. The conductive materials include first and second contact pads under the first and second bumps with the contact pads, in turn, being connected to a conductive substrate or redistribution layer. The conductive substrate or redistribution layer is, in turn, connected to first and second conductive vias that each provide a connection to one or more of a series of conductive layers that are arranged under the conductive substrate or redistribution layer and over a silicon device.

Abstract: A chip includes a first group of dummy bumps disposed at a top surface of the chip in a first corner of the chip, a second group of dummy bumps disposed at the top surface of the chip in a second corner of the chip, and active bump connectors disposed at the top surface of the chip. The chip also includes an outer seal ring disposed around a periphery of the chip, a first seal ring arrangement disposed around the first group of dummy bumps, and a second seal ring arrangement disposed around the second group of dummy bumps. The first seal ring arrangement and second seal ring arrangement are disposed in dielectric layers underlying the first and second groups of dummy bumps.

Abstract: Interconnect structures, packaged semiconductor devices, and methods of packaging semiconductor devices are disclosed. In some embodiments, an interconnect structure includes a polymer material and a post passivation interconnect (PPI) pad disposed over the polymer material. A PPI line is disposed within an opening in the polymer material, the PPI line being coupled to the PPI pad.

Abstract: Methods and apparatus are disclosed for manufacturing metal contacts under ground-up contact pads within a device. A device may comprise a bottom metal layer with a bottom metal contact, a top metal layer with a top metal contact, and a plurality of middle metal layers. Any given metal layer of the plurality of middle metal layers comprises a metal contact, the metal contact is substantially vertically below the top metal contact, substantially vertically above the bottom metal contact, and substantially vertically above a metal contact in any metal layer that is below the given metal layer. The metal contacts may be of various and different shapes. All the metal contacts in the plurality of middle metal layers and the bottom metal contact may be smaller than the top metal contact, therefore occupying less area and saving more area for other functions such as device routing.

Abstract: Interconnect structures, packaged semiconductor devices, and methods of packaging semiconductor devices are disclosed. In some embodiments, an interconnect structure includes a polymer material and a post passivation interconnect (PPI) pad disposed over the polymer material. A PPI line is disposed within an opening in the polymer material, the PPI line being coupled to the PPI pad.

Abstract: A vertical type light emitting diode die and a method for fabricating the same is disclosed. A growth substrate is provided and an epitaxial layer is formed on the growth substrate. A metallic combined substrate is connected to the epitaxial layer. Then, the growth substrate is removed. Electrode units are formed on the top surface of the epitaxial layer. The epitaxial layer is divided into epitaxial dies according to the number of the plurality of electrode units. Each vertical type light emitting diode die formed in the abovementioned way includes the metallic combined substrate having a first metal layer and second metal layers. The first metal layer is combined with the two second metal layers by cutting, vacuum heating, and polishing, so as to enable the metallic combined substrate to have a high coefficient of thermal conductivity, a low coefficient of thermal expansion, and initial magnetic permeability.

Abstract: A vertical type light emitting diode die and a method for fabricating the same is disclosed. A growth substrate is provided and an epitaxial layer is formed on the growth substrate. A metallic combined substrate is connected to the epitaxial layer. Then, the growth substrate is removed. Electrode units are formed on the top surface of the epitaxial layer. The epitaxial layer is divided into epitaxial dies according to the number of the plurality of electrode units. Each vertical type light emitting diode die formed in the abovementioned way includes the metallic combined substrate having a first metal layer and second metal layers. The first metal layer is combined with the two second metal layers by cutting, vacuum heating, and polishing, so as to enable the metallic combined substrate to have a high coefficient of thermal conductivity, a low coefficient of thermal expansion, and initial magnetic permeability.

Abstract: Methods and apparatus are disclosed for manufacturing metal contacts under ground-up contact pads within a device. A device may comprise a bottom metal layer with a bottom metal contact, a top metal layer with a top metal contact, and a plurality of middle metal layers. Any given metal layer of the plurality of middle metal layers comprises a metal contact, the metal contact is substantially vertically below the top metal contact, substantially vertically above the bottom metal contact, and substantially vertically above a metal contact in any metal layer that is below the given metal layer. The metal contacts may be of various and different shapes. All the metal contacts in the plurality of middle metal layers and the bottom metal contact may be smaller than the top metal contact, therefore occupying less area and saving more area for other functions such as device routing.

Abstract: Methods and apparatuses for wafer level packaging (WLP) semiconductor devices are disclosed. A redistribution layer (RDL) is formed on a first passivation layer in contact with a conductive pad over a surface of a die. The RDL layer is on top of a first region of the first passivation layer. A second passivation layer is formed on the RDL layer with an opening to expose the RDL layer, and over the first passivation layer. An under bump metallization (UBM) layer is formed over the second passivation layer in contact with the exposed RDL layer. A second region of the first passivation layer disjoint from the first region is determined by projecting an outer periphery of a solder ball or other connector onto the surface.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: A chip includes a first group of dummy bumps disposed at a top surface of the chip in a first corner of the chip, a second group of dummy bumps disposed at the top surface of the chip in a second corner of the chip, and active bump connectors disposed at the top surface of the chip. The chip also includes an outer seal ring disposed around a periphery of the chip, a first seal ring arrangement disposed around the first group of dummy bumps, and a second seal ring arrangement disposed around the second group of dummy bumps. The first seal ring arrangement and second seal ring arrangement are disposed in dielectric layers underlying the first and second groups of dummy bumps.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: Methods and apparatus are disclosed for manufacturing metal contacts under ground-up contact pads within a device. A device may comprise a bottom metal layer with a bottom metal contact, a top metal layer with a top metal contact, and a plurality of middle metal layers. Any given metal layer of the plurality of middle metal layers comprises a metal contact, the metal contact is substantially vertically below the top metal contact, substantially vertically above the bottom metal contact, and substantially vertically above a metal contact in any metal layer that is below the given metal layer. The metal contacts may be of various and different shapes. All the metal contacts in the plurality of middle metal layers and the bottom metal contact may be smaller than the top metal contact, therefore occupying less area and saving more area for other functions such as device routing.

Abstract: A method includes forming an electrical connector over a substrate of a wafer, and molding a polymer layer, with at least a portion of the electrical connector molded in the polymer layer. A first sawing step is performed to form a trench in the polymer layer. After the first sawing step, a second sawing step is performed to saw the wafer into a plurality of dies.

Abstract: Methods and apparatus are disclosed for manufacturing metal contacts under ground-up contact pads within a device. A device may comprise a bottom metal layer with a bottom metal contact, a top metal layer with a top metal contact, and a plurality of middle metal layers. Any given metal layer of the plurality of middle metal layers comprises a metal contact, the metal contact is substantially vertically below the top metal contact, substantially vertically above the bottom metal contact, and substantially vertically above a metal contact in any metal layer that is below the given metal layer. The metal contacts may be of various and different shapes. All the metal contacts in the plurality of middle metal layers and the bottom metal contact may be smaller than the top metal contact, therefore occupying less area and saving more area for other functions such as device routing.