Abstract: A multi-chip package including a carrier, a first chip, a second chip and a first conductive layer is provided. The first chip is disposed on the carrier and is electrically connected to the carrier through at least one first wire. The second chip is disposed on the first chip and is electrically connected to the first chip through at least one second wire. The first conductive layer is disposed on the second chip and is electrically connected to the first chip or the second chip through at least one third wire. The first conductive layer is electrically connected to the carrier through the at least one fourth wire.

Abstract: A multi-chip package including a carrier, a first chip, a second chip and a first conductive layer is provided. The first chip is disposed on the carrier and is electrically connected to the carrier through at least one first wire. The second chip is disposed on the first chip and is electrically connected to the first chip through at least one second wire. The first conductive layer is disposed on the second chip and is electrically connected to the first chip or the second chip through at least one third wire. The first conductive layer is electrically connected to the carrier through the at least one fourth wire.

Abstract: An electronic package with a passive component includes a circuit carrier, at least a passive component and an anisotropic conductive layer. The circuit carrier has at least a passive-component-pad set including multiple pads. The passive component has multiple electrodes placed over the corresponding pads of the passive-component-pad set. The anisotropic conductive layer is deposited between the electrodes and the pads.

Abstract: A stack chip package structure is provided. One principal feature of the structure is the formation of a few peripheral surfaces (e.g. ladder or lead-angle surfaces) at the bottom peripheral sections of a stack structure. When the stack structure is attached to a surface of a die through an adhesive layer, the thickness of the adhesive layer under a peripheral section of the stack structure is greater than a central region. Therefore, as the chip package is subjected to a thermal stress test, the adhesive layer under the peripheral sections of the stack structure is able to provide some buffering against thermal stress so that the stress concentration around the stack structure is reduced. Consequently, damages of the die surface due to stress are prevented and the average working life of the chip package is extended.

Abstract: A stack chip package structure is provided. One principal feature of the structure is the formation of a few peripheral surfaces (e.g. ladder or lead-angle surfaces) at the bottom peripheral sections of a stack structure. When the stack structure is attached to a surface of a die through an adhesive layer, the thickness of the adhesive layer under a peripheral section of the stack structure is greater than a central region. Therefore, as the chip package is subjected to a thermal stress test, the adhesive layer under the peripheral sections of the stack structure is able to provide some buffering against thermal stress so that the stress concentration around the stack structure is reduced. Consequently, damages of the die surface due to stress are prevented and the average working life of the chip package is extended.