Abstract: A technique for addressing single-event latch-up (SEL) in a semiconductor device includes determining a location of a parasitic silicon-controlled rectifier (SCR) in an integrated circuit design of the semiconductor device. In this case, the parasitic SCR includes a parasitic pnp bipolar junction transistor (BJT) and a parasitic npn BJT. The technique also includes incorporating a first transistor between a first power supply node and an emitter of the parasitic pnp BJT in the integrated circuit design. The first transistor includes a first terminal coupled to the first power supply node, a second terminal coupled to the emitter of the parasitic pnp BJT, and a control terminal. The first transistor is not positioned between a base of the pnp BJT and the first power supply node. The first transistor limits current conducted by the parasitic pnp bipolar junction transistor following an SEL.

Abstract: A technique for addressing single-event latch-up (SEL) in a semiconductor device includes determining a location of a parasitic silicon-controlled rectifier (SCR) in an integrated circuit design of the semiconductor device. In this case, the parasitic SCR includes a parasitic pnp bipolar junction transistor (BJT) and a parasitic npn BJT. The technique also includes incorporating a first transistor between a first power supply node and an emitter of the parasitic pnp BJT in the integrated circuit design. The first transistor includes a first terminal coupled to the first power supply node, a second terminal coupled to the emitter of the parasitic pnp BJT, and a control terminal. The first transistor is not positioned between a base of the pnp BJT and the first power supply node. The first transistor limits current conducted by the parasitic pnp bipolar junction transistor following an SEL.

Abstract: A method and apparatus is provided for implementing a cache control system effective to eliminate many of the timing problems occurring in dynamic, high bandwidth cache control systems. In one exemplary embodiment, a dummy content addressable memory (CAM) cell is provided and is strategically placed on the chip layout farthest away from the cache word line driver circuit. The dummy output signal is a required input to a cache hit evaluation circuit such that premature cache hit outputs are eliminated. The dummy cell is designed to quickly discharge a cache match line and indicate a non-hit status when any address bit line produces a mismatch indication, especially for expanded bandwidth and dynamic systems where the address lines are more extensive and the system is synchronized to predetermined clock cycles. The cache system further operates in a prefetch mode to determine hits for next in-line requested addresses.

Abstract: A method and apparatus is provided for implementing a cache control system effective to eliminate many of the timing problems occurring in dynamic, high bandwidth cache control systems. In one exemplary embodiment, a dummy content addressable memory (CAM) cell is provided and is strategically placed on the chip layout farthest away from the cache word line driver circuit. The dummy output signal is a required input to a cache hit evaluation circuit such that premature cache hit outputs are eliminated. The dummy cell is designed to quickly discharge a cache match line and indicate a non-hit status when any address bit line produces a mismatch indication, especially for expanded bandwidth and dynamic systems where the address lines are more extensive and the system is synchronized to predetermined clock cycles. The cache system further operates in a prefetch mode to determine hits for next in-line requested addresses.

Abstract: A cache memory device having circuitry for controlling operation of a sense amplifier for accessing an array in the data processing system including a cache memory device includes circuitry for enabling the sense amplifier when there is a hit in the array as a result of a read request and disables the sense amplifier when there is a miss in the array as a result of the read request. The cache memory device may receives an address associated with the read request, and compares the address to addresses associated with entries in the array, wherein a hit results when the received address matches at least one of the addresses associated with the entries in the array, and wherein a miss results when the received address does not match at least one of the addresses associated with the entries in the array. The address associated with the read request and the addresses associated with entries in the array are effective addresses.