Abstract: A multi-processor computer architecture incorporating distributed multi-ported common memory modules wherein each of the memory modules comprises a control block functioning as a cross-bar router in conjunction with one or more associated memory banks or other data storage devices. Each memory module has multiple I/O ports and the ability to relay requests to other memory modules if the desired memory location is not found on the first module. A computer system in accordance with the invention may comprise memory module cards along with processor cards interconnected using a baseboard or backplane having a toroidal interconnect architecture between the cards.

Abstract: A multi-processor computer architecture incorporating distributed multi-ported common memory modules wherein each of the memory modules comprises a control block functioning as a cross-bar router in conjunction with one or more associated memory banks or other data storage devices. Each memory module has multiple I/O ports and the ability to relay requests to other memory modules if the desired memory location is not found on the first module. A computer system in accordance with the invention may comprise memory module cards along with processor cards interconnected using a baseboard or backplane having a toroidal interconnect architecture between the cards.

Abstract: This invention provides a method, system, and apparatus for generating and manipulating the structure of user interface control hierarchies. When a web page is requested from a server by client software an initial control hierarchy configuration is generated. Upon successive requests by the client to the server, the structure of the web control hierarchy generated for the given web page may be altered, as prescribed by the specifications. The nature of those alterations can include the addition or replacement of web control sub-structures. This invention can be utilized to manipulate dynamic control hierarchies generated within a statically-generated hierarchy.

Abstract: This invention provides a method, system, and apparatus for generating and manipulating the structure of user interface control hierarchies, in response to user interaction or other events within the life cycle for a given control hierarchy. Within the context of an operation where a web page is requested from a server by client software operating upon a user's computer with an active interface to the internet, or an intranet, an initial control hierarchy configuration is generated, as established by a developer utilizing this invention. Upon successive requests by the client to the server, the structure of the web control hierarchy generated for the given web page may be altered, as prescribed by the development specifications for the application, and implemented by the developer utilizing this invention.

Abstract: A heterogeneous computing system comprising a switch/network adapter port interface utilizing load-reduced dual in-line memory modules (LR-DIMMs) incorporating isolation memory buffers. In a particular embodiment of the present invention the computer system comprises at least one dense logic device and a controller coupling it to a memory bus. A plurality of memory slots are coupled to the memory bus and an adaptor port is associated with some number of the plurality of memory slots, each of the adapter ports including associated memory resources. A direct execution logic element is coupled to at least one of the adapter ports. The memory resources are selectively accessible by the at least one dense logic device and the direct execution logic element.

Abstract: An enhanced switch/network adapter port incorporating shared memory resources (“SNAPM™”) selectively accessible by a direct execution logic element and one or more dense logic devices in a fully buffered dual in-line memory module (“FB-DIMM”) format for clustered computing systems employing direct execution logic such as multi-adaptive processor elements (“MAP®”, all trademarks of SRC Computers, Inc.). Functionally, the SNAPM modules incorporate and properly allocate memory resources so that the memory appears to the associated dense logic device(s) (e.g. a microprocessor) to be functionally like any other system memory such that no time penalties are incurred when accessing it.

Abstract: A switch/network adapter port (“SNAP™”) in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format for clustered computers employing multi-adaptive processor (“MAP®”, both trademarks of SRC Computers, Inc.) elements for use with interleaved memory controllers. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format adapter port coupled to a reconfigurable processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips. The field programmable gate array (“FPGA”) based processing elements have the capability to alter data passing through it to and from an external interconnect fabric or device.

Abstract: A compact system can use modular components to enhance the isolation or quality of signals that an antenna array produces. The system can comprise an array of input coupler modules and an array of output coupler modules respectively on the input and output sides of a signal routing device. Each input coupler module can receive a signal from a specific element in the antenna array and can divide or split that received signal into a multiple signal components, such as seven. The signal routing device can route each of those signal components to a different output coupler module in the array of output coupler modules. Thus, each output coupler module can receive and combine multiple signal components, such as seven, from different input coupler modules. The signal routing device can include a readily manufacturable phase trimming section to compensate for phase mismatches.

Abstract: An enhanced switch/network adapter port (“SNAP™”) including collocated shared memory resources (“SNAPM™”) in a dual in-line memory module (“DIMM”) or any other memory module format for clustered computing systems employing direct execution logic such as multi-adaptive processor elements (“MAP®”, all trademarks of SRC Computers, Inc.). Functionally, the SNAPM modules incorporate and properly allocate memory resources so that the memory appears to the associated dense logic device(s) (e.g. a microprocessor) to be functionally like any other system memory such that no time penalties are incurred when accessing it. Through the use of a programmable access coordination mechanism, the control of this memory can be handed off to the SNAPM memory controller and, once in control, the controller can move data between the shared memory resources and the computer network such that the transfer is performed at the maximum rate that the memory devices themselves can sustain.

Abstract: A switch/network adapter port (“SNAP”) for clustered computers employing multi-adaptive processor (“MAP™”, a trademark of SRC Computers, Inc.) elements in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format to significantly enhance data transfer rates over that otherwise available through use of the standard peripheral component interconnect (“PCI”) bus. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips.

Abstract: A switch/network adapter port (“SNAP”) for clustered computers employing multi-adaptive processor (“MAP™”, a trademark of SRC Computers, Inc.) elements in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format to significantly enhance data transfer rates over that otherwise available through use of the standard peripheral component interconnect (“PCI”) bus. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips.

Abstract: An enhanced switch/network adapter port incorporating shared memory resources (“SNAPM™”) selectively accessible by a direct execution logic element and one or more dense logic devices in a fully buffered dual in-line memory module (“FB-DIMM”) format for clustered computing systems employing direct execution logic such as multi-adaptive processor elements (“MAP®”, all trademarks of SRC Computers, Inc.). Functionally, the SNAPM modules incorporate and properly allocate memory resources so that the memory appears to the associated dense logic device(s) (e.g. a microprocessor) to be functionally like any other system memory such that no time penalties are incurred when accessing it.

Abstract: A switch/network adapter port (“SNAP™”) in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format for clustered computers employing multi-adaptive processor (“MAP®”, both trademarks of SRC Computers, Inc.) elements for use with interleaved memory controllers. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format adapter port coupled to a reconfigurable processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips. The field programmable gate array (“FPGA”) based processing elements have the capability to alter data passing through it to and from an external interconnect fabric or device.

Abstract: A logic device comprising reconfigurable core logic for use in conjunction with microprocessor-based computer systems which may be implemented as fully reconfigurable circuitry or a combination of reconfigurable logic and fixed logic sections. The core logic may contain parameterized functions that are selectable dynamically or during a manufacturing process and can allow for the dynamic, or predetermined, reallocation of external bandwidth between two or more ports. The fully reconfigurable circuitry, or a combination of reconfigurable and fixed logic, may be co-fabricated on a single die or formed by integrated circuit die stacking techniques. At least portions of the reconfigurable logic circuitry may be configured to function as one or more direct execution logic (DEL) reconfigurable processing elements that may function as effective peers with the associated microprocessor(s) in terms of accessing computing system resources.

Abstract: A computer system architecture and memory controller for close-coupling within a hybrid computing system using an adaptive processor interface port (“APIP”) added to, or in conjunction with, the memory and I/O controller chip of the core logic. Memory accesses to and from this port, as well as the main microprocessor bus, are then arbitrated by the memory control circuitry forming a portion of the controller chip. In this fashion, both the microprocessors and the adaptive processors of the hybrid computing system exhibit equal memory bandwidth and latency. In addition, because it is a separate electrical port from the microprocessor bus, the APIP is not required to comply with, and participate in, all FSB protocol. This results in reduced protocol overhead which results higher yielded payload on the interface.

Abstract: A computing system having at least one microprocessor and a memory subsystem coupled to the at least one microprocessor. A memory controller is coupled to manage memory transactions between the memory subsystem and the at least one microprocessor. At least one arbitration port is coupled to the memory controller and configured to receive an external arbitration signal.

Abstract: A switch/network adapter port (“SNAP™”) in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format for clustered computers employing multi-adaptive processor (“MAP®”, both trademarks of SRC Computers, Inc.) elements for use with interleaved memory controllers. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format adapter port coupled to a reconfigurable processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips. The field programmable gate array (“FPGA”) based processing elements have the capability to alter data passing through it to and from an external interconnect fabric or device.

Abstract: A computing system having at least one microprocessor and a memory subsystem coupled to the at least one microprocessor. A memory controller is coupled to manage memory transactions between the memory subsystem and the at least one microprocessor. At least one arbitration port is coupled to the memory controller and configured to receive an external arbitration signal.

Abstract: A switch/network adapter port (“SNAP”) for clustered computers employing multi-adaptive processor (“MAP™”, a trademark of SRC Computers, Inc.) elements in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format to significantly enhance data transfer rates over that otherwise available through use of the standard peripheral component interconnect (“PCI”) bus. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips.

Abstract: A switch/network adapter port (“SNAP™”) in a dual in-line memory module (“DIMM”) or Rambus™ in-line memory module (“RIMM”) format for clustered computers employing multi-adaptive processor (“MAP® ”, both trademarks of SRC Computers, Inc.) elements for use with interleaved memory controllers. Particularly disclosed is a microprocessor based computer system utilizing either a DIMM or RIMM physical format adapter port coupled to a reconfigurable processor element for the purpose of implementing a connection to an external switch, network, or other device. In a particular embodiment, connections may be provided to either the PCI, accelerated graphics port (“AGP”) or system maintenance (“SM”) bus for purposes of passing control information to the host microprocessor or other control chips. The field programmable gate array (“FPGA”) based processing elements have the capability to alter data passing through it to and from an external interconnect fabric or device.