Abstract: An architecture of hierarchical interconnect scheme for field programmable gate arrays (FPGAs).

Abstract: An integrated circuit including a programmable logic array with a plurality of logic cells and programmable interconnections to receive input signals and to perform logical functions to transmit output signals. The integrated circuit may also include megacells comprising a plurality of functional blocks receiving inputs and transmitting outputs. The integrated circuit may also include a programmable interconnections subsystem to cascade the megacells. The megacells are coupled to the programmable logic array.

Abstract: In one embodiment, the integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: A scalable non-blocking switching network (SN) having switches and intermediate (stages of) conductors that are used to connect a first plurality of conductors to other multiple sets of conductors in a generally unrestricted fashion within respective interconnect resources constraints. The SN can be applied in a wide range of applications, in tandem or hierarchically, to provide a large switch network used in network, routers, and programmable logic circuits. The SN is used to connect a first set of conductors, through the SN, to multiple sets of conductors in a given logic circuit hierarchy whereby the conductors in each of the multiple sets are equivalent or exchangeable, which in term, by construction, makes the first set of conductors equivalent when used in the next level of circuit hierarchy. The SN is scalable for large sized sets of conductors and can be used hierarchically to enable programmable interconnections among large sized circuits.

Abstract: In one embodiment, an integrated circuit has an L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors and (L+2) levels of conductors for L at least equal to one. An (i?1)-th level of conductors comprising Ii?1 number of conductors selectively couple to the i-th level of conductors comprising Ii number of conductors which comprise of D[i] sets of conductors in the L-PSN, where i is selected from [1:L+1], through ((Ii?1×D[i])+Ii×Q) number of switches where each conductor of the Ii?1 number of conductors selectively couples to at least (D[i]+Q) number of conductors of the Ii number of conductors, at least one conductor from each of the D[i] sets of conductors, for Q at least equal to one and D[i] greater than one. The integrated circuit can be used in various electronic devices.

Abstract: An integrated circuit including a programmable logic array with a plurality of logic cells and programmable interconnections to receive input signals and to perform logical functions to transmit output signals. The integrated circuit may also include megacells comprising a plurality of functional blocks receiving inputs and transmitting outputs. The integrated circuit may also include a programmable interconnections subsystem to cascade the megacells. The megacells are coupled to the programmable logic array.

Abstract: A scalable non-blocking switching network (SN) having switches and intermediate (stages of) conductors that are used to connect a first plurality of conductors to other multiple sets of conductors in a generally unrestricted fashion within respective interconnect resources constraints. The SN can be applied in a wide range of applications, in tandem or hierarchically, to provide a large switch network used in network, routers, and programmable logic circuits. The SN is used to connect a first set of conductors, through the SN, to multiple sets of conductors in a given logic circuit hierarchy whereby the conductors in each of the multiple sets are equivalent or exchangeable, which in term, by construction, makes the first set of conductors equivalent when used in the next level of circuit hierarchy. The SN is scalable for large sized sets of conductors and can be used hierarchically to enable programmable interconnections among large sized circuits.

Abstract: In one embodiment, an integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: A scalable non-blocking switching network (SN) having switches and intermediate (stages of) conductors that are used to connect a first plurality of conductors to other multiple sets of conductors in a generally unrestricted fashion within respective interconnect resources constraints. The SN can be applied in a wide range of applications, in tandem or hierarchically, to provide a large switch network used in network, routers, and programmable logic circuits. The SN is used to connect a first set of conductors, through the SN, to multiple sets of conductors in a given logic circuit hierarchy whereby the conductors in each of the multiple sets are equivalent or exchangeable, which in term, by construction, makes the first set of conductors equivalent when used in the next level of circuit hierarchy. The SN is scalable for large sized sets of conductors and can be used hierarchically to enable programmable interconnections among large sized circuits.

Abstract: In one embodiment, the integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: In one embodiment, an integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: In one embodiment, an integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: In one embodiment, an integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: In one embodiment, the integrated circuit has a L-level permutable switching network (L-PSN) comprising L levels of intermediate conductors. The integrated circuit can be used in electronic devices, such as switching networks, routers, and programmable logic circuits, etc.

Abstract: An architecture of hierarchical interconnect scheme for field programmable gate arrays (FPGAs). A first layer of routing network lines is used to provide connections amongst sets of block connectors where block connectors are used to provide connectability between logical cells and accessibility to the hierarchical routing network. A second layer of routing network lines provides connectability between different first layers of routing network lines. Additional layers of routing network lines are implemented to provide connectability between different prior layers of routing network lines. An additional routing layer is added when the number of cells is increased as the prior cell count in the array increases while the length of the routing lines and the number of routing lines also increases. Switching networks are used to provide connectability among same and different layers of routing network lines, each switching network composed primarily of program controlled passgates and, when needed, drivers.

Abstract: An architecture of hierarchical interconnect scheme for field programmable gate arrays (FPGAs). A first layer of routing network lines is used to provide connections amongst sets of block connectors where block connectors are used to provide connectability between logical cells and accessibility to the hierarchical routing network. A second layer of routing network lines provides connectability between different first layers of routing network lines. Additional layers of routing network lines are implemented to provide connectability between different prior layers of routing network lines. An additional routing layer is added when the number of cells is increased as the prior cell count in the array increases while the length of the routing lines and the number of routing lines also increases. Switching networks are used to provide connectability among same and different layers of routing network lines, each switching network composed primarily of program controlled passgates and, when needed, drivers.

Abstract: A scalable non-blocking switching network (SN) having switches and intermediate (stages of) conductors that are used to connect a first plurality of conductors to other multiple sets of conductors in a generally unrestricted fashion within respective interconnect resources constraints. The SN can be applied in a wide range of applications, in tandem or hierarchically, to provide a large switch network used in network, routers, and programmable logic circuits. The SN is used to connect a first set of conductors, through the SN, to multiple sets of conductors in a given logic circuit hierarchy whereby the conductors in each of the multiple sets are equivalent or exchangeable, which in term, by construction, makes the first set of conductors equivalent when used in the next level of circuit hierarchy. The SN is scalable for large sized sets of conductors and can be used hierarchically to enable programmable interconnections among large sized circuits.

Abstract: An integrated circuit including a programmable logic array with a plurality of logic cells and programmable interconnections to receive input signals and to perform logical functions to transmit output signals. The integrated circuit may also include megacells comprising a plurality of functional blocks receiving inputs and transmitting outputs. The integrated circuit may also include a programmable interconnections subsystem to cascade the megacells. The megacells are coupled to the programmable logic array.

Abstract: A scalable non-blocking switching network (SN) having switches and intermediate (stages of) conductors that are used to connect a first plurality of conductors to other multiple sets of conductors in a generally unrestricted fashion within respective interconnect resources constraints. The SN can be applied in a wide range of applications, in tandem or hierarchically, to provide a large switch network used in network, routers, and programmable logic circuits. The SN is used to connect a first set of conductors, through the SN, to multiple sets of conductors in a given logic circuit hierarchy whereby the conductors in each of the multiple sets are equivalent or exchangeable, which in term, by construction, makes the first set of conductors equivalent when used in the next level of circuit hierarchy. The SN is scalable for large sized sets of conductors and can be used hierarchically to enable programmable interconnections among large sized circuits.

Abstract: An interconnection fabric using switching networks hierarchically to allow interconnections of large number of a first plurality of conductors to a large number of k plurality of conductors is described. The resulting interconnection fabric can be used in switching networks, routers and programmable logic circuits.