Abstract: Some embodiments include apparatus and methods using an input node, an analog to digital converter (ADC) including an input coupled to the input node, a first feedforward equalizer (FFE) including an input coupled to an output of the ADC, a second FFE including an input coupled to the output of the ADC, and a decision feedback equalizer (DFE) including a first input, a second input, and an output, the first input coupled to an output of the first FFE, and the second input coupled to an output of the second FFE.

Abstract: Systems and methods of interconnecting devices may include an input/output (IO) interface having one or more device-side data lanes and transceiver logic to receive a bandwidth configuration command. The transceiver logic may also configure a transmit bandwidth of the one or more device-side data lanes based on the bandwidth configuration command. Additionally, the transceiver logic can configure a receive bandwidth of the one or more device-side data lanes based on the bandwidth configuration command.

Abstract: Methods and systems may include an input/output (IO) interface that has an integrated buffer, a housing and a substrate disposed within the housing. The substrate may include a first side, a second side and a connection edge. The integrated buffer can be coupled to at least one of the first side and the second side of the substrate. A plurality of rows of contacts may be coupled to the first side of the substrate. Each row of contacts can be stacked substantially parallel to the connection edge. The substrate may have power outputs coupled thereto and the integrated buffer can include a voltage regulator that has a supply output coupled to the power outputs.

Abstract: Some embodiments include apparatus and methods having an input to receive an input signal, additional inputs to receive clock signals having different phases to sample the input signal, and a decision feedback equalizer (DFE) having DFE slices. The DFE slices include a number of data comparators to provide data information based on the sampling of the input signal, and a number of phase error comparators to provide phase error information associated with the sampling of the input signal. The number of phase error comparators of the DFE slices is not greater than the number of data comparators of the DFE slices.

Abstract: Embodiments of the present disclosure provide apparatuses and systems for proximity communications. The apparatus may include an integrated circuit (IC) package with a central processing unit (CPU) circuit, an input-output (I/O) circuit coupled with the CPU circuit, and a dielectric electromagnetic waveguide coupled with the I/O circuit, to enable communications between the CPU circuit and another apparatus. In another instance, the apparatus may include a plurality of coupler pads disposed on a first surface of the apparatus; and a processor electrically coupled with the coupler pads. One of the coupler pads may form capacitive coupling with one of coupler pads disposed on a second surface of another apparatus, in response to a placement of the first surface in at least partial contact with the second surface, to enable proximity data communication between the processor and the other apparatus. Other embodiments may be described and/or claimed.

Abstract: Techniques for forming high-bandwidth proximity connection between capacitively coupled plug and receptacle are described herein. A system for achieving capacitive coupling between contactless pads is described. The techniques include aligning and retaining the plug and receptacle in close proximity to one another. The techniques include cancelling crosstalk in the system based on the symmetry and orientation of differential pairs comprising signal pads. The techniques include enabling a high-bandwidth proximity transmission by filtering the transmission using a silicon buffer component.

Abstract: Some embodiments include apparatus and methods having an input to receive an input signal, additional inputs to receive clock signals having different phases to sample the input signal, and a decision feedback equalizer (DFE) having DFE slices. The DFE slices include a number of data comparators to provide data information based on the sampling of the input signal, and a number of phase error comparators to provide phase error information associated with the sampling of the input signal. The number of phase error comparators of the DFE slices is not greater than the number of data comparators of the DFE slices.

Abstract: Some embodiments include apparatus and methods having an input to receive an input signal, additional inputs to receive clock signals having different phases to sample the input signal, and a decision feedback equalizer (DFE) having DFE slices. The DFE slices include a number of data comparators to provide data information based on the sampling of the input signal, and a number of phase error comparators to provide phase error information associated with the sampling of the input signal. The number of phase error comparators of the DFE slices is not greater than the number of data comparators of the DFE slices.

Abstract: Methods and systems may include an input/output (IO) interface that has an integrated buffer, a housing and a substrate disposed within the housing. The substrate may include a first side, a second side and a connection edge. The integrated buffer can be coupled to at least one of the first side and the second side of the substrate. A plurality of rows of contacts may be coupled to the first side of the substrate. Each row of contacts can be stacked substantially parallel to the connection edge. The substrate may have power outputs coupled thereto and the integrated buffer can include a voltage regulator that has a supply output coupled to the power outputs.

Abstract: Systems and methods of interconnecting devices may include a connector assembly having a substrate, a set of input/output (IO) contacts, an antenna structure and transceiver logic. In one example, the transceiver logic may process one or more IO signals associated with the antenna structure and process one or more IO signals associated with the set of IO contacts.

Abstract: In an embodiment, the present invention includes a protocol stack having a transaction layer and a link layer. In addition a first physical (PHY) unit is coupled to the protocol stack to provide communication between a processor and a device coupled to the processor via a physical link, where the first PHY unit is of a low power communication protocol and includes a first physical unit circuit. In turn, a second PHY unit is coupled to the protocol stack to provide communication between the processor and the device via a sideband channel coupled between the multicore processor and the device separate from the physical link, where the second PHY unit includes a second physical unit circuit. Other embodiments are described and claimed.

Abstract: Techniques for forming high-bandwidth proximity connection between capacitively coupled plug and receptacle are described herein. A system for achieving capacitive coupling between contactless pads is described. The techniques include aligning and retaining the plug and receptacle in close proximity to one another. The techniques include cancelling crosstalk in the system based on the symmetry and orientation of differential pairs comprising signal pads. The techniques include enabling a high-bandwidth proximity transmission by filtering the transmission using a silicon buffer component.

Abstract: Disclosed is a scalable input/output interface that has multiple bays and includes a housing surrounding a plurality of pairs of substrates. A first substrate of the pair of substrates may have a first contact surface and a second substrate of the pair of substrates may have a second contact surface that opposes the first contact surface, wherein each substrate has a connection edge. At least one integrated buffer can be coupled to either the first side or the second side of each substrate. A plurality of rows of contacts can be coupled to the opposing surfaces of each substrate of the pair of substrates, wherein each row of contacts can be stacked substantially parallel to the connection edge. Each connection edge can also be coupled to a separate integrated buffer.

Abstract: A computing system can include an electronic device including a controller and a new form factor (NFF) receptacle. The computing system can also include a legacy-compatible adapter coupled to the NFF receptacle to couple the electronic device to a second electronic device. The second electronic device can include a legacy connector. The adapter can include a voltage converter to convert voltage signals between the NFF receptacle of the electronic device and the legacy connector of the second electronic device.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for hybrid memory. In one embodiment, a hybrid memory may include a package substrate. The hybrid memory may also include a hybrid memory buffer chip attached to the first side of the package substrate. High speed input/output (HSIO) logic supporting a HSIO interface with a processor. The hybrid memory also includes packet processing logic to support a packet processing protocol on the HSIO interface. Additionally, the hybrid memory also has one or more memory tiles that are vertically stacked on the hybrid memory buffer.

Abstract: In an embodiment, the present invention includes a protocol stack having a transaction layer and a link layer. In addition a first physical (PHY) unit is coupled to the protocol stack to provide communication between a processor and a device coupled to the processor via a physical link, where the first PHY unit is of a low power communication protocol and includes a first physical unit circuit. In turn, a second PHY unit is coupled to the protocol stack to provide communication between the processor and the device via a sideband channel coupled between the multicore processor and the device separate from the physical link, where the second PHY unit includes a second physical unit circuit. Other embodiments are described and claimed.

Abstract: Embodiments of the invention are generally directed to systems, methods, and apparatuses for hybrid memory. In one embodiment, a hybrid memory may include a package substrate. The hybrid memory may also include a hybrid memory buffer chip attached to the first side of the package substrate. High speed input/output (HSIO) logic supporting a HSIO interface with a processor. The hybrid memory also includes packet processing logic to support a packet processing protocol on the HSIO interface. Additionally, the hybrid memory also has one or more memory tiles that are vertically stacked on the hybrid memory buffer.

Abstract: In an embodiment, the present invention includes a protocol stack having a transaction layer and a link layer. In addition a first physical (PHY) unit is coupled to the protocol stack to provide communication between a processor and a device coupled to the processor via a physical link, where the first PHY unit is of a low power communication protocol and includes a first physical unit circuit. In turn, a second PHY unit is coupled to the protocol stack to provide communication between the processor and the device via a sideband channel coupled between the multicore processor and the device separate from the physical link, where the second PHY unit includes a second physical unit circuit. Other embodiments are described and claimed.

Abstract: Methods and systems may include an input/output (IO) interface that has an integrated buffer, a housing and a substrate disposed within the housing. The substrate may include a first side, a second side and a connection edge. The integrated buffer can be coupled to at least one of the first side and the second side of the substrate. A plurality of rows of contacts may be coupled to the first side of the substrate. Each row of contacts can be stacked substantially parallel to the connection edge. The substrate may have power outputs coupled thereto and the integrated buffer can include a voltage regulator that has a supply output coupled to the power outputs.

Abstract: Systems and methods of interconnecting devices may include a connector assembly having a substrate, a set of input/output (IO) contacts, an antenna structure and transceiver logic. In one example, the transceiver logic may process one or more IO signals associated with the antenna structure and process one or more IO signals associated with the set of IO contacts.