Abstract: Implementations of encoding techniques are disclosed. In one embodiment, an encoding system includes a codec device, a switching network, a rerouting circuit, a logic integrated circuit, and memory devices. The codec device includes a plurality of input and output (I/O) ports to transport data signals. The switching network is coupled both to the plurality of I/O ports and to a plurality of channels external to the device. The plurality of I/O ports includes at least one spare channel. The rerouting circuitry is coupled to and configured to control the switching network and the logic integrated circuit has logic circuity including command and decode queueing circuitry, redundancy circuits, and error correction circuitry. The memory devices do include any circuitry included in the logic circuitry. Other systems and apparatuses are also described.

Abstract: Apparatuses, memory modules, and methods for performing intra-module data bus inversion operations are described. An example apparatus include a memory module comprising a data bus inversion (DBI) and buffer circuit and a plurality of memories. The DBI and buffer circuit configured to encode a block of data received by the memory module and to provide DBI data and a corresponding DBI bit to a respective memory of the plurality of memories.

Abstract: An apparatus comprising is disclosed. The apparatus a driver circuit configured to selectively provide a first supply voltage to an output node in a first operating mode and to selectively provide a second supply voltage to the output node in a second operating mode, based on one or more enable signals.

Abstract: Apparatuses, memory modules, and methods for performing intra-module data bus inversion operations are described. An example apparatus include a memory module comprising a data bus inversion (DBI) and buffer circuit and a plurality of memories. The DBI and buffer circuit configured to encode a block of data received by the memory module and to provide DBI data and a corresponding DBI bit to a respective memory of the plurality of memories.

Abstract: Apparatuses, memory modules, and methods for performing intra-module data bus inversion operations are described. An example apparatus include a memory module comprising a data bus inversion (DBI) and buffer circuit and a plurality of memories. The DBI and buffer circuit configured to encode a block of data received by the memory module and to provide DBI data and a corresponding DBI bit to a respective memory of the plurality of memories.

Abstract: Memory devices and methods of making and operating them are shown. Memory devices shown include stacked memory dies with one or more buffer dies included. In one such memory device, a command die communicates with one or more downstream memory dies through the one or more buffer dies. The one or more buffer dies function to repeat signals, and can potentially improve performance for higher numbers of memory dies in the stack.

Abstract: Methods and apparatus to transfer data between a first device and a second device, is disclosed. An apparatus according to various embodiments may comprise a first device and a second device. The first device may comprise at least one first non-differential transmitter coupled to a first channel, at least one second non-differential transmitter coupled to a second channel, and at least one differential receiver to receive a data bit and its complement on the first and second channels in parallel. The second device may comprise at least one first non-differential receiver coupled to the first channel, at least one second non-differential receiver coupled to the second channel, and at least one differential transmitter to transmit a data bit and its complement on the first and second channels in parallel.

Abstract: Devices and methods for operating devices are provided, such as those that include a memory device having a reference voltage (Vref) circuit that has substantially similar paths and impedances as an on-die termination (ODT) circuit. One such Vref circuit tracks supply variations and temperature changes in a manner substantially similar to the ODT circuit. In some embodiments an update scheme is provide for the ODT circuit and the Vref circuit to enable simultaneous update of each circuit through the same digital codes.

Abstract: Methods and apparatus apparatuses to transfer data between a first device and a second device are disclosed. In various embodiments, an apparatus includes a first device and a second device. The first device includes at least one first non-differential transmitter coupled to a first channel, at least one second non-differential transmitter coupled to a second channel, and at least one differential receiver to receive a data bit and its complement on the first and second channels in parallel. The second device includes at least one first non-differential receiver coupled to the first channel, at least one second non-differential receiver coupled to the second channel, and at least one differential transmitter to transmit a data bit and its complement on the first and second channels in parallel. Other methods and apparatuses are disclosed.

Abstract: Apparatus are disclosed, such as those involving a transmitter circuit that is configured to generate multi-level signals based on a plurality of data digits. One such transmitter circuit includes a signal output and an encoder configured to provide control signals based at least partially on the plurality of data digits. The transmitter circuit also includes a first set of switches configured to receive one or more of the control signals, and to selectively conduct a first or second voltage reference to the signal output. The transmitter circuit further includes first and second voltage drop circuits that provide third and fourth voltage references, respectively. The third and fourth voltage references have voltage levels between those of the first and second voltage references. The transmitter circuit also includes a second set of switches configured to receive one or more of the control signals, and selectively conduct the third or fourth voltage reference to the signal output.

Abstract: Methods and apparatuses disclose various embodiments of time-domain signal generation. In one embodiment a method includes receiving an input waveform having a plurality of cycles with aspects of the input waveform being input and controllable by an end-user. A set of transform coefficients is calculated for at least some of the cycles using at least one hardware-based processor. A time-domain cycle is calculated for each set of transform coefficients. Other methods and apparatuses are disclosed.

Abstract: A reference voltage (Vref) generator for a single-ended receiver in a communication system is disclosed. The Vref generator in one example comprises a cascoded current source for providing a current, I, to a resistor, Rb, to produce the Vref voltage (I*Rb). Because the current source isolates Vreffrom a first of two power supplies, Vref will vary only with the second power supply coupled to Rb. As such, the Vref generator can be used in systems employing signaling referenced to that second supply but having decoupled first supplies. For example, in a communication system in which the second supply (e.g., Vssq) is common to both devices, but the first supply (Vddq) is not, the disclosed Vref generator produces a value for Vref that tracks Vssq but not the first supply.

Abstract: Apparatus are disclosed, such as those involving a 3-D integrated circuit. One such apparatus includes a first die including a plurality of vertical connectors formed therethrough. The apparatus also includes a first circuit configured to encode multiple data bits into a multi-bit symbol, and provide the multi-bit symbol to two or more of the vertical connectors. The apparatus further includes a second circuit configured to receive the multi-bit symbol from at least one of the two or more vertical connectors, and decode the multi-bit symbol into the multiple data bits. The apparatus provides enhanced repairability with no or less redundant vertical connectors, thus avoiding the need for “on the fly” or field repair of defective vertical connectors.

Abstract: Apparatus are disclosed, such as those involving a transmitter circuit that is configured to generate multi-level signals based on a plurality of data digits. One such transmitter circuit includes a signal output and an encoder configured to provide control signals based at least partially on the plurality of data digits. The transmitter circuit also includes a first set of switches configured to receive one or more of the control signals, and to selectively conduct a first or second voltage reference to the signal output. The transmitter circuit further includes first and second voltage drop circuits that provide third and fourth voltage references, respectively. The third and fourth voltage references have voltage levels between those of the first and second voltage references. The transmitter circuit also includes a second set of switches configured to receive one or more of the control signals, and selectively conduct the third or fourth voltage reference to the signal output.

Abstract: Disclosed herein are circuitry and methods for transmitting data across a parallel bus using both high common mode and low common mode signaling. The transmitter stages are configured to work with two of three possible power supply voltages: a high Vddq voltage, a low Vssq voltage, and an intermediate Vx voltage. In one embodiment, the odd numbered transmitter stages, that drive the odd numbered outputs to the bus, use the Vddq and Vx supplies, such that the odd numbered outputs comprise high common mode signals. The even numbered transmitter stages, that drive the even numbered outputs to the bus, use the Vx and Vssq supplies, such that the even numbered outputs comprise low common mode signals.

Abstract: Implementations of Data Bus Inversion (DBI) techniques within a memory system are disclosed. In one embodiment, a set of random access memory (RAM) integrated circuits (ICs) is separated from a logic system by a bus. The logic system can contain many of the logic functions traditionally performed on conventional RAM ICs, and accordingly the RAM ICs can be modified to not include such logic functions. The logic system, which can be a logic integrated circuit intervening between the modified RAM ICs and a traditional memory controller, additionally contains DBI encoding and decoding circuitry. In such a system, data is DBI encoded and at least one DBI bit issued when writing to the modified RAM ICs. The RAM ICs in turn store the DBI bit(s) with the encoded data. When the encoded data is read from the modified RAM ICs, it is transmitted across the bus in its encoded state along with the DBI bit(s). The logic integrated circuit then decodes the data using the DBI bit(s) to return it to its original state.

Abstract: Apparatus are disclosed, such as those involving a transmitter circuit that is configured to generate multi-level signals based on a plurality of data digits. One such transmitter circuit includes a signal output and an encoder configured to provide control signals based at least partially on the plurality of data digits. The transmitter circuit also includes a first set of switches configured to receive one or more of the control signals, and to selectively conduct a first or second voltage reference to the signal output. The transmitter circuit further includes first and second voltage drop circuits that provide third and fourth voltage references, respectively. The third and fourth voltage references have voltage levels between those of the first and second voltage references. The transmitter circuit also includes a second set of switches configured to receive one or more of the control signals, and selectively conduct the third or fourth voltage reference to the signal output.

Abstract: Implementations of encoding techniques are disclosed. The encoding technique, such as a Data bus Inversion (DBI) technique, is implementable in a vertically-stacked memory module, but is not limited thereto. The module can be a plurality of memory integrated circuits which are vertically stacked, and which communicate via a bus formed in one embodiment of channels comprising Through-Wafer Interconnects (TWIs), but again is not limited thereto. One such module includes spare channels that are normally used to reroute a data signal on the bus away from faulty data channels. In one disclosed technique, the status of a spare channel or channels is queried, and if one or more are unused, they can be used to carry a DBI bit, thus allowing at least a portion of the bus to be assessed in accordance with a DBI algorithm. Depending on the location and number of spare channels needed for rerouting, DBI can be apportioned across the bus in various manners.

Abstract: Methods and apparatuses for providing multi-level encoded signals are disclosed. An apparatus may include an encoding circuit and a multi-level encoder. The encoding circuit may be configured to receive data and provide encoded data based, at least in part on the data. The multi-level encoder may be coupled to the encoding circuit and configured to receive the encoded data. The multi-level encoder may be further configured to provide the encoded data to a bus as multi-level signal responsive, at least in part, to receipt of the encoded data.

Abstract: Methods and apparatuses disclose various embodiments of time-domain signal generation. In one embodiment a method includes receiving an input waveform having a plurality of cycles with aspects of the input waveform being input and controllable by an end-user. A set of transform coefficients is calculated for at least some of the cycles using at least one hardware-based processor. A time-domain cycle is calculated for each set of transform coefficients. Other methods and apparatuses are disclosed.