A clock mode configuration circuit for a memory device is described. A memory system includes any number of memory devices serially connected to each other, where each memory device receives a clock signal. The clock signal can be provided either in parallel to all the memory devices or serially from memory device to memory device through a common clock input. The clock mode configuration circuit in each memory device is set to a parallel mode for receiving the parallel clock signal, and to a serial mode for receiving a source synchronous clock signal from a prior memory device. Depending on the set operating mode, the data input circuits will be configured for the corresponding data signal format, and the corresponding clock input circuits will be either enabled or disabled. The parallel mode and the serial mode is set by sensing a voltage level of a reference voltage provided to each memory device.

A semiconductor memory instance is provided that includes an array of memory cells. The array includes a plurality of semiconductor memory cells arranged in at least one column and at least one row. Each of the semiconductor memory cells includes a floating body region configured to be charged to a level indicative of a state of the memory cell. Further includes are a plurality of buried well regions, wherein each of the buried well regions can be individually selected, and a decoder circuit to select at least one of the buried well regions.

A method can include, in an integrated circuit device: at a unidirectional command-address (CA) bus having no more than four parallel inputs, receiving a sequence of no less than three command value portions; latching each command value portion in synchronism with rising edges of a timing clock; determining an input command from the sequence of no less than three command value portions; executing the input command in the integrated circuit device; and on a bi-directional data bus having no more than six data input/outputs (IOs), outputting and inputting sequences of data values in synchronism with rising and falling edges of the timing clock. Corresponding devices and systems are also disclosed.

Methods, systems, and devices for dual address encoding for logical-to-physical mapping are described. A memory device may identify a first physical address corresponding to a first logical block address generated by a host device and a second physical address corresponding to a second (consecutive) logical block address generated by a host device. The memory device may store the first physical address and second physical address in a single entry of a logical-to-physical mapping table that corresponds to the first logical block address. The memory device may transmit the logical-to-physical table to the host device for storage at the host device. The host device may subsequently transmit a single read command to the memory device that includes the first physical address and the second physical address based on the logical-to-physical table.

A system and method are provided that, among other things, can reduce the burden on receiving computers, increase data throughput, reduce system failure, and provide components of a scalable and flexible network architecture. Specifically, the system and method provide a multichannel-multicast network environment for use in dynamically assigning data to channels. This configuration is particularly useful in a trading network environment, as it effectively performs channel reassignments in a way not to disturb the receipt of the underlying data. While the example embodiments described herein pertain to electronic trading, the principles of the present invention may be equally applied in other environments where the advantages presented herein are beneficial.

A memory device and a glitch prevention method thereof are provided. The memory device includes a data strobe signal input circuitry, a transfer signal generating circuitry, a data alignment circuitry, and a blocking circuitry. The data strobe signal input circuitry is configured to input a data strobe signal. The transfer signal generating circuitry is configured to generate a transfer signal with pulses in synchronization with rising edges or falling edges of the data strobe signal in response to a transfer command. The data alignment circuitry is configured to align a data signal to be transferred in response to the generated transfer signal. The blocking circuitry is configured to block an input of the data strobe signal over a postamble timing of the data strobe signal according to a number of bursts counted in each time of data transfer.

An apparatus includes an in-memory compute circuit that includes a memory circuit configured to generate a set of products by combining received input values with respective weight values stored in rows of the memory circuit, and to combine the set of products to generate an accumulated output value. The in-memory compute circuit may further include a control circuit and a plurality of routing circuits, including a first routing circuit coupled to a first set of rows of the memory circuit. The control circuit may be configured to cause the first routing circuit to route groups of input values to different ones of the first set of rows over a plurality of clock cycles, and the memory circuit to generate, on a clock cycle following the plurality of clock cycles, a particular accumulated output value that is computed based on the routed groups of input values.

Aspects of the invention include decoding a base address and an offset to generate a first potential memory address and a second potential memory address. A first cell data associated with the first potential memory address of a first partitioned array and a second cell data associated with a second partitioned array are evaluated. Carry-out bit information is received from a summing operation of the base address and the offset, the operating being performed in parallel to the decoding. The carry-out bit information is used to select either the first cell data or the second cell data.

The present disclosure includes apparatuses and methods for bank to bank data transfer. An example apparatus includes a plurality of banks of memory cells, an internal bus configured to transfer data between the plurality of banks and an external bus interface, and a bank-to-bank transfer bus configured to transfer data between the plurality of banks.

A semiconductor memory device includes a memory cell array, a bit-line switch, a block switch, and a column decoder. The memory cell array includes memory blocks coupled to at least one word-line and each of the memory blocks includes memory cells. The bit-line switch is connected between a first half local input/output (I/O) line of a first memory block and a second half local I/O line of the first memory block. The block switch is connected between the second half local I/O line of the first memory block and a first half local I/O line of a second memory block adjacent to the first memory block. The column decoder includes a repair circuit that controls connections by applying a first switching control signal to the bit-line switch and a second switching control signal to the block switch.