An integrated circuit includes a first memory cell array and a controller. The first memory cell array includes a first array of volatile memory cells having a first retention data time. The controller is coupled to the first memory cell array. The controller is configured to write data to each memory cell in the first memory cell array in response to the integrated circuit being successfully logged into, read data from each memory cell in the first memory cell array in response to the integrated circuit being powered on, and determine whether to allow an authentication operation of the integrated circuit in response to reading data from each memory cell in the first memory cell array.

An integrated circuit includes a first memory cell array and a controller. The first memory cell array includes a first array of volatile memory cells having a first retention data time. The controller is coupled to the first memory cell array. The controller is configured to write data to each memory cell in the first memory cell array in response to the integrated circuit being successfully logged into, read data from each memory cell in the first memory cell array in response to the integrated circuit being powered on, and determine whether to allow an authentication operation of the integrated circuit in response to reading data from each memory cell in the first memory cell array.

A novel memory device is provided. The memory device includes a plurality of memory cells, and one memory cell includes a first transistor and a second transistor. One of a source and a drain of the first transistor is electrically connected to a gate of the second transistor through a node SN. Data written through the first transistor is retained at the node SN. When an OS transistor is used as the first transistor, formation of a storage capacitor is not needed. A region with a low dielectric constant is provided outside the memory cell, whereby noise from the outside is reduced and stable operation is achieved.

A novel memory device is provided. The memory device includes a plurality of memory cells, and one memory cell includes a first transistor and a second transistor. One of a source and a drain of the first transistor is electrically connected to a gate of the second transistor through a node SN. Data written through the first transistor is retained at the node SN. When an OS transistor is used as the first transistor, formation of a storage capacitor is not needed. A region with a low dielectric constant is provided outside the memory cell, whereby noise from the outside is reduced and stable operation is achieved.

An integrated circuit (IC) includes first and scan latches that are enabled to load data during a first part of a clock period. A clocking circuit outputs latch clocks with one latch clock driven to an active state during a second part of the clock period dependent on a first address input. A set of storage elements have inputs coupled to the output of the first scan latch and are respectively coupled to a latch clock to load data during a time that their respective latch clock is in an active state. A selector circuit is coupled to outputs of the first set of storage elements and outputs a value from one output based on a second address input. The second scan latch then loads data from the selector's output during the first part of the input clock period.

Various implementations described herein are directed to an integrated circuit having first latch circuitry with multiple first latches that latch multiple input data signals. The integrated circuit may include second latch circuitry having a single second latch that receives the latched multiple input data signals from the multiple first latches and outputs a single latched data signal based on the latched multiple input data signals. The integrated circuit may include intermediate logic circuitry that is coupled between the first latch circuitry and the second latch circuitry. The intermediate logic circuitry may receive and combine the multiple input data signals from the first latch circuitry into a single data signal that is provided to the single second latch of the second latch circuitry for output as the single latched data signal.

Various implementations described herein are directed to an integrated circuit having first latch circuitry with multiple first latches that latch multiple input data signals. The integrated circuit may include second latch circuitry having a single second latch that receives the latched multiple input data signals from the multiple first latches and outputs a single latched data signal based on the latched multiple input data signals. The integrated circuit may include intermediate logic circuitry that is coupled between the first latch circuitry and the second latch circuitry. The intermediate logic circuitry may receive and combine the multiple input data signals from the first latch circuitry into a single data signal that is provided to the single second latch of the second latch circuitry for output as the single latched data signal.

Systems and methods of screening memory cells by modulating bitline and/or wordline voltage. In a read operation, the wordline may be overdriven or underdriven as compared to a nominal operating voltage on the wordline. In a write operation, the one or both of the bitline and wordline may be overdriven or underdriven as compared to a nominal operating voltage of each. A built-in self test (BIST) system for screening a memory array has bitline and wordline margin controls to modulate bitline and wordline voltage, respectively, in the memory array.

Systems and methods of screening memory cells by modulating bitline and/or wordline voltage. In a read operation, the wordline may be overdriven or underdriven as compared to a nominal operating voltage on the wordline. In a write operation, the one or both of the bitline and wordline may be overdriven or underdriven as compared to a nominal operating voltage of each. A built-in self test (BIST) system for screening a memory array has bitline and wordline margin controls to modulate bitline and wordline voltage, respectively, in the memory array.

A method of designing a circuit is provided. The method includes: providing a circuit; selecting a first NMOS fin field-effect transistor (FinFET) in the circuit; and replacing the first NMOS FinFET having a first fin number with a second NMOS FinFET having a second fin number and a third NMOS FinFET having a third fin number, wherein the sum of the second fin number and the third fin number is equal to the first fin number.