Kanika Monga scite author profile

A non-volatile SRAM cell is proposed for low power applications using Spin Transfer Torque-Magnetic Tunnel Junction (STT-MTJ) devices. This novel cell offers non-volatile storage, thus allowing selected blocks of SRAM to be switched off during standby operation. To further increase the power savings, a write termination circuit is designed which detects completion of MTJ write and closes the bidirectional current path for the MTJ. A reduction of 25.81% in the number of transistors and reduction of 2.95% in the power consumption is achieved in comparison to prior work on write termination circuits.

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A Dual-Mode In-Memory Computing Unit Using Spin Hall-Assisted MRAM for Data-Intensive Applications

Monga

Chaturvedi

Gurunarayanan

2021

IEEE Trans. Magn.

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Energy-efficient data retention in D flip-flops using STT-MTJ

Monga

Chaturvedi

Gurunarayanan

2020

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Purpose Emerging event-driven applications such as the internet-of-things requires an ultra-low power operation to prolong battery life. Shutting down non-functional block during standby mode is an efficient way to save power. However, it results in a loss of system state, and a considerable amount of energy is required to restore the system state. Conventional state retentive flip-flops have an “Always ON” circuitry, which results in large leakage power consumption, especially during long standby periods. Therefore, this paper aims to explore the emerging non-volatile memory element spin transfer torque-magnetic tunnel junction (STT-MTJ) as one the prospective candidate to obtain a low-power solution to state retention. Design/methodology/approach The conventional D flip-flop is modified by using STT-MTJ to incorporate non-volatility in slave latch. Two novel designs are proposed in this paper, which can store the data of a flip-flip into the MTJs before power off and restores after power on to resume the operation from pre-standby state. Findings A comparison of the proposed design with the conventional state retentive flip-flop shows 100 per cent reduction in leakage power during standby mode with 66-69 per cent active power and 55-64 per cent delay overhead. Also, a comparison with existing MTJ-based non-volatile flip-flop shows a reduction in energy consumption and area overhead. Furthermore, use of a fully depleted-silicon on insulator and fin field-effect transistor substituting a complementary metal oxide semiconductor results in 70-80 per cent reduction in the total power consumption. Originality/value Two novel state-retentive D flip-flops using STT-MTJ are proposed in this paper, which aims to obtain zero leakage power during standby mode.

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Design of a novel CMOS/MTJ-based multibit SRAM cell with low store energy for IoT applications

Monga

Chaturvedi

Gurunarayanan

2019

International Journal of Electronics

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Kanika Monga

Design of In-Memory Computing Enabled SRAM Macro

A Novel Low Power Non-Volatile SRAM Cell with Self Write Termination

A Dual-Mode In-Memory Computing Unit Using Spin Hall-Assisted MRAM for Data-Intensive Applications

Energy-efficient data retention in D flip-flops using STT-MTJ

Design of a novel CMOS/MTJ-based multibit SRAM cell with low store energy for IoT applications

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