Laurent Lopez

Impact of hump effect on MOSFET mismatch in the sub-threshold area for low power analog applications

Analog circuit designs are often biased to work in sub-threshold mode with good gate-source voltage matching performances. Depending on the process, hump effect may change the MOS characteristics for negative Bulk-Source Voltage (VBS) and have a slight impact for VBS=0V. To model the hump effect, two narrow parasitic MOS are introduced in parallel with the main device. To accurately simulate matching degradation in sub-threshold mode, these parasitic transistors, in case of hump effect, have to be considered.

Energy consumption optimization in nonvolatile silicon nanocrystal memories

In this paper we investigate the energy consumption of Discrete-Trap Silicon Nanocrystal (Si-nc) Nonvolatile Memory Cell during Channel Hot Electron programming operation. We compare this cell with a Floating Gate Flash in order to evaluate the current absorption and the energy consumption under different conditions. Using a commercial TCAD simulator, a good agreement between data and simulations is obtained and the involved mechanisms are analysed. Then we propose a solution to optimize the programming window and energy consumption trade-off for Si-nc Flash Cells.

Dynamic power reduction through process and design optimizations on CMOS 80 nm embedded non-volatile memories technology

This paper describes different solutions to decrease dynamic consumption of circuits processed on an embedded non-volatile memories CMOS 80 nm technology. Up to 25 % in dynamic power reduction is demonstrated without degrading performances and static leakages of devices and above all, with full DMR compliancy. Ring oscillator designs are used to estimate the dynamic power gain, comparing new development process (B) to reference process (A) currently in use in manufacturing.

Gate Voltage Matching Investigation for Low-Power Analog Applications

On CMOS technology, some process steps can create a parasitic phenomenon named “hump effect.” This parasitic effect can have a strong impact on gate voltage matching of differential pairs and, as a consequence, on analog circuit performances. In this context, several solutions to limit or remove this hump effect are proposed and described. Silicon data obtained at package and wafer levels for different temperatures are analyzed.

Active “multi-fingers”: Test structure to improve MOSFET matching in sub-threshold area

Low power analog applications are often designed under threshold and can be degraded by hump effect. This effect is explained through device dimensions and body bias studies. A MOSFET matching improvement in sub-threshold area is demonstrated with active “multi-fingers” test structure.

Octagonal MOSFET: Reliable device for low power analog applications

Low power analog circuits needs large and short MOSFETs biased in the sub-threshold area with good performances in terms of matching. In order to reach these specifications, octagonal transistors are proposed. Due to their design, these transistors avoid hump effect. As a consequence, gate-source voltage matching under-threshold is always at its best level. Moreover, the paper shows the device robustness to hot carrier stress is improved on octagonal NMOS; VT matching degradation due to hot carrier stress is also improved with an octagonal design.

Matching degradation of threshold voltage and gate voltage of NMOSFET after Hot Carrier Injection stress

Device degradation modelling is more and more important for reliable circuit design. On MOSFET, the threshold voltage drift in time can lead to circuit performance degradation. In this study, VT shift due to Hot Carrier Injection stress is accelerated on small width devices. VT matching is also degraded during stress as a function of VT deterioration. This width dependence allows explaining gate voltage matching behavior in the sub-threshold area used in low power analog applications.

Mechanical–Electrical Measurements and Relevant Test Structures for Sensing Interconnect Stress Effects in CMOS Technology

For CMOS technology, the increase of interconnects metal density is responsible for heterogeneous mechanical stress fields in active regions of silicon. Coupled mechanical–electrical measurements are performed to evaluate the impact of stress at circuit and device levels. This mismatch originated by interconnects metal lines stress is measured through the use of piezoresistive test structures. Local mechanical stress can thus be monitored in a simple process control compatible approach.

Sensing mobility mismatch due to local interconnect mechanical stress in CMOS technology

For CMOS technology, the increase of interconnects metal density is responsible for heterogeneous mechanical stress fields in active region of silicon. This mismatch originated by interconnects metal lines stress is measured through the use of piezo-resistive test structures. Local mechanical stress can thus be monitored in a simple process control compatible approach.

A New Embedded Measurement Structure for eDRAM Capacitor

The embedded DRAM (eDRAM) is more and more used in system-on-chip (SOC). It is challenging to integrate the DRAM capacitor process into a logic process to get satisfactory yields. The specific process of DRAM capacitor and the low capacitance value (/spl sim/30 fF) of this device induce problems of process monitoring and failure analysis. We propose a new test structure to measure the capacitance value of each DRAM cell capacitor in a DRAM array. This concept has been validated by simulation on a 0.18 /spl mu/m eDRAM technology.