Ping Keung Ko

Bio: Ping Keung Ko is an academic researcher from Hong Kong University of Science and Technology. The author has contributed to research in topics: MOSFET & Silicon on insulator. The author has an hindex of 24, co-authored 94 publications receiving 2124 citations. Previous affiliations of Ping Keung Ko include University of California, Berkeley.

A physical and scalable I-V model in BSIM3v3 for analog/digital circuit simulation

Abstract: A new physical and continuous BSIM (Berkeley Short-Channel IGFET Model) I-V model in BSIM3v3 is presented for circuit simulation. Including the major physical effects in state-of-the art MOS devices, the model describes current characteristics from subthreshold to strong inversion as well as from the linear to the saturation operating regions with a single I-V expression, and guarantees the continuities of I/sub ds/, conductances and their derivatives throughout all V/sub gs/, V/sub ds/, and T/sub bs/, bias conditions. Compared with the previous BSIM models, the improved model continuity enhances the convergence property of the circuit simulators. Furthermore, the model accuracy has also been enhanced by including the dependencies of geometry and bias of parasitic series resistances, narrow width, bulk charge, and DIBL effects. The new model has the extensive built-in dependencies of important dimensional and processing parameters (e.g., channel length, width, gate oxide thickness, junction depth, substrate doping concentration, etc.). It allows users to accurately describe the MOSFET characteristics over a wide range of channel lengths and widths for various technologies, and is attractive for statistical modeling. The model has been implemented in the circuit simulators such as Spectre, Hspice, SmartSpice, Spice3e2, and so on.

Electrically programmable memory device employing source side injection

Abstract: An electrically programmable and eraseable memory element using source-side hot-electron injection. A semi-conductor substrate of a first conductivity type is provided with a source region and a drain region of opposite conductivity type and a channel region of the first conductivity type extending between the source and drain regions. A control gate overlies the channel region, and a floating gate insulated from the control gate, the source and drain regions and the channel region is located either directly underneath the control gate over the channel region, partially underneath the control gate over the channel region or spaced to the source side of the control gate. A weak gate control region is provided in the device near the source so that a relatively high channel electric field for promoting hot-electron injection is created under the weak gate control region when the device is biased for programming.

Super thin-film transistor with SOI CMOS performance formed by a novel grain enhancement method

Abstract: High performance super TFTs with different channel widths and lengths, formed by a novel grain enhancement method, are reported. High temperature annealing has been utilized to enhance the polysilicon grain and improve the quality of silicon crystal after low temperature MILC treatment on amorphous silicon. With device scaling, it is possible to fabricate the entire transistor on a single grain, thus giving the performance of single crystal SOI MOSFET. The effects of grain boundaries on device performance have been studied, indicating the existence of extra leakage current paths caused by the grain boundaries traversing the channel, which induced subthreshold hump and early punchthrough of wide devices. The probability for the channel region of a TFT to cover multiple grains decreases significantly when the device is scaled down, resulting in better device performance and higher uniformity.

Mosfet carrier mobility model based on gate oxide thickness, threshold and gate voltages

Abstract: The widely accepted universal dependence of N- and P-MOSFETs carrier mobility on effective vertical field E eff = (ηQ inv + Q b ) ϵ Si has been re-examined. New empirical mobility models for both electrons and holes expressed in terms of Tox, Vt and Vg explicitly are formulated. New empirical mobility models are confirmed with experimental data taken from devices of different technologies. It is also shown that the hole mobility of both the surface and buried channel P-MOSFETs can be unified for the first time by a single universal mobility equation, rather than two separate equations as previously thought necessary.

A unified model for hot-electron currents in MOSFET's

Abstract: A simplified and efficient method to account for two-dimensional effects on the electric field in the pinched-off region near to the drain of a MOSFET is shown to provide accurate predictions of the drain, gate and substrate currents, Measurements agree well with theory for a wide range of processing parameters and geometries.

Fundamentals of Modern VLSI Devices

Abstract: Learn the basic properties and designs of modern VLSI devices, as well as the factors affecting performance, with this thoroughly updated second edition. The first edition has been widely adopted as a standard textbook in microelectronics in many major US universities and worldwide. The internationally-renowned authors highlight the intricate interdependencies and subtle tradeoffs between various practically important device parameters, and also provide an in-depth discussion of device scaling and scaling limits of CMOS and bipolar devices. Equations and parameters provided are checked continuously against the reality of silicon data, making the book equally useful in practical transistor design and in the classroom. Every chapter has been updated to include the latest developments, such as MOSFET scale length theory, high-field transport model, and SiGe-base bipolar devices.

Semiconductor device, and manufacturing method thereof

Abstract: An object is to provide a semiconductor device of which a manufacturing process is not complicated and by which cost can be suppressed, by forming a thin film transistor using an oxide semiconductor film typified by zinc oxide, and a manufacturing method thereof. For the semiconductor device, a gate electrode is formed over a substrate; a gate insulating film is formed covering the gate electrode; an oxide semiconductor film is formed over the gate insulating film; and a first conductive film and a second conductive film are formed over the oxide semiconductor film. The oxide semiconductor film has at least a crystallized region in a channel region.

Highly compact EPROM and flash EEPROM devices

Abstract: Structures, methods of manufacturing and methods of use of electrically programmable read only memories (EPROM) and flash electrically erasable and programmable read only memories (EEPROM) include split channel and other cell configurations. An arrangement of elements and cooperative processes of manufacture provide self-alignment of the elements. An intelligent programming technique allows each memory cell to store more than the usual one bit of information. An intelligent erase algorithm prolongs the useful life of the memory cells. Use of these various features provides a memory having a very high storage density and a long life, making it particularly useful as a solid state memory in place of magnetic disk storage devices in computer systems.

Hot-electron-induced MOSFET degradation—Model, monitor, and improvement

Abstract: Evidence suggests that MOSFET degradation is due to interface-states generation by electrons having 3.7 eV and higher energies. This critical energy and the observed time dependence is explained with physical model involving the breaking of the ≡ Si s H bonds. The device lifetime τ is proportional to I_{sub}^{-2.9}I_{d}^{1.9}\Delta V_{t}^{1.5} . If I sub is large because of small L or large V d , etc., τ will be small. I sub (and possibly light emission) is thus a powerful predictor of τ. The proportionality constant has been found to vary by a factor of 100 for different technologies, offering hope for substantially better reliability through future improvements in dielectric /interface technologies. A simple physical model can relate the channel field E m to all the device parameters and bias voltages. Its use in interpreting and guiding hot-electron scaling are described. LDD structures can reduce E m and I sub and, when properly designed, reduce device degradation.

Multi-state memory

Abstract: Maximized multi-state compaction and more tolerance in memory state behavior is achieved through a flexible, self-consistent and self-adapting mode of detection, covering a wide dynamic range. For high density multi-state encoding, this approach borders on full analog treatment, dictating analog techniques including A to D type conversion to reconstruct and process the data. In accordance with the teachings of this invention, the memory array is read with high fidelity, not to provide actual final digital data, but rather to provide raw data accurately reflecting the analog storage state, which information is sent to a memory controller for analysis and detection of the actual final digital data.