Variable and rotatable waveplates of PLZT electrooptic ceramicmaterial on planar waveguide circuits

We have applied the (Pb_1-xLa_x)(Zr_yTi_z)_1-x/4 O₃ (PLZT) electro-optic ceramic material to produce variable and rotatable waveplates for polarization controls. This plate has a 90 μm×90 μm window between four sides. Each of the four sides is coated with a material that acts as an electrode. The plate is inserted in a trench across an array of parallel optical waveguides. A single PLZT waveplate of this type was capable of continuous and complete conversion. This requires the control of only two parameters, the direction and strength of the applied voltage. The device is fast with a response time of only 1 μs     

BC high-/spl kappa//metal gate Ge/C alloy pMOSFETs fabricated directly on Si (100) substrates

Buried-channel (BC) high-/spl kappa//metal gate pMOSFETs were fabricated on Ge/sub 1-x/C/sub x/ layers for the first time. Ge/sub 1-x/C/sub x/ was grown directly on Si (100) by ultrahigh-vacuum chemical vapor deposition using methylgermane (CH/sub 3/GeH/sub 3/) and germane (GeH/sub 4/) precursors at 450/spl deg/C and 5 mtorr. High-quality films were achieved with a very low root-mean-square roughness of 3 /spl Aring/ measured by atomic force microscopy. The carbon (C) content in the Ge/sub 1-x/C/sub x/ layer was approximately 1 at.% as measured by secondary ion mass spectrometry. Ge/sub 1-x/C/sub x/ BC pMOSFETs with an effective oxide thickness of 1.9 nm and a gate length of 10 /spl mu/m exhibited high saturation drain current of 10.8 /spl mu/A//spl mu/m for a gate voltage overdrive of -1.0 V. Compared to Si control devices, the BC pMOSFETs showed 2/spl times/ enhancement in the saturation drain current and 1.6/spl times/ enhancement in the transconductance. The I/sub on//I/sub off/ ratio was greater than 5/spl times/10/sup 4/. The improved drain current represented an effective hole mobility enhancement of 1.5/spl times/ over the universal mobility curve for Si.     

AlGaN/GaN/InGaN/GaN DH-HEMTs with an InGaN notch for enhanced carrier confinement

We report an AlGaN/GaN/InGaN/GaN double heterojunction high electron mobility transistors (DH-HEMTs) with high-mobility two-dimensional electron gas (2-DEG) and reduced buffer leakage. The device features a 3-nm thin In/sub x/Ga/sub 1-x/N(x=0.1) layer inserted into the conventional AlGaN/GaN HEMT structure. Assisted by the InGaN layers polarization field that is opposite to that in the AlGaN layer, an additional potential barrier is introduced between the 2-DEG channel and buffer, leading to enhanced carrier confinement and improved buffer isolation. For a sample grown on sapphire substrate with MOCVD-grown GaN buffer, a 2-DEG mobility of around 1300 cm/sup 2//V/spl middot/s and a sheet resistance of 420 /spl Omega//sq were obtained on this new DH-HEMT structure at room temperature. A peak transconductance of 230 mS/mm, a peak current gain cutoff frequency (f/sub T/) of 14.5 GHz, and a peak power gain cutoff frequency (f/sub max/) of 45.4 GHz were achieved on a 1/spl times/100 /spl mu/m device. The off-state source-drain leakage current is as low as /spl sim/5 /spl mu/ A/mm at V/sub DS/=10 V. For the devices on sapphire substrate, maximum power density of 3.4 W/mm and PAE of 41% were obtained at 2 GHz.     

A low-power 22-bit incremental ADC

This paper describes a low-power 22-bit incremental ADC, including an on-chip digital filter and a low-noise/low-drift oscillator, realized in a 0.6-/spl mu/m CMOS process. It incorporates a novel offset-cancellation scheme based on fractal sequences, a novel high-accuracy gain control circuit, and a novel reduced-complexity realization for the on-chip sinc filter. The measured output noise was 0.25 ppm (2.5 /spl mu/V/sub RMS/), the DC offset 2 /spl mu/V, the gain error 2 ppm, and the INL 4 ppm. The chip operates with a single 2.7-5 V supply, and draws only 120 /spl mu/A current during conversion.     

SODEL FET: novel channel and source/drain profile engineering schemes by selective Si epitaxial growth technology

In this paper, novel channel and source/drain profile engineering schemes are proposed for sub-50-nm bulk CMOS applications. This device, referred to as the silicon-on-depletion layer FET (SODEL FET), has the depletion layer beneath the channel region, which works as an insulator like a buried oxide in a silicon-on-insulator MOSFET. Thanks to this channel structure, junction capacitance (C/sub j/) has been reduced in SODEL FET, i.e., C/sub j/ (area) was /spl sim/0.73 fF//spl mu/m/sup 2/ both in SODEL nFET and pFET at Vbias =0.0 V. The body effect coefficient /spl gamma/ is also reduced to less than 0.02 V/sup 1/2/. Nevertheless, current drives of 886 /spl mu/A//spl mu/m (I/sub off/=15 nA//spl mu/m) in nFET and -320 /spl mu/A//spl mu/m (I/sub off/=10 nA//spl mu/m) in pFET have been achieved in 70-nm gate length SODEL CMOS with |V/sub dd/|=1.2 V. New circuit design schemes are also proposed for high-performance and low-power CMOS applications using the combination of SODEL FETs and bulk FETs on the same chip for 90-nm-node generation and beyond.     

A single-chip CMOS optical microspectrometer with light-to-frequency converter and bus interface

A single-chip CMOS optical microspectrometer containing an array of 16 addressable Fabry-Perot etalons (each one with a different resonance cavity length), photodetectors, and circuits for readout, multiplexing, and driving a serial bus interface has been fabricated in a standard 1.6 /spl mu/m CMOS technology (chip area 3.9 /spl times/ 4.2 mm/sup 2/). The result is a chip that can operate using only four external connections (including V/sub dd/ and V/sub ss/) covering the optical range of 380-500 nm with full-width half-maximum (FWHM) = 18 nm. Frequency output and serial bus interface allow easy multisensor and multichip interfacing using a microcontroller or a personal computer. Power consumption is 1250 /spl mu/W for a clock frequency of 1 MHz.     

A DPS array with programmable resolution and reconfigurable conversion time

A CMOS digital pixel sensor (DPS) with programmable resolution and reconfigurable conversion time is described. The chip features a unique architecture based on the pulse width modulation (PWM) technique and operates with either an 8-b or 4-b accuracy. The 8-b conversion mode is used for high-precision imaging while the 4-b conversion mode provides a shorter conversion time and a two times increase in spatial resolution. Two quantization schemes are studied, namely, the uniform and the nonuniform time-domain quantizers, which are referred to as UQ and NUQ, respectively. It is shown that the latter scheme not only permits to linearize the nonlinear response of the PWM sensor, but also allows to significantly speed up the conversion time, particularly for wide dynamic range and low coding resolutions. A prototype of 32/spl times/32/64/spl times/32 pixels has been fabricated using 1-poly, 5-metal CMOS 0.35-/spl mu/m n-well standard process. Power dissipation is 10 mW at V/sub DD/=3.3 V, dynamic range is 90 dB, while dark current was measured at 1 pA. The reconfiguration features of the chip have been verified experimentally.     

Characteristics of In/sub x/Al/sub 1-x/N-GaN high-electron mobility field-effect transistor

GaN-based field effect transistors commonly include an Al/sub x/Ga/sub 1-x/N barrier layer for confinement of a two-dimensional electron gas (2DEG) in the barrier/GaN interface. Some of the limitations of the Al/sub x/Ga/sub 1-x/N-GaN heterostructure can be, in principle, avoided by the use of In/sub x/Al/sub 1-x/N as an alternative barrier, which adds flexibility to the engineering of the polarization-induced charges by using tensile or compressive strain through varying the value of x. Here, the implementation and electrical characterization of an In/sub x/Al/sub 1-x/-GaN high electron mobility transistor with Indium content ranging from x=0.04 to x=0.15 is described. The measured 2DEG carrier concentration in the In/sub 0.04/Al/sub 0.96/N-GaN heterostructure reach 4/spl times/10/sup 13/ cm/sup -2/ at room temperature, and Hall mobility is 480 and 750 cm/sup 2//V /spl middot/ s at 300 and 10 K, respectively. The increase of Indium content in the barrier results in a shift of the transistor threshold voltage and of the peak transconductance toward positive gate values, as well as a decrease in the drain current. This is consistent with the reduction in polarization difference between GaN and In/sub x/Al/sub 1-x/N. Devices with a gate length of 0.7 /spl mu/m exhibit f/sub t/ and f/sub max/ values of 13 and 11 GHz, respectively.     

A 4-Mbit CMOS EPROM

A high-density (512K-word/spl times/8-b) erasable programmable read-only memory (EPROM) has been designed and fabricated by using 0.8-/spl mu/m n-well CMOS technology. A novel chip layout and a sense-amplifier circuit produce a 120-ns access time and a 4-mA operational supply current. The interpoly dielectric, composed of a triple-layer structure, realizes a 10-/spl mu/s/byte fast programming time, in spite of scaling the programming voltage V/SUB PP/ from 12.5 V for a 1-Mb EPROM to 10.5 V for this 4-Mb EPROM. To meet the increasing demand for a one-time programmable (OTP) ROM, a circuit is implemented to monitor the access time after the assembly. A novel redundancy scheme is incorporated to reduce additional tests after the laser fuse programming. Cell size and chip size are 3.1/spl times/2.9 /spl mu/m/SUP 2/ and 5.86/spl times/14.92 mm/SUP 2/, respectively.     

High-performance InGaP/GaAs HBTs with compositionally graded bases grown by solid-source MBE

N-p-n InGaP/GaAs heterojunction bipolar transistors (HBTs) with compositionally graded In/sub x/Ga/sub 1-x/As (Be doped) bases have been successfully grown by solid-source molecular beam Epitaxy (SSMBE) using a gallium phosphide (GaP) decomposition source. In this paper, the dc and RF characteristics of HBTs with different indium mole fractions in the graded In/sub x/Ga/sub 1-x/As base (x:0 /spl rarr/ ;0.1 and x:0 /spl rarr/ 0.05) are measured to investigate optimum-grading profiles. The measured average current gains, /spl beta/s of a control sample, a 10% graded-base sample and a 5% graded-base sample, are 162, 397 and 362, respectively. To our knowledge, these current gains are the highest values ever reported in compositionally graded-base InGaP/GaAs HBTs with a base sheet resistance R/sub sh/ of /spl sim/200 /spl Omega//sq establishing a new benchmark for InGaP/GaAs HBTs. Furthermore, these compositionally graded-base HBTs show higher unity current/gain cutoff frequency, f/sub T/ and maximum oscillation frequency, f/sub max/. Compared to the control sample with the same base thickness, the base transit time /spl tau//sub B/ of the graded sample is reduced by /spl sim/15% to /spl sim/20% by the induced built-in potential, resulting in an increase of f/sub max/ from 16 to 18.5 GHz in a device with an emitter size of 10/spl times/10 /spl mu/m/sup 2/. Additionally, for the 5% graded-base sample, with a 5/spl times/5 /spl mu/m/sup 2/ emitter region, f/sub T/ and f/sub max/ are 16.3 and 33.8 GHz, respectively, under low-level collector current. These results demonstrate that InGaP/GaAs HBTs with In/sub x/Ga/sub 1-x/As graded-base layers (x:0 /spl rarr/ 0.05) have the potential for high-speed analogue to digital converters.     

A novel germanium doping method for fabrication of high-performance p-channel poly-Si/sub 1-x/Ge/sub x/ TFT by excimer laser crystallization

In this letter, a novel process for fabricating p-channel poly-Si/sub 1-x/Ge/sub x/ thin-film transistors (TFTs) with high-hole mobility was demonstrated. Germanium (Ge) atoms were incorporated into poly-Si by excimer laser irradiation of a-Si/sub 1-x/Ge/sub x//poly-Si double layer. For small size TFTs, especially when channel width/length (W/L) was less than 2 /spl mu/m/2 /spl mu/m, the hole mobility of poly-Si/sub 1-x/Ge/sub x/ TFTs was superior to that of poly-Si TFTs. It was inferred that the degree of mobility enhancement by Ge incorporation was beyond that of mobility degradation by defect trap generation when TFT size was shrunk to 2 /spl mu/m/2 /spl mu/m. The poly-Si/sub 0.91/Ge/sub 0.09/ TFT exhibited a high-hole mobility of 112 cm/sup 2//V-s, while the hole mobility of the poly-Si counterpart was 73 cm/sup 2//V-s.     

A technique to improve the drive current of high-voltage I/O transistors in digital CMOS technologies

By combining a 0.12-/spl mu/m-long 1.2-V thin-oxide transistor with a 0.22-/spl mu/m-long 3.3-V thick-oxide transistor in a 0.13-/spl mu/m CMOS process, a composite MOS transistor structure with a drawn gate length of 0.34 /spl mu/m is realized. Measurements show that at V/sub GS/=1.2 V and V/sub DS/=3.3 V, the composite transistor has more than two times the drain current of the minimum channel length (0.34 /spl mu/m) 3.3-V thick-oxide transistor, while having the same breakdown voltage (V/sub BK/) as the thick-oxide transistor. Exploiting these, it should be possible to implement 3.3-V I/O transistors with better combination of drive current, threshold voltage (V/sub T/) and breakdown voltage in conventional CMOS technologies without adding any process modifications.     

Low-voltage high performance compact all cascode CMOS current mirror

A high performance and compact current mirror with extremely low input and high output resistances (R/sub in//spl sim/0.01/spl Omega/, R/sub out//spl sim/10 G/spl Omega/), high copying accuracy, very low input and output voltage requirements (V/sub in/, V/sub out//spl ges/V/sub DSsat/), high bandwidth (200 MHz using a 0.5 /spl mu/m CMOS technology) and low settling time (25 ns) is proposed. Simulations and experimental results are shown that validate the circuit.     

Normal optical flow measurement on CMOS APS imager

A 92/spl times/52 active pixel sensor (APS) for dense normal flow estimation is presented. The sensor combines imaging and processing on the same chip efficiently. The algorithm computes partial derivatives with respect to time and space and uses their ratio to compute normal flow velocity. The chip, which has been fabricated in a CMOS 0.5 /spl mu/m process, occupies an area of 4.5 mm/sup 2/ and consumes 2.6 mW power at V/sub dd/=5 V.     

5.2 GHz SiGe HBT upconverter using active-inductor LC current mirror

A compact 5.2 GHz upconversion micromixer using the 0.35 /spl mu/m SiGe HBT technology is demonstrated. A bandpass and area-saving LC current mirror using the active inductor is incorporated to increase the conversion gain. The demonstrated upconverter has conversion gain of -3.5 dB, OP/sub 1dB/ of -10 dBm, and OIP/sub 3/ of 0 dBm.     

InGaAs-InP mesa DHBTs with simultaneously high f/sub /spl tau// and f/sub max/ and low C/sub cb//I/sub c/ ratio

We report an InP-InGaAs-InP double heterojunction bipolar transistor (DHBT), fabricated using a conventional triple mesa structure, exhibiting a 370-GHz f/sub /spl tau// and 459-GHz f/sub max/, which is to our knowledge the highest f/sub /spl tau// reported for a mesa InP DHBT-as well as the highest simultaneous f/sub /spl tau// and f/sub max/ for any mesa HBT. The collector semiconductor was undercut to reduce the base-collector capacitance, producing a C/sub cb//I/sub c/ ratio of 0.28 ps/V at V/sub cb/=0.5 V. The V/sub BR,CEO/ is 5.6 V and the devices fail thermally only at >18 mW//spl mu/m/sup 2/, allowing dc bias from J/sub e/=4.8 mA//spl mu/m/sup 2/ at V/sub ce/=3.9 V to J/sub e/=12.5 mA//spl mu/m/sup 2/ at V/sub ce/=1.5 V. The device employs a 30 nm carbon-doped InGaAs base with graded base doping, and an InGaAs-InAlAs superlattice grade in the base-collector junction that contributes to a total depleted collector thickness of 150 nm.     

Fabrication of high-packing-density vertical cavity surface-emitting laser arrays using selective oxidation

We describe the nearly-planar processing of two-dimensional vertical cavity laser arrays based on the selective conversion of AlAs to Al/sub x/O/sub y/. The individual lasers of 8/spl times/8 and 2/spl times/2 arrays are defined by native Al/sub x/O/sub y/ to achieve 4-/spl mu/m square active regions on 12-/spl mu/m center-to-center spacings. Interelement thermal coupling is characterized along with the optical mode structure.     

A 256-kbit flash E/SUP 2/PROM using triple-polysilicon technology

A high-density 256-kb flash electrically erasable PROM (E/SUP 2/PROM) with a single transistor per bit has been developed by utilizing triple-polysilicon technology. As a result of achieving a novel compact cell that is as small as 8/spl times/8 /spl mu/m/SUP 2/, even with relatively conservative 2.0-/spl mu/m design rules, a small die size of 5.69/spl times/5.78 mm/SUP 2/ is realized. This flash E/SUP 2/PROM is fully pin-compatible with a 256-kb UV-EPROM without increasing the number of input pins for erasing by introducing a novel programming and erasing scheme. Programming time is as fast as 200 /spl mu/s/byte and erasing time is less than 100 ms per chip. A typical access time of 90 ns is achieved by using sense-amplifier circuitry.     

A resonant tunneling quantum-dot infrared photodetector

A novel device-resonant tunneling quantum-dot infrared photodetector-has been investigated theoretically and experimentally. In this device, the transport of dark current and photocurrent are separated by the incorporation of a double barrier resonant tunnel heterostructure with each quantum-dot layer of the device. The devices with In/sub 0.4/Ga/sub 0.6/As-GaAs quantum dots are grown by molecular beam epitaxy. We have characterized devices designed for /spl sim/6 /spl mu/m response, and the devices also exhibit a strong photoresponse peak at /spl sim/17 /spl mu/m at 300 K due to transitions from the dot excited states. The dark currents in the tunnel devices are almost two orders of magnitude smaller than those in conventional devices. Measured values of J/sub dark/ are 1.6/spl times/10/sup -8/ A/cm/sup 2/ at 80 K and 1.55 A/cm/sup 2/ at 300 K for 1-V applied bias. Measured values of peak responsivity and specific detectivity D/sup */ are 0.063 A/W and 2.4/spl times/10/sup 10/ cm/spl middot/Hz/sup 1/2//W, respectively, under a bias of 2 V, at 80 K for the 6-/spl mu/m response. For the 17-/spl mu/m response, the measured values of peak responsivity and detectivity at 300 K are 0.032 A/W and 8.6/spl times/10/sup 6/ cm/spl middot/Hz/sup 1/2//W under 1 V bias.     

Standby power reduction using dynamic voltage scaling and canary flip-flop structures

Lowering V/sub DD/ during standby mode reduces power by decreasing both voltage and current. Analysis of flip-flop structures shows how low the voltage can scale before destroying the state information. Measurements of a 0.13-/spl mu/m, dual-V/sub T/ test chip show that reducing V/sub DD/ to near the point where state is lost gives the best power savings. We show that "canary" flip-flops provide a mechanism for observing the proximity to failure for the flip-flops. The canary flip-flops enable closed-loop standby voltage scaling for achieving savings near the optimum. This approach potentially provides over 2/spl times/ higher savings than an optimal open-loop approach without loss of state.