Ep optima synopsis

The aim of the project is to establish the added value of bipolar SiGe ICs with respect to Si-based and III-V solutions by both developing the required process technology and by demonstrating the manufacturability in application specific designs.

• 
  Several application specific circuits based on the bipolar SiGe technology (time division multiplexer, divider, broad-band amplifier, LNA). These circuits will be state-of-the-art in terms of complexity (design and technology) and performance.
  
• 
  Establish the technological targets which are expected to be necessary to realise these circuits.
  
• 
  A technical and economical benchmark of the SiGe based circuitry as compared with Si-based and III-V based equivalents.
  
• 
  A process technology available for selected key customers.
  

A LIGA-like microsystem process to produce 3-dimensional microstructures with high aspect ratios will be developed. The development is based on an inexpensive fabrication process for microstructuring of different materials using high aspect ratio dry etching and reproduction in plastic microstructures with IC tolerances. Microassembly of the structures will also form part of the project. The technology will be suited for economical fast prototyping as well as production of certain products.

· Development of fast and versatile fabrication processes for mould inserts by means of high aspect ratio dry etching of silicon and metals. The silicon moulds can be used for an electroplating process, resulting in metal mould inserts for production of microstructures by means of moulding and embossing. The aspect ratios to be expected are 10 to 20 typically at diameters in the range of microns with profile control for releasing the structures.

The goal of the project is to deliver packaged and tested evaluation samples of several specific CMOS integrated magnetic microsystems for a variety of attractive high volume applications as well as high-end safety products. The main objective is to elaborate, consolidate and to transfer to the industrial environment the know-how for mass production of versatile integrated microsystems based on magnetic sensors. The common ground is the design and test of CMOS based magnetic sensor and interface circuit prototypes by ETH Zürich and the University of Pavia, and their manufacturing by AMS.

The work is centred around four demonstrators:

A cost-effective micromachined integrated relay is to be developed. The new feature of this relay is that it combines a hard-metal contact, electromagnetic actuation, as well as electronic circuitry on the same silicon substrate. The relay will be manufactured in a batch process in a way similar to IC fabrication. The feasibility of electromagnetic principles that are commonly employed in conventional reed relays for actuation of the relay will be investigated. Furthermore, special attention will be given to the development of reliable electrical contacts and of a suitable packaging technology. The actuator (e.g. a coil), the electrical contacts and the moving mechanical parts will be fabricated in an integrated process sequence using micromachining technologies.

· Development of a novel, low-cost, high quality switching technology, which combines the switching advantages of solid-state relays with those of hard-metal-contact relays where added value electronics can be implemented on a single silicon substrate.

· The microrelay must be small, display a low and stable contact resistance, a high off-resistance and be low-cost.

· Development of a cost-effective fabrication process based on micromachining technologies for hard-contact relays with integrated electronic circuitry.

· Development of a contact technology that guarantees the required contact characteristics for life and which is fully compatible and integrated with the actuator technology and movable mechanical parts.

· Development of a low-cost packaging technology.

· Operative microrelays demonstrating the tools, features and technologies developed are to be produced. These will undergo full reliability testing in real user applications.

Participants

CP Clare (B); CSEM (CH); IMEC (B); Aritech (NL); SPEA (I).
Contact Point Duration

Harrie A. C. Tilmans 29 months from 15.11.95

CP Clare Corporation

Overhaamlaan 40

B-3700 Tongeren, (Belgium)
tel: +32 12 390 404

fax: +32 12 235 754

E-mail: tilmans@imec.be

EP 21458 Si-GYRO

Silicon Surface Micromachined Gyroscope for Mass Market Applications
Summary

A surface micromachined one-axis gyroscope mainly for automotive applications with strong market penetration is to be developed based on Thick Polysilicon Surface Micromachining (TPSM) technology. The basic process will be improved to meet the stringent requirements of the gyroscope application with respect to critical material and process parameters (control of active polysilicon layer stress and stress gradients, surface roughness, inclusion of a buried polysilicon contact layer, accuracy and aspect ratio of the microstructuring process, sacrificial etching techniques, housing and vacuum encapsulation of the sensor elements). Driving and evaluation circuitry will be realised on a separate chip and combined with the sensing device by hybrid mounting.

· Installation of a club of (automotive) end users to agree on a broadly based specification.

· Development of a surface micromachined gyroscope device for automotive applications with high resolution angular rotation (0.5 °/sec) and offset stability (0.1...1°/sec), based on the TPSM process.

· Reduction of thick polysilicon stress, stress gradients and surface roughness to extend the application of the TPSM process to the gyroscope.

· Introduction of a buried polysilicon layer with low electrical resistivity into the TPSM process. This layer is needed for capacitor fields underneath the moving gyroscope structures which provide the sensor signal, and for electrical contacting.

· Improvement of the high density plasma etching process. This is the key process for silicon surface micromachining and determines the quality of the sensor structures.

· Development of electronic circuitry to drive the sensor oscillation and detect the yaw rate signal. A breadboard version of the evaluation electronics will be debugged and optimised, serving as the basis for a monolithically integrated circuit chip.

· Fabrication of a demonstrator with sensor element and electronic circuit chip mounted together in a metal housing which will be evacuated and hermetically sealed.

A family of accelerometer microsystems will be developed for automotive applications based upon the following two types accelerometers;

· Crash sensors for frontal impacts and airbag applications range around 50g

· Crash sensors for side impacts and airbag applications range around 500g.

The project will focus on the development of key process technologies including assembly and testing, product designs and manufacture and test of functional prototypes in coordination with the establishment of high volume production capabilities.
Objectives

· Development of a 50g accelerometer sensor based on a bulk micromachined silicon resonator.

· Development of a 500g accelerometer sensor based on a bulk micromachined silicon resonator.

· Development of accompanying ASICs for integration with 50g accelerometer in a hybrid integrated microsystem for frontal impact airbag applications.

· Development of accompanying ASICs for integration with 500g accelerometer in a hybrid integrated microsystem for side impact airbag applications.

· Test and demonstration of the microsystems in the airbag application by Autoliv.

· Development and installation of the mass fabrication of silicon microsystems, glass-silicon-glass bonding, assembly and test.
Participants

SensoNor (N), Autoliv (D), Sintef (N)
Contact Point Duration

Per Ohlckers 24 months from 01.01.96

SensoNor

Knutsrodveien 7

Horten, Vestfold County

N-1392 (Norway)
tel: +47 33 035179

fax: +47 33 044098

E-mail: Per.Ohlckers@si.intef.no

EP 22889 OLMO

On-Vehicle Laser Microsystem

For Obstacle Detection
Summary

A functional prototype of a compact laser-based system for obstacle detection on-vehicles is to be developed. New microsystem technologies are to be used to address the requirements of reliability, detection performance in adverse visibility, eye safety, and cost effectiveness.

The key technologies are an eye-safe microchip laser at 1,5 m wavelength, and a beam-scanning system based on micromachined lenses and flexure structures for actuation. Original signal processing circuits will be developed, where time-of-flight and correlation techniques are integrated, aiming to improve the operation in bad atmospheric conditions. A technical evaluation, including real-field tests, and an overall assessment of the solution will be performed.

The system for obstacle detection will be the core component for driver support functions, with an high impact on safety, traffic efficiency and driving comfort. New application areas are also anticipated such as instrumentation, industrial automation and security systems.

• 
  To demonstrate the feasibility of a miniaturized and integrated obstacle detection system based on laser technology, to be used for automotive applications, particularly Intelligent Cruise Control and Anticollision.
  
• 
  To develop and make available the technology of small,eye-safe, solid-state microchip lasers with fast risetime and high peak power.
  
• 
  To develop solutions for efficient laser beam scanning, which can withstand vibrations and guarantee long lifetime, integrating microoptics and micromechanics.
  
• 
  To support the industrial evaluation of technologies for driver support functions, by a comparative assessment of the developed solution, and a review of application trends.
  

C.R.F. (Centro Ricerche Fiat) (I), LETI (CEA- Direction des Technologies Avancees) (F), Jenoptik Laserdiode (D), Magneti Marelli (I), Renault (F), CSEM (Centre Suisse d’Electronique et de Microtechnique) (CH).

• 
  Requirements and specifications on 77 GHz radar sensor for automotive CW/A applications, feasible w.r.t. users/drivers needs and expectation on function and price.
  

• 
  Technology, components, complete prototypes of radar sensor and vehicle system proven feasible w.r.t. requirements, functionality and volume production.
  

• 
  Evaluation results of prototype CW/A radar and system. Plans and results (functional, technological, collaborative) for industrialisation and commercial marketing of the developed CW/A radar.
  

INTACT will develop an intelligent vehicle rear light system capable of automatically controlling its brightness dependent on the environmental conditions and the state of the rear light lens which will also be fault tolerant related to lamp failures by incorporating dual role functions in each light source. This new generation of rear lights will be based on LED illumination technology with the intelligence an control being achieved by utilizing the latest integrated micro-systems combination with CAN communication as well as new innovations in the miniaturization of existing weather sensors.

• 
  Design of an intelligent rear light that can be marketed at an acceptable price to be fitted into a production car within a few years.
  
• 
  Utilising existing applications of microprocessor control, CAN communication and MOSFET technology to enable the control and intelligence requirements.
  
• 
  Research and model the characteristics of the physical weather variants that exist around the rear light which includes rain, fog, mist sunlight and dirt.
  
• 
  Miniaturisation of existing weather visibility sensors to enable them to be integrated into a final prototype rear light system.
  
• 
  Intelligent environmental sensor fusion including self-diagnosis of fault conditions.
  
• 
  High volume assembly of LEDs, sensors and microprocessor components into the rear light cluster.
  
• 
  LED light performance twice that of a conventional filament bulb to allow automatic brightness control.
  

The objective of the project is to demonstrate and implement smart microsystems for gas analysis and odour recognition based on state-of-the-art sensor technologies, data processing and analysis techniques.

The project will be strongly application driven and address two areas:

· domestic appliances (air cleaner) for gas detection (CO, NO_x, SO₂, HCHO)

· process and quality control in food industry applications (detection of off-flavours and volatile based raw material defects and product classification).
Objectives

· Design and development of thin-film semiconductor oxide gas sensors on a silicon substrate. Miniaturisation and high integration techniques will be used to achieve low production cost, large number of sensors per wafer and performance reproducibility.

· Specific development of a new generation of gas sensors by integrating them on the same chip, resulting in a monolithic multisensor array.

· Unique combination of expertise in process knowledge, sensor technology and data analysis for implementation of smart gas-odour detection microsystems.

· Advanced neural network algorithms for adaptivity, robustness of measurements and error-free analysis.

· Application of such gas detection microsystems into the next generation of domestic air cleaners of the Product Division of Philips DAP.

· Application of the odour recognition system to process (or quality) monitoring in the field of off-flavour and contaminant detection related to packaging.
Participants

LEP (F); DAP (NL); Nestec Ltd (CH); Microsens (CH); CSEM (CH); Neotronics Scientific (UK); IPC (D).
Contact Point Duration

Serge Gourrier 36 months from 01.12.95

Laboratoires d'Electronique PHILIPS S.A.S.

22 av. Descartes, BP 15,

F-94453 Limeil-Brevannes (France)
tel: +33 1 45 10 68 94

fax: +33 1 45 10 67 43

E-mail: gourrier@lep-philips.fr

EP 21428 SMOG

Smart Air Pollution Monitoring Network
Summary

A miniaturised air quality monitoring station for use in urban environments, capable of detecting a range of important air pollutant species (e.g. CO, NO_x, O₃), produced by road traffic, will be developed using a novel system architecture. The heart of the SMOG demonstrator will be an array of miniaturised silicon-integrated metal-oxide gas sensors that will allow a drastic reduction in volume and power consumption of the monitoring station. Selective detection of the individual target gases will be enabled by state-of-the-art pattern recognition techniques. To reduce dead volumes, the development of a miniaturised actuator system will constitute an important goal of the project.

· Substrate heater elements characterised by low power consumption, improved thermal and mechanical stability; membranes made of either amorphous or crystalline silicon carbide, or porous silicon, will be the core of the new advanced substrates.