Proceedings of the 1st iCC 1994 in Mainz (Germany)
| CAN Protocol Performance |
|---|
| Dr. K. Tindell, A. Burns (University of New York): Guaranteeing message latencies on CAN |
| Dr. L. Rauchhaupt (University of Magdeburg): Performance analysis of CAN-based systems |
| J. Charzinski (University of Stuttgart): Performance of the error detection mechanism in CAN |
| CAN Physical Layer |
|---|
| Dr. H. Beikirch, Dr. T. Schindler, Dr. L. Rauchhaupt (University of Magdeburg): Integrated power supply transmission for CAN |
| M. Rucks (Kabelwerke Reinshagen): Optical Layer for CAN |
| M. Clayton, A. Kreutzer (Texas Instruments): A robust CAN transceiver designed for the automotive enviroment |
| CAN Controller Chips 1 |
|---|
| K. Turski (NEC): A global time system for CAN-Networks |
| H. Müller (Siemens): Integrated and stand-alone CAN solutions for different application levels |
| C. Szydlowski (Intel): Tradeoffs between stand-alone and integrated CAN peripherals |
| CAN Industrial Applications 1 |
|---|
| N. Laurance (Ford): Connecting CAN-based networks to an MMS network |
| M. Jaeggi (Selectron): CAN in industrial applications |
| K. Rupp (FhG/IPA), O. Wurst (Putzmeister): Implementationof CAN system in truck-based aircraft washing system |
| Development and Verification Tools |
|---|
| E.-J. Heins (Philips Medical Systems): A real-time PC with iRMX for Windows controls medical system |
| Chr. Bräutigam (Softing): CAN tool requirements |
| F. Hartwich, E. Esch, M. Strugala (Robert Bosch): Modelling of the CAN protocol in C and VHDL |
| Open Systems 1 |
|---|
| J. Uphoff (i+ME), Prof. Dr. W. Lawrenz (FH Braunschweig/Wolfenbüttel): Theories and practical experience with CAL-based industrial control |
| W. Tabingh (Philips CFT): Linear servo motor for production equipment uses CAN and CAL |
| M. Rostan, Prof. Dr. G. Gruhler (STA Reutlingen): CAN real-time communication profile |
| CAN Controller Chips 2 |
|---|
| P. Buehring (Philips Semiconductors): A new generation of integrated circuits fpr CAN systems |
| M. Embacher (National Semiconductor): DC motor control in vehicle body applications |
| K.-T. Neumann, Ch.-E. Cordonnier (Motorola): Highly integrated cost-effective CAN |
| CAN Automotive Applications |
|---|
| Dr. K. W. Young, R. T. McLoughlin, S. B. Khoh (University of Warwick): Low-cost CAN-based body control system |
| Dr. P. Käkkäinen, M. Haataja (Oulu Institute of Technology), U. Niemelä (RoBosys Oy): SLIO-based data acquisition in testing brakes of trucks |
| G. Waizmann, F. Steinert, R. Wolters (Ontime Engineering): CAN-base for new applications in vehicles |
| Open System 2 |
|---|
| R. Crovella (Honeywell): A CAN protocol for plant floor control |
| D. Doonen, S. Siegel, P. Maloney (Allen-Bradley): DeviceNet application protocol |
| Prof. Dr. K. Etschberger (STZP): Modelling distributed application Processes with CAL |
| CAN Industrial Applications 2 |
|---|
| J. Dahlkemper, Dr. A. Langen (FhG/IPA): Sensor-based solutionsfor automation |
| Dr. C. Sommer, Dr. E. Sommer (Sommer Automation): Flexible manufacturing systems need CAN |
| J. Doran, J. Scannell, M. Harrington (Moog): A servodrive profile for CAN |
| CAN Industrial Applications 3 |
|---|
| Prof. Dr. R. Kroeger (Fachhochschule Wiesbaden): DIRECT: A basis for distributed real-time control applications |
| S. Bassem, P. Crohaert (ACT'L): Security system for workers in the HST Maintenance Building in Brussels |
| P. Priller (Mikron): A distributed control system using the CAN |
