AN206

AN206 Vishay Siliconix DG406 Multiplexer Optimizes Medical Simulator Introduction A patient monitoring system collects information from several transducers connected to a patient. The transducers convert physiologic electromechanical activity into electrical signals which are routed to a data acquisition module for digitization. The digitized data is then processed and displayed on the monitor screen. Additionally, bedside patient information can be relayed to a central nursing station, a hospital information system, or a doctor’s office. Patient monitors must provide reliable data at all times. For this reason, it is imperative to have an accurate means for calibration and troubleshooting of patient monitoring instrumentation. This function can be accomplished by using a patient simulator which generates electrical signals similar to those produced by the transducers. For this application note, a patient simulator was designed and built. The simulator consisted of a personal computer peripheral device and had to be capable of producing the static display of all numerics and graphics associated with the following three human parameters: a) body temperature, b) blood oxygen saturation level, c) heart pulse rate. Having these capabilities greatly enhances the ability to perform fine calibration and troubleshooting. Performance Goals The simulator design goals were as follows: a) b) c) Body temperature: from –1_C to 46_C in 0.1_C increments, with an accuracy of "0.1_C. Blood oxygen saturation level: sixteen independent values in the range of 60% to 100%. Heart pulse rate: fifteen independent values in the range of 30 to 300 pulses/min. Theory of Operation The commands to modify the simulated parameters are sent from a PC over an RS-232 line to the peripheral device. A microcontroller containing a UART receives these commands as 8-bit frames and processes the data. After processing, the microcontroller uses its I/O port bits to send data to the parameter generation hardware. The parameter’s signal is modified as specified by the down-loaded command. The modified signals are then output to the patient monitor to produce the appropriate visual displays. Central Nursing Station Bedside Monitor Network Controller Doctor’s Office PC From Patient FIGURE 1. A Typical Medical Information System Document Number: 70604 10-Aug-99 www.vishay.com S FaxBack 408-970-5600 6-1 AN206 Vishay Siliconix PC Temperature RS-232 Micro Controller Oxygen Saturation To Patient Monitor Pulse Rate FIGURE 2. Patient Simulator Block Diagram Design Considerations The temperature parameter was simulated by using a discrete resistor array and a pair of analog multiplexers as illustrated in Figure 3. A discrete resistor value representing a known temperature was placed between the same channel of two analog multiplexers. Using its I/O lines, the microcontroller simultaneously selects one of the 16 resistors. A know current is sent through the resistor. The medical monitor reads the voltage drop across the resistor and translates it into a temperature reading. Since rDS(on) affects the output voltage, in order to obtain accurate results, it was necessary to use the multiplexers with a low on-channel resistance. The temperature simulation section of the design utilized the DG406, a 16-channel multiplexer manufactured by Vishay Siliconix. Thus, it was possible to simulate 16 discrete temperatures by using a pair of multiplexers. The DG406 was ultimately chosen for its low rDS(on) of approximately 40 W typical. This value was measured and confirmed several times. To get the best results possible, lower resistor values were used and a digital potentionmeter array was used to get the exact resistance required including the 40-W rDS(on). Simulating the saturated oxygen level was accomplished utilizing another DG406 multiplexer. An analog signal was sent through the selected channel of the multiplexer and attenuated in a predetermined manner. The resulting signal is then output to the medical patient monitor modifying the saturated oxygen parameter. Again an array of digital pots was used to compensate for the already low on-resistance and to get the exact resistance values desired. R1 Digital Pots R2 VOUT to Monitor I R16 DG406 DG406 From mC FIGURE 3. Temperature Simulation Circuit www.vishay.com S FaxBack 408-970-5600 Document Number: 70604 10-Aug-99 6-2 AN206 Vishay Siliconix R17 R18 VREF Programmable VOUT to Monitor From mC Counter Frequency Out to Monitor R32 Clock DG406 From mC FIGURE 4. Saturated Oxygen Simulation Circuit FIGURE 5. Pulse Rate Simulator The pulse rate parameter was simulated by varying the frequency of a square wave obtained from a programmable timer/counter. The timer/counter was programmed using some of the microcontroller I/O lines. The square wave frequency represents the patient’s pulse rate. Although this design used lower resistor values and digital pots to compensate for the rDS(on), this may not be necessary in other less sensitive designs. The critical components in this design were the microncontroller for its speed and numerous on-board devices, the analog multiplexer for its low rDS(on), and the digital potentionmeters. Considerable time was spent shopping around for these three devices. Viewing from the better than expected results of the overall design, it is obvious that the time spent in search of these devices was well worth it. Conclusion The finished simulator met all design goals. The DG406 worked as documented in the Vishay Siliconix data book. Document Number: 70604 10-Aug-99 www.vishay.com S FaxBack 408-970-5600 6-3