Patient temperature and heartbeat rate monitoring system
First Claim
1. A patient temperature and heartbeat rate monitoring system comprising a plurality of transmitters one for each patient to be monitored, and a receiver,wherein each transmitter is comprised of sensor means for sensing patient temperature and heartbeat rate and for providing an actual temperature input which has a voltage level proportional to actual patient temperature, a reference temperature input which has a voltage level proportional to a predetermined reference temperatre, and a heartbeat rate input which has a frequency corresponding to heartbeat rate, low pass filter means coupled to said sensor means and receiving said heartbeat rate input for isolating an electrical heartbeat signal having a frequency equal to heartbeat rate, phase lock loop means for receiving said heartbeat signal and for providing a harmonic heartrate signal at a phase controlled frequency which is an upper harmonic of said heartbeat signal, multiplexing means coupled to receive said actual temperature input and said reference temperature input from said sensor means and coupled to receive said heartrate signal from said phase lock loop means, voltage controlled oscillator means coupled to provide an input and receive an output from said multiplexing means, frequency dividing means connecting to receive an input from said voltage controlled oscillator means through said multiplexing means and to provide an output to said multiplexing means, whereby said actual temperature input and said reference temperature input are provided by said sensor means to said voltage controlled oscillator means through said multiplexing means to produce a voltage controlled output signal of frequency proportional to voltage level, and said voltage controlled output signal is provided as an input to said frequency dividing means in sequence with said heartrate signal through said multiplexing means, and said frequency dividing means produces clock and data signals to said multiplexing means of frequency proportional to and stepped down from that of the existing input to said frequency dividing means to sequentially gate each of said voltage level inputs through said multiplexing means to said voltage controlled oscillator means, and said clock and data signals are sequentially at a frequency proportional to voltage level of said reference temperature input, voltage level of said actual temperature input and frequency of said heartbeat rate input, and modulating means for transforming said clock and data signals of said dividing means into radio frequency signals,and wherein said receiver is comprised of demodulating means for sensing said radio frequency signals and for reproducing said clock and data signals, and signal processing means for producing a visual display from said reproduced clock and data signals.
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Accused Products
Abstract
Hospital patient temperatures and heartbeat rates are monitored by providing each patient with a battery powered transmitter containing a reference resistance and to which two sensor electrodes are connected. The first electrode includes a thermistor and is positioned in thermal contact with the patient'"'"'s skin over the axillary artery. The second electrode is positioned in contact with the patient'"'"'s skin proximate to the fourth intercostal left parasternal area of the patient'"'"'s chest. A receiver, carried by a nurse, includes a magnetic actuator for closing a reed switch in a transmitter unit to activate the generation of data signals from that transmitter. The transmitter, when actuated provides an output of modulated, sequential data signals. The data signals are of a duration corresponding to a reference temperature, actual patient temperature, transmitter battery level, and patient heartbeat rate. The receiver includes demodulator circuitry and a microprocessor to provide numerical indicia quantitatively indicative of actual patient temperature and heartbeat rate. The microprocessor compares the demodulated data signals to allowable limits associated with each signal.
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Citations
12 Claims
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1. A patient temperature and heartbeat rate monitoring system comprising a plurality of transmitters one for each patient to be monitored, and a receiver,
wherein each transmitter is comprised of sensor means for sensing patient temperature and heartbeat rate and for providing an actual temperature input which has a voltage level proportional to actual patient temperature, a reference temperature input which has a voltage level proportional to a predetermined reference temperatre, and a heartbeat rate input which has a frequency corresponding to heartbeat rate, low pass filter means coupled to said sensor means and receiving said heartbeat rate input for isolating an electrical heartbeat signal having a frequency equal to heartbeat rate, phase lock loop means for receiving said heartbeat signal and for providing a harmonic heartrate signal at a phase controlled frequency which is an upper harmonic of said heartbeat signal, multiplexing means coupled to receive said actual temperature input and said reference temperature input from said sensor means and coupled to receive said heartrate signal from said phase lock loop means, voltage controlled oscillator means coupled to provide an input and receive an output from said multiplexing means, frequency dividing means connecting to receive an input from said voltage controlled oscillator means through said multiplexing means and to provide an output to said multiplexing means, whereby said actual temperature input and said reference temperature input are provided by said sensor means to said voltage controlled oscillator means through said multiplexing means to produce a voltage controlled output signal of frequency proportional to voltage level, and said voltage controlled output signal is provided as an input to said frequency dividing means in sequence with said heartrate signal through said multiplexing means, and said frequency dividing means produces clock and data signals to said multiplexing means of frequency proportional to and stepped down from that of the existing input to said frequency dividing means to sequentially gate each of said voltage level inputs through said multiplexing means to said voltage controlled oscillator means, and said clock and data signals are sequentially at a frequency proportional to voltage level of said reference temperature input, voltage level of said actual temperature input and frequency of said heartbeat rate input, and modulating means for transforming said clock and data signals of said dividing means into radio frequency signals, and wherein said receiver is comprised of demodulating means for sensing said radio frequency signals and for reproducing said clock and data signals, and signal processing means for producing a visual display from said reproduced clock and data signals.
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2. A patient temperture and heartbeat rate monitoring system comprising a plurality of transmitters, one associated with each patient to be monitored, and a receiver,
each transmitter comprising: -
reference temperature resistor means, a first electrode for securement to the skin of a patient to be monitored in electrical contact therewith, a thermistor mounted on said first electrode adapted to be in thermal contact with the skin of said patient, a second electrode for securement to the skin of said patient, means for applying voltage to said reference temperature resistor means to produce a reference temperature input which is at a voltage level proportional to the value of said reference temperature resistor means and for applying voltage and to said thermistor to produce an actual temperature input which is at a voltage level proportional to the temperature of said patient, means connected to said first and second electrodes for monitoring voltage differential therebetween and for producing heartbeat signals at a frequency proportional to the heartbeat rate of said patient as a heartbeat rate input, transducer means comprised of low pass filter means coupled to said means for monitoring voltage differential between said first and second electrodes for isolating an electrical heartbeat signal having a frequency equal to heartbeat rate, phase lock loop means for receiving said heartbeat signal and for providing a harmonic heartrate signal at a phase controlled frequency which is an upper harmonic of said heatbeat signal, multiplexing means, voltage controlled oscillator means coupled to provide an input to and receive an output from said multiplexing means, and frequencey dividing means connected to receive an input from said voltage controlled oscillator means through said multiplexing means and to provide an output to said multiplexing means, whereby said voltage levels of said reference temperature input and said actual temperature input are provided by said reference temperature resistor means and said thermistor to said voltage controlled oscillator means through said multiplexing means to produce a voltage controlled output signal of frequency proportional to voltage level, and said voltage controlled output signal is provided as an input to said frequency dividing means through said multiplexing means, and said heartrate signal is also provided as an input to said frequency dividing means through said multiplexing means, and said frequency dividing means produces a clock output to said multiplexing means for frequency proportional to and stepped down from that of the existing input to said frequency dividing means to sequentially gate said reference temperature input and said actual temperature input through said multiplexing means to said voltage controlled oscillator means, and said clock output is also connected to said multiplexing means to sequentially gate said output signal and said heartrate signal through said multiplexing means to said frequency dividing means, and modulating means for receiving said clock output from said frequency dividing means to modulate a carrier signal to generate radio signals corresponding to said reference temperature, actual temperature and patient heartbeat rate, said receiver comprising; demodulating means for demodulating said radio signals to produce data signals corresponding to said reference temperature, actual temperature and heartbeat rate, and signal processing means for converting said data signals to indicia indicative of patient temperature and heartbeat rate. - View Dependent Claims (9, 10, 11, 12)
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3. A patient temperature and heartbeat rate monitoring system comprising a plurality of transmitters, one associated with each patient to be monitored, and a receiver,
each transmitter comprising: -
reference temperature resistor means, a first electrode for securement to the skin of a patient to be monitored in electrical contact therewith, a thermistor mounted on said first electrode in thermal contact with the skin of said patient, a second electrode for securement to the skin of said patient, means for applying voltage to said reference temperature resistor means to produce a reference temperature input which is at a voltage level proportional to the value of said reference temperature resistor means and for applying voltage to said thermistor to produce an actual temperature input which is at a voltage level proportional to the temperature of said patient, means connected to said first and second electrodes for monitoring voltage differential therebetween and for producing heartbeat signals at a frequency proportional to the heartbeat rate of said patient as a heartbeat rate input, transducer means comprising low pass filter means coupled to said means for monitoring voltage differential between said first and second electrodes for isolating an electrical heartbeat signal having a frequency equal to heartbeat rate, phase lock loop means for receiving said heartbeat signal and for providing a harmonic heartrate signal at a phase controlled frequency which is an upper harmonic of said heartbeat signal, multiplexing means, voltage controlled oscillator means coupled to provide an input to and receive an output from said multiplexing means, and frequency dividing means connected to receive an input from said voltage controlled oscillator means through said multiplexing means and to provide an output to said multiplexing means, whereby said voltage levels of said reference temperature input and said actual temperature input are provided by said reference temperature resistor means and said thermistor to said voltage controlled oscillator means through said multiplexing means to produce a voltage controlled output signal of frequency proportional to voltage level, and said voltage controlled output signal is provided as an input to said frequency dividing means through said multiplexing means, and said heartrate signal is also provided as an input to said frequency dividing means through said multiplexing means, and said frequency dividing means produces a clock output to said multiplexing means of frequency proportional to and stepped down from that of the existing input to said frequency dividing means to sequentially gate said reference temperature input and said actual temperature input through said multiplexing means to said voltage controlled oscillator means, and said clock output is also connected to said multiplexing means to sequentially gate said voltage controlled output signal and said heartrate signal through said multiplexing means to said frequency dividing means and, modulating means for receiving said clock output from said frequency dividing means to modulate a carrier signal to generate radio signals corresponding to said reference temperature actual temperature and patient heartbeat rate, said receiver comprising; demodulating means for demodulating said radio signals to produce envelope signals corresponding to said reference temperature, actual temperature and patient heartbeat rate, and microprocessor means coupled to receive inputs from said demodulating means to convert said envelope signals to numeric data signals indicative of patient temperature and heartbeat rate. - View Dependent Claims (4, 5)
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Specification