CA2288061C - Microprocessor based bed patient monitor - Google Patents

Abstract

This invention relates generally to monitoring sys- tems and more particularly concerns devices and systems used to monitor patients lying in hospital beds or in other care giving environments. According to a first aspect of the instant invention, a microprocessor based patient mon- itor is disclosed which includes a loudspeaker driven by a power amplifier responsive to an input signal derived from a programmable volume control. The microproces- sor synthesizes any one of multiple alarm sounds under software control, operates the programmable volume con- trol of the alarm system and activates and deactivates the alarm in response to the electronic signals received from the sensor and a user interface. An electrically erasable programmable read-only memory accessible by the pro- cessor stores data which can be modified to tailor the op- erations of the monitor to suit a variety of different needs. According to still another aspect of the instant invention, a microprocessor-based patient monitor is disclosed which has a personality that is defined by software that is res- ident in modifiable nonvolatile memory, which software can thus be altered to change the programmed responses of the monitor. Finally, a software and hardware system is provided for reading information from and writing in- formation to modifiable nonvolatile RAM within a micro- processor-based patient monitor. This information might be parameter settings, data values, or computer instruc- tions.

Description

MICROPROCESSOR HASED BED PATIENT MONITOR
BACKGROUND OF THE INVENTION
This invention relates generally to monitoring systems and more particularly concerns devices and systems used to monitor bed patients i_n hospital or other care giving environments.
It is well do~~umented that the elderly and post-surgical patients are at a heightened risk of falling. There are many reasons for thi:~ but, broadly speaking, these individuals are often afi=:Licted by gait and balance disorders, weakness, dizziness, coni-usion, visual impairment, and postural hypotension (i.e., a sudden drop in blood pressure that causes dizziness and fainting), all of which are recognized as potential contributors to a fall. Additionally, cognitive and functional impairment, arid sedating and psychoactive medications are also wel:L recognized risk factors.
A fall place~;the patient at risk of various injuries including sprains, frac:t,.zres, and broken bones - injuries which in some cases can be severe enough to eventually lead to a fatality. Of course, those most susceptible to falls are often those in the poorest general health and least likely to recover quickly from their injuries. In addition to the obvious physiological consequences of fall-related injuries, there are also a variety of adverse economic and legal consequences that include the actual cost: of treating the victim and, in some cases, caretaker liabi7..ity issues.
In t=he past, it has been commonplace to treat patients that are prone to falling by limiting their mobility through the use of restraints, the underlying theory being that if the patient is not free to move about, he or she will not be as likely to :fall. However, research has shown that restraint-based patient treatment.;~trategies are often more harmful than beneficial and should generally be avoided - the emphasis today being on the promotion of mobility rather than immobility.
Among the more successful mobility-based strategies for fall prevention include interventions to improve patient strength and functiona7_ status, reduction of environmental hazards, and staff identification and monitoring of high-risk hospital patients and nursing home residents.
Of course, mcmitoring high-risk patients, as effective as that care strategy might appear to be in theory, suffers from the abvious practical disadvantage of requiring additional staff if the monitoring is to be in the form of direct observation. Thus, the trend in patient monitoring has been toward the use of electrical devices to signal changes in a patient' s c:ircumstan<::e too a caregiver who might be located either nearby or remotely at a central monitoring facility, such as a nurse's station. The obvious advantage of an electronic monitoring a:rrrangement :is that it frees the caregiver to pursue other tasks away from the patient.
Additionally, when the rr;onitoring is done at a central facility a single nurse can mon.itc>r multiple patients which can result in decreased staffing :requirements.
Generally speaking, electronic monitors work by first sensing an initial stat~u.s of a patient, and then generating a signal when that status changes, e.g., he or she has sat up in bed, left the bed, riserG from a chair, etc., any of which situations could pose a potential cause for concern in the case of an at-risk patient. Electronic bed <~nd chair monitors typically use a pressure sensitive switch in combination with a separate monitor/micropz~ocessor. In a common arrangement, a patient's weight restizlct on a pressure sensitive mat (i.e., a "sensor" mat) completes an electrical circuit, thereby signalling the presence of the patient to the microprocessor.

When the weight is remc>vc=_d from the pressure sensitive switch, the electrical. circuit i;~ interrupted, which fact is sensed by the microprocessor. Th.e software logic that drives the monitor is typically programmeci. to respond to the now-opened circuit by triggering some sort of: alarm-either electronically (e.g., to the nursing station via a conventional nurse call system) or audibly (via a built-ire si.ren). Some examples of devices that operate in this general- fashion may be found in U.S. Letters Patent Nos. 4,484,043, 4,565,91.0, 5,554,835, and 5,634,760.
That. being said, patient monitoring systems that rely on sensor mat; to detect the presence of a patient in a bed suffer from a variety c:~f drawbacks. For example, the bed monitoring sy;~tems curi:~ently available in the marketplace feature externally accessible configuration switches that allow the caregiver to reconfigure the device at will and to adjust parameters such as the duration of the alarm, and the time lapse between the sensing of the "empty bed" condition and the sounding of an alarm. External switching makes tampering with the system exl~remely easy and makes it more difficult to establish and maintain a hospital-wide policy with respect to monitor settings.
A further problem with conventional bed monitoring systems is that they use oscillating transducers in their alarm audio circuits, resulting in single frequency audio alarms.
Since bed monitor alarms are frequently employed in environments in which <:~ mu:Ltiplicity of other problems might also trigger audio ala:r_rris, if the single alarm sound provided by the bed monitor happens to be similar to one or more other alarm sounds heard in :response to different monitors, confusion and consequential lengthened response times to patient monitor alarms may result.
2a Those skilled in the art know that there are many nurse call station configurations and it is to the economic advantage of a manufact~.zrer to be able to accommodate all of them. However, another problem with the present state-of-the-art in bed monitoring sy~;tems is that they are typically pre-configured internally at t;he factory for one particular type of nurse call station. Thug>, if the unit is misconfigured when it arrives at an installation, it may be necessary 2b to summon a medical technician to reconfigure it, since internal modifications to the unit are required to adapt it to different call station types. This can result in additional expense and delay in getting the unit correctly configured and into operation. Further, there are many hospitals that use multiple incompatible nurse call system types, each having been separately added as a new building or wing was constructed. The inability to quickly and reliable move electronic monitors between these systems means that the hospital will generally be required to maintain excess inventory of each type of compatible monitor, a result that ultimately adds to the health care costs borne by the consumer / patient.
Still another failure in known bed monitoring systems is that they do not provide a method of accumulating statistical data relating to the operation of the unit including, for example, the response times of the caregiver to alarm conditions. This sort of information could be very helpful to the maintenance and proper operation of the monitor, and for caregiver quality control purposes.
It is, therefore, a primary object of this invention to provide a patient monitor that is microprocessor-based so as to be reconfigurable by the uploading of configuration data to an electronically erasable programmable read only memory accessible by the microprocessor. A
further object of this invention is to provide a microprocessor based patient monitor which synthesizes multiple alarm sounds in software for selection by the caregiver.
It is also an object of this invention to provide a microprocessor based patient monitor having a nurse call interface allowing interconnection with any nurse call station without modification of the monitor. Yet another object of this invention is to provide a microprocessor based patient monitor having an electrically erasable programmable read only memory accessible by the microprocessor for logging statistical data with respect to the use of the monitor and the response time of the caregiver using the monitor. Another object of this invention is to provide a microprocessor based bed patient monitor which permits the downloading of the logged statistical data to a host microprocessor connected to the system. It is still another object of the instant invention to provide a system for configuration of monitor parameters and for recalling and analyzing statistical data accumulated therein.
Heretofore, as is well known in the bed monitor arts, there has been a need for an invention to address and solve the above-described problems. Accordingly, it should now be recognized, as was recognized by the present inventor, that there exists, and has existed for some time, a very real need for a electronic patient monitor that would address and solve the above-described problems.
Before proceeding to a description of the present invention, however, it should be noted and remembered that the description of the invention which follows, together with the accompanying drawings, should not be construed as limiting the invention to the examples (or preferred embodiments) shown and described. This is so because those skilled in the art to which the invention pertains will be able to devise other forms of this invention within the ambit of the appended claims.

SUMMARY OF THE INVENTION
In a;.cordance with the invention, a patient monitor is provided in which a processor receiving electronic signals from a sensor indicatin~_~ t:he presence on the sensor and absence from the sensor of a patient is combined with an alarm system which includes a loudspeaker driven by a power amplifier which responds to an input si:~rLal derived from a programmable volume control to produce an aural alarm. The processor synthesizes at least one and preferably multiple alarm sounds under software control, operates the programmable volume control of the alarm system to selec:t~ the decibel level of the alarm and activates and deactivate: the alarm in response to the electronic signals received from the sensor and a user interface. Preferably, an electrically erasable programmable read-only memcry accessib_Le by the processor stores a plurality of alarm sounds for seleci~ion by the processor for synthesis of the selected alarm sound. In addition, the electrically erasable programmable recto-only memory may store multiple decibel levels for select. ion by the processor of the desired decibel level of the alarm sound. In the preferred embodiment, the patient monitor will be used tc sense the presence of patient who is lying in a bed, however, it should be noted and remembered this monitor could also be used in other sorts of applications, including with chair and toilet monitors.
Preferably, the electrically erasable programmable read-only memory also permits storage of a plurality of options for the delay time betwe~=n initiation of the absence of a patient from t:he sensor arid the activation of the alarm by the processor. Furthermore, the monitor is preferably provided with an external switch connected to the processor for caregiver selection of the delay time from the plurality of delay time options.
It is also preferred that the electrically erasable programmable read-only memory log usage data with respect to the monitor including the total hours of use of the monitor, the total time of alarms sounded by the monitor, the total number of alarms sounded by the monitor and the response time between the most recent ~~ounding of an alarm and a subsequent operation of the monitor by the caregiver. The monitor will include a port for downloading the log usage data to a host computer.
The monitor al:~o includes a nurse call interface having a relay which is energized when the power amplifier is de-energized and which has a normally opened contact, a normally closed contact <~n.d a common contact for interconnecting the monitor to a nurse call system to one of the normally opened and normally closed contacts so that the monitor requires no modi:Eication to accommodate the type of nurse call station with which the monitor is used.
According to still another aspect of the instant invention, there is provided a bed monitor/computer system which allows easy on-site configuration of a monitor to work with different: nurses stations. In more particular, the monitor of the instant invention is designed to be reconfigured through the u:~e of a host computer, which obviates the need for internal modif=ications of monitor parameters through the use of dip switches, rotary dials, etc., which 5a are commonly used in the industry. In the preferred embodiment, a standard computer interface, such as serial interface, is provided as a means for communication between the monitor and a separate host computer. This allows the unit to be readily reprogrammed without risking the exposure of the internal electronic components to the environment.
According to still a further aspect of the instant invention, there is provided a software system for providing the monitor with nevi programming instructions or a new "personality"
which will enable it to operate with potentially any plug-compatible nurse call station. In the preferred embodiment, the internal operating logic and various parameters which change the operation of the device to match a particular nurse call station are preferably stored in nonvolatile flash-type RAM which is RAM that can be modified on demand through the use of a host computer-to-patient monitor transfer. One obvious advantage of this arrangement is that it eliminates the many problems associated with mechanical configuration switches, such as dip switches and rotary dials, while providing an easy, inexpensive, and reliable way of upgrading or otherwise modifying the functionality of a monitor while it is in the field.
The foregoing has outlined in broad terms the more important features of the invention disclosed herein so that the detailed description that follows may be more clearly understood, and so that the contribution of the instant inventor to the art may be better appreciated. The instant invention is not to be limited in its application to the details of the construction and to the arrangements of the components set forth in the following description or illustrated in the drawings. Rather, the invention is capable of other embodiments and of being practiced and carried out in various other ways not specifically enumerated herein.
Additionally, the disclosure that follows is intended to cover all alternatives, modifications and equivalents as may be included within the spirit and scope of the invention as defined by the appended claims.
Further, it should be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting, unless the specification specifically so limits the invention.
While the instant invention will be described in connection with a preferred embodiment, it will be understood that it is not intended to limit the invention to that embodiment. On the contrary, it is intended to cover all alternatives, modifications and equivalents as may be included within the spirit and scope of the invention as defined by the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS
Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
Figure 1 is a block diagram illustrating a preferred embodiment of the monitor;
Figure 2 is a schematic diagram illustrating a portion of a preferred embodiment of the processor of the monitor;
Figure 3 is a schematic diagram illustrating a portion of a preferred embodiment of the processor of the monitor;
Figure 4 is a schematic diagram illustrating a preferred embodiment of the user interface of the monitor;
Figure 5 is a schematic diagram illustrating a preferred embodiment of the audio section of the monitor;
Figure 6 is a schematic diagram illustrating a preferred embodiment of the signal condition circuit of the monitor;
Figure 7 is a schematic diagram illustrating a preferred embodiment of the non-volatile memory of the monitor;
Figure 8 is a schematic diagram illustrating a preferred embodiment of the nurse call interface of the monitor;
Figure 9 is a schematic diagram of a preferred embodiment of the power supply of the monitor;
Figure 10 is a flow diagram illustrating a preferred embodiment of a cold start routine of the monitor;
Figure 11 is a flow diagram illustrating a preferred embodiment of the executive routine of the monitor;
Figure 12 is a flow diagram illustrating a preferred embodiment of the hold mode routine of the monitor;
Figure 13 is a flow diagram illustrating a preferred embodiment of the monitor routine of the monitor;
Figure 14 is a flow diagram illustrating a preferred embodiment of a portion of the alarm mode of the monitor;
Figure 15 is a flow diagram of another portion of the alarm mode routine of the monitor;
Figure 16 is a flow diagram illustrating a portion of a preferred embodiment of the program mode of the monitor;
Figure 17 is a flow diagram illustrating a portion of a preferred embodiment of the program mode of the monitor;

Figure 18 is a flow diagram illustrating a portion of a preferred embodiment of the program mode of the monitor;
Figure 19 is a flow diagram illustrating a preferred embodiment of the data logger subroutine of the monitor; and Figure 20 is a flow diagram illustrating a preferred embodiment of the pull-out protection subroutine of the monitor.
Figure 21 contains an illustration of the general environment of the instant invention, wherein a host computer is connected to the monitor for purposes of data transfer.
Figure 22 illustrates the main hardware elements of the reprogrammable monitor embodiment.
Figure 23 contains a flow chart that illustrates the principle computer steps in the personality loading routine.
Figure 24 is a flow chart of the principle steps in the parameter recall routine, wherein data is passed from the monitor to the host CPU.

DETAILED DESCRIPTION OF THE INVENTION
Microprocessor-Based Patient Monitor According to a first aspect of the instant invention, there is provided a microprocessor based patient monitor that offers improved functionality in comparison with known control units by introducing added features and improvements in the intuitiveness of the operation. As is illustrated in Figure 1, a preferred embodiment of the instant monitor hardware has seven functional blocks including a processor 10, a user interface 40, an audio section 70, a signal conditioning circuit 100, a non-volatile memory 130, a nurse call interface 160 and a power supply 190.
As is made clear in Figure 1, the microprocessor 10 is responsible for various functions within the monitor including managing its user interface 40, communicating with the nurse call interface 160, and controlling the signal condition circuit 100 /
audio section 70.
Additionally, the processor 10 is able to retrieve from and store to non-volatile memory 130 as needed.
As shown in Figures 2 and 3, the processor 10 includes a microcontroller 11, a latching display driver 13 and a latch 15. Since the microcontroller 11 is synthesizing the alarm sound in software, it is important to run the microcontroiler 11 at its maximum operating speed. The microcontroller 11 preferably has fourteen general purpose I/O pins grouped into a port A and a port B and one interrupt request input IRQ. The pins of the microcontroller 11 are preferably utilized as follows:
Port A Bit 0: via a multifunction bus 17 to D1 of the latch 15, AIN of the latching display driver 13, INC of a volume control 71 in the audio section 70, via a diode 25 to Ull l of the user interface 40 and via a resistor R1 to VCC;
Port A Bit 1: via the multifunction bus 17 to D2 of the latch 15, B IN of the latching display device 13 and U/D of the volume control 71, via a diode 27 to UI12 of the user interface and via a resistor R2 to VCC;
Port A Bit 2: via the multifunction bus 17 to D3 of the latch 15 and CIN of the latching display driver 13;
Port A Bit : via the multifunction bus 17 to D4 of the latch 15 and DIN of the latching display driver 13;
Port A Bit 4: to Key Input Enable of the user interface 40;
Port A Bit 5: via the multifunction bus 17 to D6 of the latch 15;
Port A Bit 6: to LE of the latching display driver 13;
Port A Bit 7: to CLK of the latch 15;

Port B Bit 0: to SDA of the non-volatile memory 130 (EEPROM Data), via a resistor R3 to VCC and the power supply 190;
Port B Bit l: to SCL of the non volatile memory 130 (EEPROM clock), via a resistor R6 to VCC and the power supply 190;
Port B Bit 2: to the nurse call interface 160 (pull out detection);

Port B Bit 3: to CS of the volume control 71 (volume);

Port B Bit 4: to VH of the volume control 71 (audio out);

Port B Bit 5: to the signal condition circuit 100 (mat detection);

IRQ: (Interrupt Request) to the signal condition circuit 100 (mat input);

Reset: to VCC through the time delay R13/C13; and OSCI & OSC2: to the master clock for the microcontroller 11.
Additionally, the remaining pins of the latching display driver 13 are preferably used as follows:
Aov.i.: Via a resistor R4 to UI1 of the user interface 40;
BoU.I.: Via a resistor RS to UI2 of the user interface 40;
CoU.i.: Via a resistor R~ to UI3 of the user interface 40;
Do~: Via a resistor Rg to UI4 of the user interface 40;
EoU.i.: Via a resistor Rlo to UIS of the user interface 40;
FoU.I.: Via a resistor R11 to UI6 of the user interface 40 ;
GoU.i.: Via a resistor R12 to UI7 of the user interface 40; and LT and B 1: to VCC
The remaining pins of the latch 15 are preferably used as follows:
Q1: via a resistor R14 to UI8 of the user interface 40;
Q2: via a resistor Rls to UI9 of the user interface 40;
Q3: via a resistor RZ6 to UI10 of the user interface 40;
Q4: to the nurse call interface 160;
Q5: unused;
Q6: to the nurse call interface 160; and DS and CLR: to VCC.
The multifunction bus 17 to D1, 2, 3, 4 and 6 of the latch 15 capitalizes on the bidirectional feature of the microcontroller 11 to create a Iocal data bus.
This allows the associated pins PAO, 1, :?, 3 and 5 of the microcontroller 11 to be used for several functions, reducing the total number of I/0 pins required and allowing for a smaller, less expensive microcontroller 11 to be used. The multifunction bus 17 sources information for a numeric display 41 via the latching display driver 13, selects annunciators 43 to be illuminated via the latch 15, energizes the nurse call relay K1 via the latch 15, prc>vides up/down information for the programmable volume control 71 and i~aputs the status of the keypad 45.
1C Operation of the multifunction bus 17 is purely under software control. The microcor~t=roller 11 contains internal RAM 19, EPROM 21, and a 'timer 2:3. One suitable hardware choice for the microcontroll.er 11 is a Motorola* MC68HC705J2, the latching display driver 13 is a Motorola 74HC4511 and the latch 15 is a lc~ Motorola 74HC174.
A resistor R.13 and capacitor C13 connected between the power source VCC and the RESET port of the microcontroller 11 provide time delay at initialization and a typical clock circuit is connected t:o the OSC1 and OSC2 ports of the 20 microcontroller 11.
Turning to Figure 4, the user interface 40 preferably consists of the numeric display 41, an annunciator bank 43 including a HOLD annunciator 47, a MON annunciator 49 and an ALARM annunciator 51 and the keypad 45 including a reset switch 25 53 and a delay adjust switch 55. Needless to say, many other arrangements of the cc:>ntr_ol switches and displays are possible and are well within the capability of one of ordinary skill in the art to devise.
The numeric display 41 is a seven segment display 3c) driven by the latching display driver 13. The preferred *Trade-mark takes Binary Coded Decimal (BCD) in and decodes it into the appropriate segments to display the desired number. The BCD
input is provided by D1--D4 of the multifunction bus 17. The information is latched into the latching display driver 13 by Port A Bit 6. The latching operation frees up the multifunction bus 17 for other purposes while maintaining a stable display. The latching display driver 13 provides a blanking function, a tot=ally dark display, by writing a number greater than nine to the BCD input. Four bits of data provide 16 possible combination: (0-15), while only ten combinations are defined in BCD (0-9;. The other six combinations (10-15) result in turning off a_I_:1 of the display segments. The numeric display 41 is used to display the seconds of delay which precede an alarm in ncrmal operation of the monitor. In addition, the display 4.L is used to show selected options during the local prograrncning mode, as is hereinafter further described in relation to the monitor' software. All three annunciators, 43, 45 and 47, are LED's driven by the latching display driver 13. The preferred latching display driver 13, a Motorola 74HC'4511, is c<~pable of sourcing 20 milliamps per output 50. No additional drive is necessary to each LED. The driver 13 has a hex latch (six individual D flip/flops with a common clock line). On:L:y~ five latch outputs are implemented and one of those is ur_u:~ed in the current software. Ql through Q3 are used for the annunciators 47, 49 and 51, respectively.
By using a latch 15 with sufficient drive capability, the latching display driver 13 provides the source current to illuminate each LED arad also latches the data so that the annunciators 43, 45 arid 47 remain stable while the 3C multifunction bus 17 i.s used for other purposes. To turn on a particular annunciator 47, 49 or 51, the processor 10 raises the appropriate b.it of t:he multifunction bus 17, D1 for ALARM
47, D2 for MON 49 or D3 for HOLD 51, and then toggles Port A
Bit 7 to latch the data. Operating characteristics for each mode are hereinafter de:~cribed in relation to the monitor software. The reset sw~_t=ch 53 and delay adjust switch 55 are inputted to the processor 10 on bits D1 and D2 of the multifunction bus 17. ':~,he two switches 53 and 55 share a common select line so a read of either switch 53 or 55 always reads both switches 53 and 55. To accomplish a read, the processor 10 must make F?ort A Bit 0 and Port A Bit 1 inputs.
The switches 53 and 55 are then read by taking Port A Bit 4 low. The two inputs are pulled up by resistors R1 and R2 and these two bits may be ;pu=Lled low through diodes D1 and D2 respectively. This can only happen if the appropriate switch 53 or 55 is closed and the key enable line is low.
Looking now at. Figure 5, the audio section 70 consists of a programmable volume control 71, a power amplifier 73 and a loudspeaker 75.. The audio is a single bit square wave generated by the proces:~or 10 under software control. The audio signal is divided too the requested volume by the programmable volume co:nt~rol 71, the power amplified to a sufficient level to drive the loudspeaker 75, and converted to audio by the loudspeaker_ 75.
The volume control 71 is preferably a Xicor Corporation* X9314 digital potentiometer. This integrated circuit performs the same function as a potentiometer except the wiper position VW i:~ digitally positioned to any one of 32, (i.e., 0-31) possible steps. The circuit is designed such that position zero corresponds to a minimum volume (no sound) and position 31 is maximum. volume. To control the volume chip *Trade-mark 12a select CS, which is connected to VCC via a pull-up resistor R32, is set low (Port D F3it 3), the up-down pin U/D (mfb D1) is set low to reduce volume or high to increase volume, and the increment-decrement INC pin (mfb DO) is toggled the appropriate number of times to reach the new wiper position.
The multifunction bus 17 is used for the U/D control and for the INC control :since these signals have no effect on the chip in the absence of a valid chip select signal.
Therefore, using mfb Dl and mfb D2 will not effect the volume when used for other purposes and the chip select signal (active low) is high. The output. o.f the programmable volume control 71 is AC coupled by a resi:~t=or R33 and capacitor C5 and directed to the input of the audio power amplifier 73.
The power amp7_ifier is preferably a National Semiconductor* LM388 audio amplifier which has adequate drive for the required volume levels and requires relatively few discrete components to produce a viable audio amplifier. It is used in its simplest configuration and *Trade-mark 12b directly drives the unit's loudspeaker 75. It preferably has a fixed gain of 20 and a resistor R26 scales the audio appropriately for the desired maximum output level.
The loudspeaker 75 is preferably a simple two inch polycone speaker. However, it should be noted that other arrangements are certainly possible and it is within the ordinary skill of in the art to devise. By way of example only, the loudspeaker element might be a piezoelectric device capable of generating an audible alarm signal. Thus, when the term "loudspeaker" is used hereinafter, that term should be construed in the broadest possible sense to include any device capable of emitting an audible alarm signal under the control of the microprocessor 10. Additionally, when loudspeaker is used herein that term should also be taken to include an associated power amplifier, if one is necessary from the context of its use (as it usually will be). Finally, it should also be noted that it is not an essential element of the instant invention that the loudspeaker 75 be found within the body of the monitor. The speaker 75 could also be mounted externally thereto, and, as an extreme example, might by located in an adjacent hallway or at the nurses station.
The signal conditioning circuit 100, shown in detail in Figure 6, filters noise from the mat inputs JRl-1 and 2 and provides a reasonable degree of protection to the monitor from static discharge. Filtering at one input JR1-2 is accomplished by a single RC
circuit including resistors R2o and R2t and a capacitor C6 and at the other input JR1-1 by a simple RC circuit including resistors R~9 and R3t and a capacitor C3. This eliminates some noise and assists in increasing the immunity from static discharge. A static discharge to the monitor passes through the RC filters and is then clamped by surge limiting devices, RV j and RV2 of Figure b. The combination of the first input components R2o, R2~, C6 and RV2 and the second input components R ~ 9, R3 ~ , C 3 and RV ~ should provide static protection far in excess of known monitors.
The non-volatile memory 130 illustrated in Figure 7 includes a 1 Kbit ( 128x8) electrically erasable programmable read only memory EEPROM 101. It is connected via resistors R25 and R2~ to the power supply interface connections J3-4 and J3-5.
The actual IC
chip is preferably a Microchip X24LC01 which uses a two wire serial interface to communicate with the processor 10. The interface is based on the I2C bus which has become the predominant standard for low cost inter-chip communications (i.e., "Inter-IC"
bus, which is a standard means of providing a two-wire communication link between integrated circuits) .
Detailed information on the chip and the I2C bus may be found in the Microchip Nonvolatile Memory Products databook. The EEPROM 101 is used to store operating characteristics, usage information and device specific information such as a repair log and unit serial number.
The operating characteristics are defined, in part, by a collection of user-modifiable parameters that control various aspects of the monitor's operations, including, for example, the type of alarm tone (e.g., Figure 15, item 329), the relay action, the hold time delay, and the volume of the alarms. These memory locations may be modified either through use of the front panel control switches or, as hereinafter described, via a computer program that is executing on a remote host connected to the monitor via an electronic interface, such as a serial port. Usage information might consist, by way of example only, of an hour meter which logs total hours of use of the monitor, the total time alarming, the total number of alarms, the response time to the last alarm, and / or the date and time of past alarms (the calendar date and time being provided by, for example, a date / time chip 595 of the sort illustrated in Figure 22).
Downloading usage information to a host computer allows a number of diagnostic statistics to be calculated, including the "average time to respond". This information is preferably only be written by the monitor, and read only to an inquiring host computer. Read only status is purely a software function of the host. Device specific information would N typically not be used by the monitor and is never written to or read by the monitor. It is preferably written only at the time of manufacture or time of repair by an external host computer. The information is intended for use by the factory, a repair station, or a facilities biomedical staff and might include, for example, the date of the last ten repairs and corresponding work order numbers and the unit's serial number.
Turning now to Figure 8, the nurse call interface 160 uses a relay K1 to provide isolation between the monitor circuitry and the nurse call system. A normally open contact 161, a normally closed contact 163 and a common contact 165 of the relay K1 are connected to a connector J2. The nurse call cord (not shown) plugs into this connector J2 and would typically be an RJ-45 or similar connector. Since there is always a potential for inadvertent disconnection of a connector J2, two additional pins J2-4 and 5 are used in the connector J2 to provide a continuity loop. By monitoring this loop, the processor 10 can detect a pulled-out nurse call cord. If this condition is detected, a distinct in-room alarm is sounded. Pull-out protection may be disabled via the profile stored in the nonvolatile memory 130 when the system is used in a facility without a nurse call system or in a home. The relay Kl is energized in the non-alarming state. This effectively reverses the contacts 161 and 163 so that the normally open contact 161 appears to be normally closed and vice versa. Thus, a nurse call is issued whenever power is interrupted to the monitor. This provides a fail safe on the power supply 190 and its interconnects. A single RC filter consisting of a resistor R i R and a capacitor C4 provides static protection for the processor 10. The relay KI is turned on by the transistor Q1 via a current limiting resistor R23 and a diode D3 which absorbs the inductive kick which occurs when the relay KI is de-energized.

As shown in Figure 9, the power supply 190 includes an external connector J3.
The connector J3 includes a transformer (not shown) connected between two pins J3-1 and J3-2 of the connector. Power VCC is brought into the monitor through a voltage regulator 191 connected to the first connector pin J3-1. Two additional pins J3-4 and 5 of this connector J3 S are used for the read/write interface of the external EEPROM 101. Filter capacitors C ~ ~ and C~2 are preferably connected on either side of the voltage regulator 191.
Monitor Front Panel Control Functions The internal software allows the monitor to perform a variety of functions. As illustrated in Figure 4, the user interface 40 includes inputs allowing a user to modify control unit actions via the reset button 53 and to adjust the delay via the delay adjust button 55 and outputs for controlling operation of the 0 through 9 numeric display 41, the status annunciators 43 and various aural signals.
An idle mode (HOLD), which is active when the monitor is not monitoring, enables automatic advancement to the monitor mode, manual override for immediate advancement to the monitor mode, adjustment of the delay time, aural indications of any unsafe conditions and logging of hours in use. The monitor mode (MON) enables monitoring of the patient for activity within the bed which could be a precursor for a bed evacuation, adjustment of the delay time, manual return to the idle mode (HOLD), automatic advancement to the alarm mode (ALARM), aural indications of any unsafe hardware conditions and logging of hours in use.
The alarm mode (ALARM) enables generation of a nurse call through the nurse call system 160, aural in-room alarm, manual return to the idle mode (HOLD) and logging of response time and total alarm time. A program mode enables the user to customize the features of the monitor and to update the non-volatile memory 130 with user selected parameters.
All functions which utilize the user interface 40 are consistent with the nomenclature which the user sees on the labels of the buttons S3 and 55 and on the numeric display 41. For example, any features which use the reset button 53 have an intuitive connection to the word "reset". Likewise, the delay adjust button 55, which preferably features a triangle pointing up, causes an upward adjustment in the numeric display 41 with appropriate roll over at a maximum value.
Internal Software / Logic Functions Figure 10 illustrates the main steps that are executed within the monitor as part of a power-up (i.e., cold start) sequence. In the preferred embodiment, a cold start 201 will cause the processor l0 to automatically enter into the HOLD mode as part of step 201. Then, the system initialize hardware 203 and variables 205, after which it will then set the I2C interface to inputs 207 to determine whether the interface is already being used, for example to change the programs in the EEPROM 101. An inquiry is then made as to whether the I2C
is busy 209. If the response to this inquiry is "YES," then the inquiry is repeated until the response is "NO." If a "NO" response is received, the system proceeds to recall parameters stored previously within EEPROM 213. The system will next inquire. as to whether the delay time equals nine (step 215). If the response to this inquiry is "YES," the system will next inquire as to whether the reset is pressed 217. If the response to either the inquiry as to whether the delay time equals nine 215 or whether the reset is pressed 217 is "NO," then the system proceeds to go to executive routine 219. If the response to the inquiry as to whether the reset is pressed 217 is "YES," the system proceeds to go to local configuration 221.
As is illustrated in Figure 11, if the system has gone into executive 223 mode, the system will again inquire as to whether the I2C is busy 225. If the response to this inquiry is "YES," the system will continue to inquire as to whether the I2C bus is still busy 227. As long as the response to this inquiry is "YES," the inquiry continues. If the response to the inquiry as to whether the I2C bus is still busy 227 is "NO," then the system will go to cold 229 and resume from the cold start 201 as shown in Figure 10. If, however, on inquiry as to whether I2C is busy 225 the response is "NO," the system proceeds to display delay time 231 on the display 41 and will turn on hold annunciator light 233 which is an indication to the caregiver that there is no weight on the mat used to monitor the patient's presence. The system then inquires as to whether it is time to log (step 235). In the preferred embodiment, every six minutes or 1/lOth of an hour the system will log the lapse of an increment so as to maintain a record of total hours of use of the monitor. If six minutes have not elapsed, the response to the inquiry is "NO" and the system proceeds to inquire as to whether the delay adjust switch is pressed 237. If six minutes have elapsed, the response to the inquiry as to whether it is time to log 235 is "YES" and the system will proceed to call data logger 239 so as to register this increment. The system then continues to the delay adjust switch pressed inquiry 237 until another six minute interval has elapsed and the call data logger 239 is again cycled. If the response to the inquiry as to whether the delay adjust switch is pressed 237 is "NO," the system proceeds to inquire as to whether the mat is pressed 241. If the response to the inquiry as to whether the delay adjust switch is pressed 237 is "YES," the system proceeds to increment delay 243 by stepping to the next of the nine increments available for delay as hereinbefore discussed and then inquires as to whether the mat is pressed 241.
If the response to the mat pressed inquiry 241 is "NO," the system will recycle to the time to log inquiry 235 and continue the process until the response to the mat pressed inquiry 241 is "YES," indicating that a patient is on the sensor mat. If the response to this inquiry is "YES,"
the system then proceeds to go to hold delay 245.

Turning now to Figure I2, representing the transient condition between the hold mode 201 and the monitor mode 273, when the monitor is at hold delay 247, the system will initialize hold timer to program value 249. Generally, the hold timer will permit selection by the caregiver of from 1 to 20 seconds as the interval that the patient's weight must be on the sensor mat before monitoring of the patient's presence is initiated. In the preferred embodiment described herein, this available time interval is in a range of 1 to 9 seconds. The system then proceeds to initialize flasher timer 251. The flasher timer establishes the flash interval for the attenuator indicating that a patient's weight is on the sensor mat. With the timers initialized, the system proceeds to get keys 253 by examining the switches 53 and 55 of the keypad 45.
Inquiry is first made as to whether the caregiver has operated the delay adjust 255. A "YES"
response indicating that the delay adjust switch 55 is depressed will result in an increment change 257. If the response to the delay adjust inquiry 255 is "NO" or the increment change 257 is made, the system continues on to inquire as to whether the reset is pressed 259. If the response to this inquiry is "NO," the system proceeds to inquire as to whether the hold time is expired 261. If the response to this inquiry is "NO," the system inquires as to whether the flash time has expired 263. If the flash time has expired, providing a YES
response, the system will toggle the hold light and reset the timer 265. If the flash time has not expired or has been reset, the system will proceed to inquire as to whether there is a weight on the mat 267. If the response to this inquiry is "NO," the system will go to executive 219, returning to the loop illustrated in Figure 11. If the response to the weight on mat inquiry 267 is "YES,"
the system will perform a pullout check 269 to determine if there is an improper connection in the system. After performing the pullout check 269, the system will return to the get keys step 253 of the hold delay loop 247. If, in the operation of the hold delay loop 247, the response to the reset pressed inquiry 259 or the hold time expired inquiry 261 is "YES," then the system will go to monitor 271, as will hereinafter be described.
The HOLD mode 235 is characterized by a continuous hold indicator 47 and the number of seconds of delay time is displayed on the numeric display 41. The nurse call relay K1 is energized (non-alarming state). There is no testing of the sensor validation input, there is no pull-out detection, and the keypad 45 is monitored at least 20 times per second except during tone generation. Upon pressing the delay adjust button 55, the delay is bumped by one second and the display 41 is updated with the new delay time. After nine seconds, the delay time resets to one second. If the reset button 53 is pressed, a 1/2 second tone at lkHz is generated. Software exits this loop and enters the pre-monitor phase of the monitor mode MON when weight is detected on the mat (IRQ goes low). During the hold mode HOLD, logging of hours in use occurs every 1/lOth of an hour (six minutes).
The main monitor routine is illustrated in Figure 13. When the system goes to monitor 273, it will change the annunciator condition by turning on MON and turning off HOLD 275.

Thus, the HOLD annunciator 47 will be de-energized and the monitor annunciator energized. The system will then inquire as to whether it is time to log 277, as has been hereinbefore explained. If the response to this inquiry is "YES," then the system will call data logger 279 to log the expiration of the six minute increment. If the answer to the inquiry as to time to log 277 is "NO," or if an increment has been logged, the system will proceed to a get keys status 281. The system will inquire as to whether the delay adjust switch is pressed 283.
If the response to this inquiry is "YES," an increment change 285 will be made in the time delay. If the response to the delay adjust inquiry 283 is "NO" or the increment change 285 has been made, the system will proceed to inquire as to whether the reset is pressed 287. If the response to this inquiry is "YES," the system will go to executive 289 and perform the loop illustrated in Figure 11. If the response to the reset pressed inquiry 287 is "NO," the system will proceed to call pull-out 291 to determine whether there is an electrical connection failure in the system. The system then inquires as to whether there is a weight on the mat 293.
If the response to this inquiry is "YES," the system will return to the time to log step 277 of the monitor loop 273. If the response to the inquiry as to weight on the mat 293 is "NO," the system will proceed to go to alarm 295. The monitor mode 273 has a transient pre-monitor phase shown in Figure 12 and a steady-state monitor phase shown in Figure 13. The pre-monitor state is characterized by a flashing hold indicator 47. The LED
flash period is .2 seconds on and .2 seconds off. During the pre-monitor phase, the nurse call relay K1 is energized (non-alarming state), nurse call pull-out protection is active, the sensor input is validated, the numeric display 41 continues to display delay time, and the keypad 45 is polled at least 20 times per second. If the software detects an improperly inserted nurse call connector, a tone will be generated, preferably sixteen cycles of 400Hz followed by 42 msec of silence, repeated four times, followed by a minimum of 320 msec of silence before repeating the entire process. Pressing the delay adjust button S5 will increment the delay time one second up to a maximum of nine seconds. The delay time then resets to one second. The numeric display 41 is updated with each change in the delay time. Pressing the reset button 5 3 will cause the monitor to immediately proceed to the monitor phase 273. This mode expires after a programmable hold time. The hold time defaults to ten seconds but may be programmed by the user for any time from 1 to 10 seconds. Upon expiration of the hold time or upon pressing the reset button 53, the software advances to the monitor phase 273.
The software will return to the hold mode 247 if weight is removed from the mat prior to entering the monitor phase 273.
The monitor phase of the monitor mode 273 is characterized by a solid monitor status indicator 49. During this phase, the sensor is monitored for weight on mat, the nurse call relay K1 is energized (non-alarming state), nurse call pull-out protection is active, the numeric display 41 continues to display the delay time, and the keypad 45 is polled at least 20 times per second. If an improperly inserted nurse call cord is detected, the unit will sound an alarm as described in the pre-monitor phase. Pressing the delay adjust button 55 will advance the delay time one second up to a maximum of nine seconds. The delay time then resets to one second.
The numeric display 41 is updated with each change in the delay time. Pressing the reset button 53 will return the software to the hold mode 247, allowing removal of the patient from the bed. Since there must be weight on tije mat to be in this mode 247, the hold mode 247 will automatically advance to the pre-monitor phase of the monitor mode 273.
To improve functionality, the hold time will temporarily be set to 25 seconds when this path is taken to allow sufficient time to remove the patient from bed. If weight is removed from the mat, the software advances to the pre-alarm phase of the alarm mode 302. That parameter "hours in use" is logged / incremented every 1/lOth of an hour.
The alarm mode 301 illustrated in Figure 14 consists of a transient re-alarm phase and a steady state alarm phase. The pre-alarm phase is characterized by a flashing alarm indicator 51. The flash period is .2 seconds on and .2 seconds off. During the pre-alarm phase the nurse call relay K1 is energized (non-alarming state), the mat input is monitored, and the keypad 41 is polled at least 20 times per second. Returning weight to the mat will cause the software to return to the monitor mode 273. Pressing the delay adjust button 55 has no effect.
Pressing the reset button 53 will return the software to the hold mode 247.
Since this mode 247 is only active with weight off the mat, the monitor will remain in hold upon returning to the hold mode 247. This mode 247 expires after the number of seconds displayed in the numeric display 41 and then enters the alarm phase.
The alarm phase of the alarm mode 301 is characterized by a solid ALARM
indicator 51 and an audible alarm. During this mode the nurse call relay K1 is operated in accordance with a pre-programmed protocol and the keypad 41 is polled at least 20 times per second.
Pressing the delay adjust button 55 has no effect. The audible alarm will continue to sound until the reset button 53 is pressed, returning the unit to the hold mode 247.
The alarm preferably provides one of six possible user selectable alarms (see, for example, 329) including a lkHz beep in intervals of .5 seconds on and .5 seconds off, a lkHz beep in intervals of .25 seconds on and .25 seconds off, a lkHz beep in intervals of 1 second on and 1 second off, 16 cycles at 400Hz followed by 18 cycles at 440Hz repeated 12 times followed by one second of silence, a rising whoop or a stepped alarm providing four alarms at 320 Hz in intervals of 28 cycles and 28 cycles off, four alarms at 392 Hz in intervals of 32 cycles on and 32 cycles off, four alarms at 277 Hz intervals of 24 cycles on and 24 cycles off with 1/2 second of silence. It is also possible to have no audible alarm. The nurse call relay K1 has three possible operating modes to accommodate various nurse call systems including continuous closure, one-shot and asynchronous 331. At the termination of the ALARM mode 301, the response time is written to the EEPROM 101, the stored number of alarms is bumped by one and rewritten to the EEPROM 101 and the current response time is added to the total alarm time and the EEPROM 101 is updated with the new value.
In the alarm mode 301 the system will initialize flash timer 303 and change the annunciator status to turn on alarm and turn off HOLD 305. The system then inquires as to whether reset is pressed 307 and, if the response to this inquiry is "YES,"
the system will go to executive 309 and repeat the executive loop 223 illustrated in Figure 11.
If the response to this inquiry is "NO," the system will proceed to inquire as to whether the flash timer has expired 311. If the response to this inquiry is "YES," the system will toggle the alarm light 313 and reset the timer 315. If the response to the flash timer expired inquiry 31I is "NO" or the timer is reset 315, the system will proceed to inquire as to whether there is weight on mat 317. If the response to this inquiry is "YES," the system will go to monitor 319 and repeat the monitor loop 273 illustrated in Figure 13. If the response to the weight on mat inquiry 317 is "NO," the system will inquire as to whether the delay timer expired 321. In this step, the system determines whether the time selected by the caretaker to elapse after weight has left the mat and before weight has returned to the mat has expired. If the response to this delay time expired inquiry 321 is "NO," the system will return to the reset pressed inquiry 307 of the alarm loop 301. If the response to the delay timer expired inquiry 321 is "YES," the system proceeds to loop A 323 of the alarm mode illustrated in Figure 15 to provide the audio alarm. In this phase of the alarm mode 301, the system will set the volume 325 and initialize the alarm variables 327 established by the caregiver for the system. The system then dispatches for selected tone 329, causing the monitor to give the audio tone selected from the six audio tones available to the caregiver. The system will also exercise relay per selected option 331, causing the nurse call station relay K1 to function according to one of the four alternatives selected by the caregiver for the system. The system will next inquire as to whether the reset is pressed 333. If the reset button 53 has not been operated by the caregiver, the response to the inquiry is "NO" and the system will return to the dispatch for selected tone 3 2 9 step of the alarm loop 301 and continue to provide the selected audio alarm.
If the response to the reset press inquiry 333 is "YES," the system will bump event counter, save response time and total response 335 in which the system makes a record of the responses and response times of the caregiver. When this has been completed, the system will go to executive 337 and return to the executive loop 223 illustrated in Figure 11.
The local configuration or program mode 341 provides the user with a means to select various user options and save these selections in the non-volatile memory 131.
To enter this mode 341, the delay time is set to nine seconds. The monitor is then powered down. The monitor then is re-powered up with the reset button 53 pressed. The software will then illuminate multiple annunciators to indicate the particular phase of the programming mode 341 which has been entered. There are four phases of the program mode 341 including tone select, relay action & pull-out detection enable, hold time select and volume adjust.
The tone select phase will display the last tone selected in the numeric display 41. A new tone may be chosen by cycling through the available options with the delay adjust button 55.
Preferably, the default for the first time to apply power is the lkHz beep at .5 second intervals mentioned S above. The relay action phase will display the current relay action in the numeric display 41.
A different action may be chosen by cycling through the available options with the delay adjust button 55. The default for the first time to apply power is continuous operation. The available relay options are discussed above in relation to the alarm mode 301.
Programming to a three will disable the pull-out detection. This allows the unit to be used in facilities which do not have a nurse call system or choose not to connect to the nurse call system.
Programming this to a zero, one, or two enables the pull-out detection. The hold time phase allows the user to adjust the time delay between a patient placing weight on the mat and the beginning of monitoring. The default is preferably 10 seconds. The user may select 1 to 10 seconds. A
zero in the numeric display 41 represents 10 seconds. The volume adjust allows the user to select one of ten possible volume levels. The alarm is silent when set to zero and at full volume when set to nine. The software translates 1 through 9 into actual steps (0-31) of the wiper control VW of the programmable volume control 71. When programmed from the external interface, all 32 steps are available. The default volume is seven (numeric displayed value) which translates to a wiper position of 25. For all of the above, a value is accepted and the next phase is entered by pressing the reset button 53. After the programming of the volume control 71, the monitor enters the hold mode 247. If power is removed during the programming process, the new values up to the last time reset 53 was pressed will be saved.
In the local configuration loop 341, the system will first turn on hold, monitor and alarm lights, load tone selection and output to numeric display 343. The system then proceeds to get keys 345 as earlier discussed with respect to other system loops, inquiring as to whether the delay adjust is pressed 347. If the response to this inquiry is "YES," the system will increment the toning selection 349 and then inquire as to whether the tone is greater than five 351. This relates to the sequence of six tones earlier referenced in relation to the alarm mode 301. If the response to this inquiry 351 is "YES," the system will reset the alarm mode to zero 353. If, after incrementing tone selection 349 the tone is not greater than five 351 or is set to zero 353, the system returns to the turn-on hold, monitor and alarm lights, load current tone selection and output numeric display step 343. If the response to the delay adjust pressed inquiry 347 is "NO," the system next inquires as to whether the reset is pressed 355. If the answer to this inquiry 349 is "NO," the system returns to the get keys step 345. If the response to this inquiry 349 is "YES," the system will save tone to EEPROM
357. When the tone has been saved in EEPROM 101, the system will beep 359 to indicate this status. The system will then turn off alarm light, load current relay action and output to numeric display 361 and again proceed to get keys 363. The system again inquires as to whether the delay adjust is pressed 365. If the response to this inquiry 365 is "YES," the system will increment relay action 367 according to the sequence discussed in relation to the alarm mode 301. The system will inquire as to whether the relay is greater than three 369, determining which increment of the relay options the system will select. If the response to this inquiry 369 is "YES," indicating that the option will be greater than three, the system sets to zero 371 to begin a recycle of available selections. If the answer to the inquiry 369 is "NO" or if the selection is set to zero 371, the system returns to the turn off alarm light, load current relay action and output to numeric display step 361. If the response to the delay adjust pressed inquiry 365 is "NO" the system proceeds to inquire as to whether the reset is pressed 373. If the answer to this inquiry is "NO," the system returns to the get keys step 363. If the answer to this inquiry is "YES," the system proceeds to point B 375 of Figures 16 and 17. Looking at Figure 17, if the reset pressed inquiry 373 response is "YES," the system will save relay to EEPROM 377, storing the selected relay position in the EEPROM 101. The system then proceeds to beep 379 to advise the caregiver of the status. The system then turns on the alarm annunciator, turns off the monitor annunciator, loads the current hold time and outputs to numeric display 381. The system then again proceeds to get keys 383, first inquiring as to whether the delay adjust is pressed 385. If the response to this inquiry is "YES," the system will increment hold time 387. Inquiry is made as to whether the hold is greater than nine 3 8 9 and if the response to this inquiry is "YES," the system will set to zero 391.
If the response to the inquiry 389 is "NO," or the system has been set to zero 391, the system will return to the turn-on alarm enunciator, turn-off monitor enunciator, load current hold time and output numeric display 381. If the response to the delay adjust pressed inquiry 385 is "NO," the system will then inquire as to whether the reset is pressed 393. If the response to this inquiry is "NO," the system returns to the delay adjust pressed inquiry 385. If the response to the inquiry 393 is "YES," the system will save hold time to EEPROM 395, storing the selected delay time in the EEPROM 101. The system will then provide a beep 397 to indicate the status and will then turn off the HOLD annunciator, turn on monitor annunciator, load, e.g., 7 as the volume and output to the numeric display 399. That is, of the ten volume increments selectable, the system will automatically proceed to the seventh increment level. The system then proceeds through point C 401 as illustrated in Figure 18 to get keys 403 and inquire as to whether the delay adjust is pressed 405. If the response to this inquiry 405 is "YES," the system will increment volume 407 and inquire whether the volume is greater than nine 409. If the response to this inquiry 409 is "YES," the system will reset volume to zero 411. If the response to the volume greater than nine 409 is "NO," or the system has set the volume to zero 411, the system then returns through point D 413 to turn-off HOLD
annunciator, turn-on monitor annunciator, load 7 as volume and output to numeric display 399 as shown in Figure 17. Returning to Figure 18, if the response to the delay adjust pressed inquiry 405 is "NO,"
the system proceeds to inquire as to whether the reset is pressed 415. If the response to this inquiry 415 is "NO," the system returns to the get key step 403. If the response to the inquiry 415 is "YES," the system proceeds to look up actual volume 417. The system then writes the volume to EEPROM 419, storing the selected volume in the EEPROM 101, and then goes to cold 421, returning to the cold start 201 illustrated in Figure 10.
The data logger subroutine 431 illustrated in Figure 19 is used by the system at the call data logger steps 239 and 279 of the executive loop 223 illustrated in Figure 11 and the monitor mode 273 illustrated in Figure 13, respectively. In the data logger sub routine 431, the system will read hours from RAM 433 and write hours to EEPROM 435, storing the number of hours that the system has operated in EEPROM 101. The system will then read minutes from RAM 437 and write minutes to EEPROM 439 to store any portion of an hour not already stored in EEPROM 101. The system will then reset 0.1 hour timer 441 and return 443 to the routine making the data logger demand.
The pull-out protection sub routine 451 illustrated in Figure 20 is used by the system at the call pull-out steps 269 and 291 of the hold delay mode 247 illustrated in Figure 12 and the monitor mode 273 illustrated in Figure 13, respectively. In the pull-out protection subroutine 451, the system will read the output Q6 of the latch and read the status of Bit 2 of Port B 455. The system will then inquire as to whether PB2 is high 457. If the response to this inquiry is "NO," the system will sound alarm 459 and return 461 to the pull-out protection step 451. If the response to this inquiry is "YES," the system will proceed to return 461 to the routine making the pullout protection demand without sounding the alarm.
In summary, the monitor will preferably conform to the following specifications:
Specification Min: Max: Units Tolerance Delay Time 1 10 seconds +/-5%

Hold Time 1 10 seconds +/-5%

Relay One-shot Duration 0.5 5 seconds n/a Relay Asynchronous On 0.25 2 seconds n/a Relay Asynchronous Off 0.25 2 seconds n/a Tone Programming 0 7 n/a n/a Relay Programming 0 2 n/a n/a Pull-out Programming 0 1 n/a n/a Specification Min: Max: Units Tolerance Hold Time Programming 0 9 n/a n/a Warning Frequencies n/a n/a Hertz +/-10%

Tone Durations n/a nla seconds +/-10%

lvlicroprocessor-nasea ivlonltor wltn a lvloarnanle rersonatity According to a second aspect of the instant invention, there is provided a microprocessor based monitor substantially as described above, but wherein the software that controls the actions of the monitor is stored within modifiable nonvolatile memory (e.g., flash-y RAM) within the device, so as to be modifiable to create a patient monitor that has different personalities, depending on the needs of a particular application. More specifically, it is contemplated that much, if not all, of the software illustrated in Figures 10 to 20 - the software that controls the personality / functionality of the unit - will be stored within the monitor in a form that can be modified to suit the requirements of any site or individual patient (per doctor's orders) and, more particularly, the needs of the particular nurse call station to which the monitor is connected.
Turning first to Figure 21 wherein the general environment of the instant invention is broadly illustrated, in the preferred embodiment the reprogrammable monitor 550 is connected to sensor mat 500 by way of an RJ-11 connector 525. As has been discussed previously, the RJ-11 connector 525 provides the internal microprocessor 10 access to the state of the patient detector circuit within the mat 500. During normal operations, power line 565 would be plugged into monitor 550 to provide a source of external power to the unit.
However, Figure 21 illustrates the preferred configuration of the monitor 500 and a interconnected computer host 570 during exchange of information. Interface unit 560 is designed to act as a data conduit and pass serial information along line 580 from the host computer 570 to the monitor 550 and back again on demand from the host 570 or monitor 550. Additionally, the instant interconnection incorporates a power line into the serial line 590 for use by the monitor 550 during programming. It is not essential that the power be incorporated into the interconnecting line 590, but it is part of the presently preferred embodiment that it be so designed. In the event that a source of power is not needed via line 590, that line could take the form of a simple parallel serial, USB, etc. cable and interface unit 560 could then be a standard computer port (serial, parallel, etc.). Additionally, it should be noted that, although the interface unit 560 is pictured as being a separate device that is external to both the monitor 5 5 0 and the host 570, it might easily be incorporated into one unit, or the other, or both.
In the preferred embodiment, the lines 580 and 590 that interconnect the host computer 570 and electronic monitor 550 are serial lines, and the data communications protocol used is the I2C standard. However, those skilled in the art will recognize that there are many other standard and non-standard communications protocols that could be used in the alternative. For example, the instant inventors specifically contemplate that the interconnecting communications lines ( 580 and 590) could be parallel cables. Further, it might prove to be desirable in some cases to put a separate data port on the monitor 550 which might be, for example, a serial or parallel connector and which is dedicated for use in communications with a host computer 570, i.e., it does not share the responsibility of conveying power to the unit during data transfer.
Finally, it specifically contemplated by the inventors that it would even be possible to communicate with a remotely positioned monitor 550 through nurse call interface 130 (Figure 1), thereby eliminating the need to physically bring together the host computer 570 and monitor 550, it being well within the capability of one of ordinary skill in the art to modify the invention-as-disclosed to implement this variation.
Within the monitor 550 and as is illustrated in Figure 22, data sent from the host computer 570 are received by the CPU 620 of the microprocessor 10 and then subsequently stored, preferably within a local flash RAM 610. As is well known to those skilled in the art, many other similar arrangements might be used instead that would be functionally equivalent to using flash RAM, including using conventional RAM with battery backup, EEPROM, a local disk drive, etc, the key feature being that - what ever type of storage is used - it should be at least relatively nonvolatile for purposes of the instant embodiment and, most importantly, modifiable under local program control. Thus, in the text that follows the phase "modifiable nonvolatile RAM" will be used in the broadest sense to refer to the type of storage just described. Additionally, it is anticipated that CPU 620 will be provided with some amount of ROM 130 or other storage type for permanently storing information and which could contain, for example, the serial number of the unit, date of manufacture, and the code that would control the basic operations of the CPU 10 during cold starts, resets, personality uploads, etc.
During operation, the monitor 550 could use the flash RAM 620 as storage for various data parameter values including accumulated performance statistics, data /
time stamps of alarm events, patient identification numbers, hold delay, delay time, speaker volume, type of alarm tone (i.e., what sort of alarm will be sounded - e.g., fast beep, slow beep, whoop, etc.), relay action type (e.g., continuous, one-shot, asynchronous, etc.), total time in service, date of last bio-med check,total number of alarms sounded, response time to Iast alarm, average response to last four alarms, alarm history (e.g., response times for the last fifteen or so alarms and time / date of alarm occurrence), repair history, hospital equipment identification number (e.g., asset number), or a current time / date stamp. Additionally, this same connection could be used to read parameters from the monitor 550 such as total time in service, date of last bio-medical check, the unit serial number, etc.

However, the main anticipated use for the flash RAM 620 is for storage of the operating personality of the unit. In particular, Figures 10 to 20 discussed previously are implemented within the monitor in the form of assembly language computer instructions which are stored in and read from ROM memory 130, thereby making those program steps immutable, unless the memory chip containing them is replaced. In the instant embodiment, it is anticipated that much of the functionality.of the software illustrated in those figures would be stored in a form that can be modified to suit the requirements of a particular nurse call station, or hospital environment, e.g., within flash RAM 620.
As is broadly illustrated in Figure 23, the personality loading program 700 within the monitor 550 is preferably initiated through the use of a non-maskable interrupt 705 (defined as a "master mode" interrupt) as is provided for by the I2C communications standards. In more particular, when the CPU 610 senses an interrupt on the pins associated with port 593, it preferably enters a slave mode, wherein the host computer 570 completely controls its operations. The host computer 570 then directs the monitor CPU 610 to begin receiving "data" 715 and storing that data 725 at predetermined locations within the flash RAM 620, which data may be parameter values as discussed previously or, preferably, binary computer instructions that define the personality / operations of the unit.
At the conclusion of the loading process, the host computer will preferably require the monitor to execute a cold start 735, after which the monitor will continue execution as before, only this time using the various aspects of the new personality stored 740 in flash-RAM. Of course, the obvious advantage of an arrangement such as this is that it permits the functionality of the monitor to be modified to suit specific applications and, indeed, makes it possible for a single monitor to function with multiple nurse call station formats with only minimal effort.
System for Programming a Reprogrammable Monitor According to still a further aspect of the instant invention, there is provided a monitor /
host software combination that allows the end-user to make personality changes in the software that controls the monitor. Additionally, this same system provides a means for the user to read and / or modify data values that are maintained in the nonvolatile memory of the patient monitor. In the preferred embodiment, the software that manages the user interface would run on a host computer 570 such as a lap top computer. As is well known to those skilled in the art, the software embodying the instant invention might be conveyed into the computer that is to execute it by way of any number of devices 571 including, for example, a floppy disk, a magnetic disk, a magnetic tape, a magneto-optical disk, an optical disk, a CD-ROM, flash RAM, a ROM card, a DVD disk, or loaded over a network.
As is broadly illustrated in Figures 21 through 23 and as has been discussed previously, a preferred embodiment of the instant invention uses a host computer 570 to load operating parameters and executable instructions into the monitor.
Additionally, this same connection is used to retrieve statistical and other information from the monitor. Further, cumulative statistical values such as total time spent in an alarm condition, alarm history, etc., can be reset (e.g., made equal to zero) by this same process.
As is illustrated in Figure 24, the host control program for parameter and operating statistics recall 800 preferably begins by generating a non-maskable interrupt 805 which results in monitor 550 passing operating control to the host computer 570. The host computer 570 then instructs the monitor CPU 610 to pass the contents of specific memory locations (steps 815 to 830) back to itself. The data returned from the monitor 550 are then presented to the user for review. Needless to say, once the data have been collected additional analysis of the resulting information would certainly be useful in some situations and that additional step has been specifically contemplated by the instant inventors.
Conclusions Although the preceding text has occasionally referred to the electronic monitor of the instant invention as a "bed" monitor, that was for purposes of specificity only and not out of any intention to limit the instant invention to that one application. In fact, the potential range of uses of this invention is much broader than bed-monitoring alone and might include, for example, use with a chair monitor, a toilet monitor, or other patient monitor, each of which is configurable as a binary switch, a binary switch being one that is capable of sensing at least two conditions and responding to same via distinct electronic signals. In the preferred embodiment, those two conditions would be the presence of patient and the absence of a patient from a monitored area. Although a pressure sensitive switch is the binary switch of choice for use in the preferred embodiment, other types of switches could work as well for some applications. Additionally, it should be noted that the use of the term "binary" is not intended to limit the instant invention to use only with sensors that can send only two signal types.
Instead, binary switch will be used herein in its broadest sense to refer to any sort sensor that can be utilized to discern whether a patient is present or not, even if that sensor can generate a multitude of different of signals.
Thus, it is apparent that there has been provided, in accordance with the invention, a monitor and method of operation of the monitor that fully satisfies the objects, aims and advantages set forth above. While the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art and in light of the foregoing description.
Accordingly, it is intended to embrace all such alternatives, modifications and variations as fall within the spirit of the appended claims.

Claims (8)

THE CLAIMS
WHAT IS CLAIMED IS:

1. A bed patient monitor comprising:
(a) a loudspeaker, said loudspeaker being driven by a power amplifier and said amplifier responding to an input signal derived from a programmable volume control to produce an aural alarm; and (b) a processor (1) for receiving electronic signals from a sensor indicative of the presence thereon and absence therefrom of a patient, (2) for synthesizing at least one alarm sound under software control, (3) for operating said programmable volume control to select a decibel level of said at least one alarm sound, and (4) for activating and deactivating said alarm in response to said electronic signals.

2. A monitor according to Claim 1 further comprising (c) electrically erasable programmable read only memory for storing a plurality of alarm sounds for selection by said processor of said at least one alarm sound.

3. A monitor according to Claim 1 further comprising (c) electrically erasable programmable read only memory for storing a plurality of decibel levels for selection by said processor of said decibel level of said at least one alarm sound.

4. A monitor according to Claim 1 further comprising (c) electrically erasable programmable read only memory for storing a plurality of options for a delay time between an initiation of absence of a patient from the sensor and an activation of said alarm by said processor.

5. A monitor according to Claim 4 further comprising (d) an external switch connected to said processor for selecting said delay time from said plurality of options.

6. A monitor according to Claim 1 further comprising (c) electrically erasable programmable read only memory for logging usage data including total hours of use of the monitor, total time of alarm sounding by the monitor, total number of alarms sounded by the monitor and a response time between a most recent sounding of an alarm and a subsequent operation of the monitor.

7. A monitor according to Claim 6 having a port for downloading said logged usage data to a host computer.

8. A monitor according to Claim 1 further comprising (c) a nurse call interface having a relay which is energized when said power amplifier is deenergized and having a normally open contact, a normally closed contact and a common contact for interconnecting the monitor to a nurse call system through one of said normally open and normally closed contacts.