Abstract:
A removable package for use primarily in an ambulatory monitoring device, such as a medical monitor includes a RAM and a power supply. The RAM package is connected to an external device via an edge connector which includes interlock means for sensing when the removable RAM package is properly connected to the external device in order to prevent inadvertent writes into the RAM. In a preferred embodiment of the invention disclosed, the removable RAM circuit also includes a microprocessor compatible real time timer which is connected to the same data and address buses as the RAM.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to a removable RAM package for a data acquisition system. In particular, the present invention has utility in an ambulatory medical monitor such as an ambulatory blood pressure monitoring system. 
     A number of portable monitoring devices are used in medical monitoring. One well known device is the so-called Holter monitor which is an EKG monitor which typically uses a magnetic tape recorder to record EKG signals from a patient over extended periods of time. A patient whose EKG is being monitored usually wears a Holter monitor for 24 hours, during which time the monitor records EKG signals for later analysis by a physician. 
     Heretofore, very few portable monitoring devices existed for obtaining blood pressure readings over extended periods of time. The reason for this was twofold. First of all, there are very few automatic, non-invasive blood pressure monitoring devices in use today. Second, an improved recording means for collecting data in a portable blood pressure monitoring unit did not exist. 
     One known non-invasive blood pressure monitoring unit is the blood pressure cuff designed and sold by VitaStat Medical Services, Inc. and described more fully in U.S. Pat. No. 4,206,765 entitled CUFF MECHANISM which issued to T. G. Huber on June 10, 1980. This particular unit requires an air pump to pump up the cuff each time a reading is taken. Accordingly, an ambulatory blood pressure monitoring device must include means for energizing the air pump. While a battery would be suitable to provide electric power to the air pump, so much power is required to operate the air pump that some means of preserving battery power would also be desirable. 
     SUMMARY OF THE INVENTION 
     The present invention is a removable package containing a random access memory (RAM), a real time timer, and means for energizing the RAM when the package is properly plugged into either an ambulatory blood pressure monitoring device or into a computer readout device. The circuitry contained within the removable RAM package is able to determine if it is properly inserted into either the ambulatory blood pressure monitoring device or into the computer readout device before it energizes the RAM. The circuitry in the removable RAM package thereby prevents spurious signals on the input terminals of the package from destroying data contained within the removable RAM package. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     In the Drawing: 
     FIGS. 1a and 1b illustrate the circuitry of the removable RAM package of the present invention; 
     FIG. 2 illustrates the edge connector of the removable RAM package of the present invention; and 
     FIG. 3 is a schematic diagram showing the manner in which the power interlock of the present invention operates. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring generally to FIG. 1, the removable RAM package 10 of the present invention is comprised of RAM 12, a real time timer circuit 14, a dual one shot monostable multivibrator 16, and a voltage regulator 18. In the preferred embodiment of the invention the RAM 12 is a 2K×8 CMOS static RAM such as an HM6116, and the real time timer circuit 14 is a National Semiconductor MM58167 Microprocessor Compatible Real Time Clock Circuit. 
     The RAM 12 has a series of data lines D0-D7 and address lines A0-A10, an output enable line 20, a write enable line 22, and ground and positive power supply connections 24, 26, respectively. The real time timer 14 also has a series of data lines D0-D7, which are connected to the data lines D0-D7 of the RAM 12 on a common data bus 28. The real time timer circuit 14 is also connected to address lines A0-A4 on an address bus 30 which is also connected to the RAM 12. Each of the lines of the data bus 28 and each of the lines of the address bus 30 are connected to ground via a series of 100K resistors 32, 34, respectively. 
     It is very important, for the proper operation of the removable RAM package 10, for the circuitry to be able to know when the removable RAM package 10 is properly plugged into either an ambulatory monitoring device or into the computer readout device, either of which may hereinafter be referred to as an &#34;external device&#34;. In order to prevent data stored in the RAM 12 or timing parameters stored in the real time timer 14 from being changed, a mechanism, comprising a combination of elements, is provided for assuring that the removable RAM package 10 is properly connected to an appropriate external device. 
     Referring now also to FIG. 2, an end view of the edge connector 36 which is used to connect the removable RAM package 10 to an external device is shown. The contacts on the edge connector 36 are numbered from 1 through 34, as shown, with the odd numbered contacts being on the top of the edge connector 36 and the even numbered contacts being on the bottom of the edge connector 36. With reference now to FIG. 3, contact number 2 and contact number 33 are connected together in the removable RAM package 10 via a jumper 38. Similarly, contact number 1 and contact number 2 are connected together via a jumper 40 in the external device (represented by the left side of the vertical dashed line). Accordingly, only when the edge connector 36 is fully inserted into the external device will full contact be made all along the edge connector 36, as represented by the contacts numbered 1 and 2 at one edge of the connector and the contacts number 33 at the distant edge of the connector 36, making full electrical contact. Accordingly, only then will line number 1 on the edge connector 36 of the removable RAM package 10 be connected to a RAM INTERLOCK POWER FAIL line (line number 33 on edge connector 36) in the external device. 
     With reference again to FIG. 1, once the edge connector 36 is fully plugged into the external device, the positive power supply voltage of the external device (on the RAM INTERLOCK POWER FAIL line 33 of the edge connector 36) will be present on line 1 of edge connector 36. The RAM INTERLOCK POWER FAIL line is the input to an inverter circuit 46. Normally, the input to inverter circuit 46 is kept low by a 10K pull-down resistor 48 when the removable RAM package 10 is not connected to an external device. When the removable RAM package 10 is properly connected to an external device, the output of the inverter 46 goes low. The negative going signal at the input of the dual one shot 16, a Motorola MC14538 integrated circuit in the preferred embodiment of the invention, causes line 52 to NAND gate 54 to go low for approximately 1.25 seconds (based upon the values of R3, R4, C2, and C3). That causes the output of NAND gate 54 to go high for approximately 1.25 seconds, causing the output of OR gate 56 to go high. The high output on OR gate 56 brings the output of NAND gate 58, corresponding to the READY signal on line 28 of edge connector 36, low. 
     The high output signal from OR gate 56 also causes the outputs of OR gates 60, 62, and 64 to go high. High outputs from gates 60, 62, and 64 disable the RAM and timer chips 12, 14. Both the RAM and timer chips 12, 14 remain disabled until there are no more transitions on the RAM INTERLOCK POWER FAIL line for more than 1.25 seconds. Any additional upward transitions on the RAM INTERLOCK POWER FAIL line will keep the RAM and timer chips 12, 14 disabled for the reasons set forth above. Similarly, any additional downward transitions on the RAM INTERLOCK POWER FAIL line will keep the RAM and timer chips 12, 14 disabled for 1.25 seconds, as the input line 53 to NAND gate 54 will be forced low. Accordingly, the signal on the RAM INTERLOCK POWER FAIL line must be stable in a high state for more than 1.25 seconds to allow the one shot 16 to stop timing out and to cause its pin 7 to go high thereby causing the output of NAND gate 54 and OR gate 56 to go low and stay low. This also causes the output of NAND gate 58 to go high, i.e. placing a high signal on the READY line, indicating to the external device that the removable RAM package 10 is ready for data acquisition. The same signal also allows writes to the RAM and timer chips 12, 14 since the outputs of OR gates 60, 62, and 64 will be controlled by the Write Enable and Chip Enable signals on edge connector 36 lines 23, 26, and 27, respectively, since the RAM INTERLOCK POWER FAIL controlled inputs of OR gates 60, 62, and 64 will be low, so the outputs of OR gates 60, 62, and 64 will be controlled exclusively by the inputs from the external device on lines 23, 26, and 27 of the edge connector 36.