Pulse oximetry testing
First Claim
1. An apparatus for testing a pulse oximeter having means for optically sensing SpO2 values of living tissue, electrical drive means for electrically activating the optically sensing means, and electrical signal processing means responsive to the optically sensing means for producing an oximeter signal corresponding to the SpO2 value being sensed, said testing apparatus comprising:
- first testing means bypassing the optically sensing means and responsive to the electrical drive means for generating selected first electrical test signals respectively representative of selected SpO2 values in living tissue and for transmitting said first signals to the electrical signal processing means to test the ability of the signal processing means to process said representative SpO2 values and produce oximeter signals corresponding to the selected SpO2 values represented by the test signals generated, and second testing means for generating second electrical test signals, for transmitting the same to the optically sensing means, for receiving response signals from the optically sensing means in response to transmission of the second test signals, and for providing an indication of said response signals thereby to test the optically sensing means separately from said testing by the first testing means.
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Abstract
A method and apparatus for testing a pulse oximeter which is based on the concept of an electrical interface between the testing instrument and the oximeter rather than an optical interface. The pulse oximeter signal processor is tested separately from the probe, and still further, the optical elements, that is, the LEDs and the photodiode, of the probe are tested separately from the probe cable. With the probe disconnected from the oximeter, a modulated electrical test signal representative of SpO2 values and other parameters is generated in response to an electrical signal from the oximeter, and the test signal is applied to the oximeter signal processor, whereby the display of the oximeter shows a value of SpO2 which is compared with the SpO2 value represented by the test signal. Independently, the probe including the probe cable, the LEDs and the photodiode are respectively and separately subjected to continuity and optical sensitivity tests. Each of the main components of the oximeter is thereby separately analyzed, and the source of a defect is isolated.
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Citations
91 Claims
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1. An apparatus for testing a pulse oximeter having means for optically sensing SpO2 values of living tissue, electrical drive means for electrically activating the optically sensing means, and electrical signal processing means responsive to the optically sensing means for producing an oximeter signal corresponding to the SpO2 value being sensed, said testing apparatus comprising:
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first testing means bypassing the optically sensing means and responsive to the electrical drive means for generating selected first electrical test signals respectively representative of selected SpO2 values in living tissue and for transmitting said first signals to the electrical signal processing means to test the ability of the signal processing means to process said representative SpO2 values and produce oximeter signals corresponding to the selected SpO2 values represented by the test signals generated, and second testing means for generating second electrical test signals, for transmitting the same to the optically sensing means, for receiving response signals from the optically sensing means in response to transmission of the second test signals, and for providing an indication of said response signals thereby to test the optically sensing means separately from said testing by the first testing means. - View Dependent Claims (2, 30, 31, 32, 33, 34)
the optically sensing means includes an LED, a photodiode for producing an electrical output signal in response to activation of the LED, a first electrical circuit including the LED, and a second electrical circuit including the photodiode, said drive means being connected to the first electrical circuit for electrically activating the optically sensing means, said oximeter further including driven means interconnecting the second electrical circuit and the signal processing means for transmitting the electrical output signal from the photodiode to the signal processing means;
wherein said first testing means is capable of transmitting said first test signals instead of said photodiode output signal, to the driven means for testing the drive means, the driven means and the signal processing means, said second test signals including electrical continuity test signals and electrical sensitivity test signals, wherein said second testing means is capable of conducting the electrical continuity test signals through both of said first and second circuits to provide electrical continuity outputs, wherein said second testing means is capable of conducting the electrical sensitivity test signals through said first circuit to provide an electrical sensitivity output in the second circuit, and further including means for sensing said electrical continuity and sensitivity outputs from said circuits in response to said continuity and sensitivity test signals to test both the continuity and the optical sensitivity of the optical sensing means.
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30. The apparatus of claim 1,
wherein said first and second testing means are capable of independently but simultaneously testing the signal processing means and the optically sensing means. -
31. The apparatus of claim 1,
wherein there is a housing enclosing both the first and second testing means, and wherein there are spaced first and second connector means on the housing respectively connected to the first and second testing means and respectively adapted to be connected to the signal processing means and the optically sensing means. -
32. The apparatus of claim 1,
wherein there are microprocessor means for controlling the first and second testing means to enable the first and second testing means to test either the signal processing means or the optically sensing means separately or to test both the signal processing means and the sensing means simultaneously. -
33. The apparatus of claim 1 wherein the optically sensing means includes an LED, a photodiode for producing an electrical output signal in response to activation of the LED, a first electrical circuit including the LED, and a second electrical circuit including the photodiode, said drive means being connected to the first electrical circuit for electrically activating the optically sensing means, said oximeter further including driven means interconnecting the second electrical circuit and the signal processing means for transmitting the electrical output signal from the photodiode to the signal processing means;
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wherein said first testing means is capable of transmitting said first test signals, instead of said photodiode output signal, to the driven means for testing the drive means, the driven means and the signal processing means, wherein said second test signals are electrical continuity test signals, wherein said second testing means is capable of conducting the electrical continuity test signals respectively through said first and second circuits to provide electrical continuity outputs, and wherein there are means for sensing said electrical continuity outputs and displaying an indication of the continuity of the optical sensing means.
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34. The apparatus of claim 1 wherein the optically sensing means includes an LED, a photodiode for producing an electrical output signal in response to activation of the LED, a first electrical circuit including the LED, and a second electrical circuit including the photodiode, said drive means being connected to the first electrical circuit for electrically activating the optically sensing means, said oximeter further including driven means interconnecting the second electrical circuit and the signal processing means for transmitting the electrical output signal from the photodiode to the signal processing means;
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wherein said first testing means is capable of transmitting said first signals, instead of said photodiode output signal, to the driven means for testing the drive means, the driven means and the signal processing means, wherein said second test signals are electrical sensitivity test signals, wherein said second testing means is capable of conducting the electrical sensitivity test signals through said first circuit to provide electrical sensitivity outputs in the second circuit, and wherein there are means for sensing said electrical sensitivity outputs and displaying an indication of the optical sensitivity of the optical sensing means.
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3. An apparatus for testing a pulse oximeter capable of sensing the SpO2 in living tissue and including a probe including LEDs and a photodiode;
- and an electronic unit including an LED driver providing output signals for activating the LEDs, an electronic signal processor for receiving and processing input signals from the photodiode in response to activation of the LEDs, and a display for showing the SpO2 values represented by the input signals, said probe releasably interconnecting the LED driver and the LEDs and the photodiode and the signal processor, comprising;
means operable with the probe disconnected from the LED driver and the signal processor for providing electrical test signals in response to output signals from the LED driver;
means for modulating said electrical test signals so as to provide modulated electrical test signals representative of selected SpO2 values corresponding to those in living tissue; and
means for transmitting said modulated electrical test signals to the signal processor in place of said input signals to cause the signal processor to process the test signals as if they were said input signals whereby SpO2 values shown on the display can be compared with a range of selected SpO2 values corresponding to the modulated electrical test signals thereby to test said electronic unit over its normal operating range. - View Dependent Claims (4, 5, 35)
electronic memory means adapted to store an SpO2 profile including a plurality of SpO2 values which vary over a predetermined time base; and
wherein said modulating means is adapted to modulate said electrical test signals with selected SpO2 profiles so as to provide modulated electrical test signals representative of selected SpO2 profiles.
- and an electronic unit including an LED driver providing output signals for activating the LEDs, an electronic signal processor for receiving and processing input signals from the photodiode in response to activation of the LEDs, and a display for showing the SpO2 values represented by the input signals, said probe releasably interconnecting the LED driver and the LEDs and the photodiode and the signal processor, comprising;
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5. The apparatus of claim 4 further including:
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display means;
wherein said electronic memory means is also adapted to store a cursor for said profiles, wherein said modulating means is further adapted to feed a selected SpO2 profile and said cursor to said display means so that a selected profile and cursor can be displayed, wherein said memory means, said modulating means and said display means cooperate to cause the cursor to move in steps over the displayed profile at a predetermined rate stored in said memory, with the position of the cursor at each step indicating on the display means the value of SpO2 then modulating the test signal whereby the oximeter can be tested with said profile of SpO2 values sequentially delivered to the signal processor.
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35. The apparatus of claim 3,
wherein the apparatus includes means for displaying the values of SpO2 represented by the modulated electrical test signals whereby SpO2 values showing on the oximeter display can be compared with selected SpO2 values showing on the displaying means thereby to determine the accuracy of the oximeter throughout a range of SpO2 values.
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6. An apparatus for testing the probe of a pulse oximeter having an electronic unit including an LED driver and an electronic signal processor;
- said probe including red and IR LEDs, a photodiode, and a probe cable, said probe cable being releasably connected to the driver and the signal processor when the probe is being used to sense the SpO2 of living tissue and to feed a signal representative of the same to the signal processor, comprising;
means for supplying current to the LEDs and the photodiode while the probe is disconnected from the driver and the signal processor to provide electrical continuity outputs from the LEDs and the photodiode;
means for driving the LEDs while the probe is disconnected from the driver and the signal processor so as to activate the photodiode and provide electrical sensitivity outputs from the photodiode; and
means for sensing said outputs thereby to indicate the sensitivity and the continuity of the probe.
- said probe including red and IR LEDs, a photodiode, and a probe cable, said probe cable being releasably connected to the driver and the signal processor when the probe is being used to sense the SpO2 of living tissue and to feed a signal representative of the same to the signal processor, comprising;
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7. An apparatus for testing a pulse oximeter probe which includes optical sensing means providing an LED circuit including red and IR LEDs and a photodiode circuit including a photodiode, there being an interactive red LED-photodiode combination and an interactive IR LED-photodiode combination, said LED circuit, said photodiode circuit, said interactive red LED-photodiode combination, and said interactive IR LED-photodiode combination constituting first, second, third, and fourth parts, respectively, of the optical sensing means capable of being tested for continuity and sensitivity, comprising:
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current supply means simultaneously connectable to the LED and photodiode circuits for causing testing current to flow in at least one of said circuits and for producing test output signals representative of the test results on at least one of said parts of the optical sensing means; and
means for receiving the test output signals and being responsive to the magnitude thereof to produce an indication of the results of said test to a user of the apparatus. - View Dependent Claims (8, 9, 10)
wherein said current supply means and said receiving means interact to produce test output signals each of which individually represents the test results for one of said parts of the optical sensing means, and wherein said indicator means is capable of indicating each of said individual output signals, whereby selected parts of the optical sensing means can be separately analyzed.
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9. The apparatus of claim 7, further including:
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indicator means;
wherein for said continuity test, the current supply means is adapted to supply current simultaneously to each of said circuits thereby to produce LED circuit continuity output test signals and photodiode circuit continuity output test signals;
wherein said receiving means includes means for multiplexing said continuity output test signals and means for feeding said multiplexed output test signals to said indicator means; and
wherein said indicator means is adapted separately to indicate the LED and photodiode continuity output signals thereby to enable individual analysis of the continuity of the LED and photodiode circuits.
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10. The apparatus of claim 7, further including:
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indicator means;
wherein said receiving means includes microprocessor means;
wherein, for said sensitivity test, the microprocessor means is adapted to cause the current supply means to alternately supply current to the red LED and the IR LED whereby said test output signals are alternately red sensitivity signals and IR sensitivity signals, said microprocessor means being adapted to develop red sensitivity/IR sensitivity ratio signals from said red and IR sensitivity signals, and said indicator means being adapted to indicate said red sensitivity signals, said IR sensitivity signals, and said red sensitivity/IR sensitivity ratio signals to a user of the apparatus, thereby to enable the user to analyze the sensitivity of said third and fourth parts of the optical sensing means.
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11. An apparatus for testing the continuity of a pulse oximeter probe which provides an LED circuit and a photodiode circuit, said apparatus comprising:
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means for activating each of said circuits so as to produce an electrical test output in each circuit representative of whether the circuit is open, continuous or shorted;
means for separating the test outputs representing the LED circuit from the test outputs representing the photodiode circuit; and
means for analyzing each of said outputs to determine whether or not the LED circuit or the photodiode circuit is open, continuous or shorted. - View Dependent Claims (12, 13, 14)
said activating means is adapted to activate said photodiode circuit by causing current to flow in a direction in said photodiode circuit opposite to the direction current flows when light activates the photodiode.
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13. The apparatus of claim 11,
wherein said analyzing means includes display means providing separate channels respectively associated with the test outputs of the LED and photodiode circuits, and wherein said analyzing means is capable of displaying representations of said test outputs in the respective channels for the LED and photodiode circuits so that a predetermined representation indicates whether the respective circuit is open, continuous, or shorted. -
14. The apparatus of claim 11,
wherein said analyzing means includes display means, wherein said analyzing means is capable of displaying representations of said test outputs on the display means so that a predetermined representation represents a circuit that is open, continuous, or shorted, and wherein said analyzing means is capable of freezing the representation on the display means when a circuit is open or shorted.
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15. An apparatus for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs an a photodiode adapted to be alternately activated by said LEDs, said apparatus comprising:
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means for electrically alternately activating the LEDs so as to produce electrical red and IR sensitivity test output signals from the photodiode;
means for producing red sensitivity/IR sensitivity ratio signals from said red and IR test output signals; and
means for indicating each of said red sensitivity, IR sensitivity and red sensitivity/IR sensitivity ratio signals to determine the sensitivity of the optical sensing means. - View Dependent Claims (16, 17, 43)
wherein said activating means is adapted alternately to supply relatively low and relatively high current to the red and IR LEDs to produce alternately low and high red signals and low and high IR signals, said apparatus further including means for subtracting the low red from the high red signal and the low IR and from the high IR, and wherein said producing means is adapted to produce said red sensitivity signal from the difference between the high and low red signals and to produce said IR sensitivity signal from the difference between the high and low IR signals. -
17. The apparatus of claim 15,
wherein said indicating means includes display means for respectively separately displaying said red and IR sensitivities and said red sensitivity/IR sensitivity and said red sensitivity/IR sensitivity ratio. -
43. The apparatus of claim 15,
wherein said indicating means includes display means for respectively displaying bargraphs in separate channels of said red and IR sensitivities and said red sensitivity/IR sensitivity ratio.
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18. A method for testing a pulse oximeter having means for optically sensing SpO2 values in living tissue, means for electrically activating the optically sensing means, and electrical means responsive to the optically sensing means for indicating the SpO2 value in tissue being sensed, said method comprising the steps of:
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generating first test signals representative of SpO2 values in living tissue in response to the electrically activating means and independently of the optically sensing means, transmitting the first test signals to the electrical responsive means independently of the optically sensing means to test the ability of the oximeter to indicate said representative SpO2 values, generating a second test signal independently of the electrically activating means for testing the optically sensing means, transmitting the second test signal to the optically sensing means independently of the electrically activating means, and receiving an output from the optically sensing means indicative of the responses of the optically sensing means to the second test signal, thereby to test the operability of the optically sensing means. - View Dependent Claims (19, 20, 44, 45)
wherein said generating step for testing the optically sensing means is capable of testing the electrical continuity of the optically sensing means. -
20. The method of claim 18, including the further step of:
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disconnecting the optically sensing means from the electrically activating means and the electrical responsive means, wherein said generating step includes receiving an output signal from the electrically activating means and modulating said output signal so as to provide a modulated test signal representative of a selected value of SpO2 corresponding to that in living tissue; and
wherein said transmitting step involves transmitting said modulated test signal to the electrical responsive means so as to provide a modulated test signal representative of a selected value of SpO2 corresponding to that in living tissue.
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44. The method of claim 18,
wherein said generating step for testing the optically sensing means is capable of testing the optical sensitivity of the optically sensing means. -
45. The method of claim 19,
wherein said generating step for testing the optically sensing means is capable of testing the optical sensitivity of the optically sensing means.
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21. A method for testing a pulse oximeter over a range of values of SpO2 expected to exist in living tissue said oximeter having a probe including LEDs and a photodiode;
- and an electronic unit including an LED driver providing an output signal for activating the LEDs, an electronic signal processor for receiving and processing input signals from the photodiode representative of SpO2 values in living tissue in response to activation of the LEDs, and a display for showing the SpO2 values represented by the input signals, said probe releasably interconnecting the LED driver and the LEDs and the photodiode and the signal processor, comprising the steps of;
disconnecting the probe from the driver and signal processor;
generating an electrical test signal in response to the output signal from the LED driver;
modulating said electrical test signal so as to provide a modulated electrical test signals representative of selected SpO2 values in living tissue;
transmitting said modulated electrical test signals to the signal processor in place of said input signals to cause the signal processor to process the test signals as if they were said input signals thereby to test said electronic unit and, displaying the selected SpO2 values so that a comparison can be made with the SpO2 values displayed by the oximeter display to determine the accuracy of the oximeter over a range of SpO2 values. - View Dependent Claims (22, 23)
electronically storing an SpO2 profile including a plurality of SpO2 values which vary over a predetermined time base; and
wherein said modulating step is adapted to modulate said electrical test signals with selected SpO2 profiles so as to provide modulated electrical test signals representative of selected SpO2 profiles.
- and an electronic unit including an LED driver providing an output signal for activating the LEDs, an electronic signal processor for receiving and processing input signals from the photodiode representative of SpO2 values in living tissue in response to activation of the LEDs, and a display for showing the SpO2 values represented by the input signals, said probe releasably interconnecting the LED driver and the LEDs and the photodiode and the signal processor, comprising the steps of;
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23. The method of claim 22 including the further steps of:
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electronically storing a cursor for said profiles and a stepping rate for the cursor, displaying a selected profile and said cursor; and
moving the cursor in steps over the displayed profile at said stepping rate so that the position of the cursor at each step indicates the value of SpO2 then modulating the test signal whereby the oximeter can be tested with said profile of SpO2 values sequentially delivered to the signal processor.
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24. A method for testing a pulse oximeter probe which includes optical sensing means providing an LED circuit including red and IR LEDs and a photodiode circuit including a photodiode, there being an interactive red LED-photodiode combination and an interactive IR LED-photodiode combination, said LED circuit, said photodiode circuit, said interactive red LED-photodiode combination, and said interactive IR LED-photodiode combination constituting first, second, third, and fourth parts, respectively, of the optical sensing means one or more of which is capable of being tested for the parameters of continuity and sensitivity, comprising the steps of:
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electrically activating said circuits so as to produce electrical test output signals which are representative of at least one of the parameters to-be-tested; and
sensing the test output signals and displaying an indication of whether one or more of said parts meet the standards established for said at least one of the parameters to-be-tested. - View Dependent Claims (25, 26, 27, 28, 47)
said activating step activates the circuits so as to produce output test signals which are not affected by ambient light on the photodiode.
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26. The method of claim 24, wherein:
said activating step involves causing current to flow in the photodiode circuit in the opposite direction from that occurring when the photodiode is activated by light.
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27. The method of claim 24, wherein:
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said activating step involves alternatively supplying high and low current pulses in the red and IR LED circuits, respectively, to produce alternate red high and red low test output signals and IR high and IR low test output signals, said activating step further involving subtracting red low signals from the corresponding red high signals and IR low signals from the corresponding IR high signals, thereby to produce said red sensitivity and said IR sensitivity signals, respectively, and including the further step of generating red sensitivity/IR sensitivity ratio signals from said red sensitivity and said IR sensitivity signals, and wherein said sensing step involves analyzing said red and IR sensitivity signals and said red sensitivity/IR sensitivity ratio signals thereby to determine the sensitivity of the optically sensing means.
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28. The method of claim 24, further including the step of:
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displaying graphical representations of the test output signals sensed from said circuits thereby to indicate the condition of the continuity of said circuits, and displaying graphical representations of the test output signals sensed from the photodiode thereby to indicate the sensitivity of the optically sensing means.
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47. The method of claim 24 which involves the use of a testing device capable of performing said activating, sensing and displaying steps, further including the step of:
electrically connecting the testing device simultaneously to both the LED and photodiode circuits prior to said electrically activating step thereby to enable testing of selected ones of said parts.
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29. A method for testing the continuity of a pulse oximeter probe which provides an LED circuit and a photodiode circuit, comprising the steps of:
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activating each of said circuits so as to produce an electrical test output in each circuit representative of whether the circuit is open, continuous or shorted;
separating the test outputs representing the LED circuit from the test outputs representing the photodiode circuit; and
analyzing each of said outputs to determine whether or not the LED circuit or the photodiode circuit is open, continuous or shorted. 30. The method of claim 29, wherein said analyzing step further includes; displaying representations of said test outputs so that a predetermined representation represents a circuit that is open, continuous, or shorted, and freezing the representation when a circuit is open or shorted.
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36. An apparatus for testing the continuity of a pulse oximeter probe which provides LED and photodiode circuits connected to LED and photodiode terminals of a probe connector, said apparatus comprising:
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means simultaneously connectable to the LED and photodiode terminals of the probe connector for activating each of said circuits so as to produce an electrical test output in each circuit representative of whether the circuit is open, continuous or shorted; and
means responsive to said test outputs for displaying indicia representing whether said LED and photodiode circuits are open, continuous or shorted.
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37. The apparatus of claim 37,
wherein the activating means is a current source for each of said circuits.
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38. The apparatus of claim 38,
wherein the current sources are simultaneously connectable to their respective LED and photodiode circuits, and wherein the activating means causes current from the current sources to supply current simultaneously to said circuits.
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41. The apparatus of claim 41,
wherein the combining means combines the test outputs into a combined analog signal with said alternating LED and photodiode pulses, wherein there are means for converting the combined analog signal into discrete digital signals representative of said LED and photodiode pulses; - and
wherein there are means for sampling the digital signals and displaying the same to indicate whether or not the LED circuit or the photodiode circuit is open, continuous or shorted.
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42. An apparatus for testing the continuity of a pulse oximeter probe that has an LED circuit and a photodiode circuit, comprising
means for supplying testing current to each of the LED and photodiode circuits to produce responses including separate analog LED and photodiode continuity voltages, means for combining said voltages into a single voltage signal with alternating LED and photodiode pulses, means for converting the single voltage signal into a series of discrete digital voltage pulses representative of the alternating LED and photodiode pulses, means for sampling the digital voltage pulses, display means, and means for activating the display means with the signal samples to indicate whether the LED and photodiode circuits are open, continuous, or shorted.
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46. A method for testing a pulse oximeter probe which includes optical sensing means providing an LED circuit including red and IR LEDs and a photodiode circuit including a photodiode, there being an interactive red LED-photodiode combination and an interactive IR LED-photodiode combination said LED circuit, said photodiode circuit, said interactive red LED-photodiode combination, and said interactive IR LED-photodiode combination constituting first, second, third, and fourth parts, respectively, of the optical sensing means to be subjected to such testing including the parameters of continuity and sensitivity, comprising the steps of:
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electrically activating said circuits so as to produce electrical test output signals which are representative of the parameters to-be-tested of said parts;
electrically separating the test output signals so that there is a test output signal representative of continuity for each of said first and second parts and a test output signal representative of the sensitivity for each of said third and fourth parts;
and analyzing each of said output signals to determine whether or not said parts meet the standards established for said parameters.
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48. A method for testing the continuity of a pulse oximeter probe that includes an LED circuit and a photodiode circuit, comprising the steps of:
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simultaneously connecting electrical activating means to both of the LED and photodiode circuits, electrically activating each of said circuits with test signals thereby to produce an electrical test output in each circuit representative of whether the circuit is open, continuous or shorted; and
processing the test outputs to provide a visual indication of whether or not each circuit is open, continuous or shorted.
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49. The method of claim 49,
wherein the activating step involves simultaneously supplying said test signals in the form of current fed to each of said circuits from separate current sources respectively associated with said circuits.
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51. The method of claim 51,
wherein the moving step causes a voltage spike in said test output of the circuit in which an intermittent short or open condition exists; and wherein the processing step is responsive to the voltage spike to provide a visual indication of the same, whereby such intermittent short or open conditions are not overlooked by the user performing the test.
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52. A method for testing the continuity of a pulse oximeter probe that has an LED circuit and a photodiode circuit, comprising the steps of:
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supplying current to both the LED and photodiode circuits to produce responses including separate LED and photodiode continuity voltages;
sensing said responses and combining them into a single voltage signal with alternating LED and photodiode pulses;
converting the single voltage signal into a series of discrete voltage pulses representative of the alternating LED and photodiode pulses; and
using the discrete voltage pulses to display indications of whether the LED and photodiode circuits are open, continuous or shorted.
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53. An apparatus for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs and a photodiode, said apparatus comprising:
- 54. The apparatus of claim 54,
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55. An apparatus for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs and a photodiode, said apparatus comprising:
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56. A method for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs and a photodiode, comprising the steps of:
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57. The method of claim 57,
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58. An oximeter tester for an oximeter that includes a signal processor, an LED driver and a probe including LED and photodiode circuits respectively including light emiting diodes and a photodiode, the probe being releasably connected to the signal processor and the LED driver, the tester comprising:
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59. An apparatus for testing a pulse oximeter having an optical sensor that senses SpO2 values of living tissue, an electrical driver that produces an electrical signal that activates the optical sensor, and a signal processor responsive to the optical sensor that produces an oximeter signal corresponding to the SpO2 value being sensed, said testing apparatus comprising:
forfirst testing circuitry that is responsive to the signal from the electrical driver in the oximeter, that generates first electrical test signals that are SpO2 waveforms simulating those generated by the probe of the oximeter when the oximeter is used to check the blood oxygen level of a patient, and that transmits said first signals to the signal processor of the oximeter independently of the optical sensor,
- 60. The testing apparatus of claim 60,
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61. The apparatus of claim 61,
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66. An apparatus for testing the probe of a pulse oximeter, said probe including an LED, a photodiode, and a probe connector with LED and photodiode terminals respectively connected to the LED and photodiode, the testing apparatus comprising:
- 67. The apparatus of claim 67, the probe having LED and photodiode circuits respectively including the LED and the photodiode,
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69. The apparatus of claim 69, the probe having red and IR LEDs,
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70. A method for testing the continuity of a pulse oximeter probe that includes an LED circuit and a photodiode circuit, said method involving the use of a tester having a tester connector providing terminals connected to an electrically actuating source and a sensor in the tester, and a probe connector providing terminals connected to said circuits, comprising the steps of:
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71. A method for testing the sensitivity of a pulse oximeter probe that has red and IR LED circuits and a photodiode circuit including a photodiode, said method involving the use of a tester having a tester connector providing terminals connected to an electrically actuating source and a sensor in the tester, and a probe connector providing terminals connected to said circuits, comprising the steps of:
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72. A pulse oximeter testing apparatus for testing a pulse oximeter having an optical sensor that senses SpO2 values of living tissue, an electrical driver that produces an electrical signal that activates the optical sensor, and a signal processor responsive to the optical sensor that produces an oximeter signal corresponding to the SpO2 value being sensed, said testing apparatus comprising:
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73. The combination of a pulse oximeter and a testing apparatus, the oximeter having a signal processor, a display and a probe, the probe normally receiving signals from the oximeter and delivering modulated human signals to the signal processor resulting from a human finger or other body part placed in the probe,
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74. An apparatus for testing a pulse oximeter having an optical sensor that senses SpO2 values of living tissue, an LED driver, a signal processor responsive to the optical sensor that produces an oximeter signal corresponding to the SpO2 value being sensed and a display, said testing apparatus comprising:
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75. An apparatus for testing a pulse oximeter having an optical sensor that senses SpO2 values of living tissue, a signal processor responsive to the optical sensor that produces an oximeter signal corresponding to the SpO2 value being sensed, and a display that displays the said SpO2 values sensed, the testing apparatus comprising:
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76. An oximeter probe tester for an oximeter probe having LED and photodiode circuits, comprising:
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77. An oximeter probe tester for an oximeter probe having a LED circuit including LEDs and a photodiode circuit including a photodiode, comprising:
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78. An oximeter probe tester for an oximeter probe having an LED circuit including LEDs and a photodiode circuit including a photodiode, comprising:
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80. The apparatus of claim 80,
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81. A method for testing a pulse oximeter with a testing instrument wherein the oximeter includes a probe, an LED driver, a signal processor, an oximeter interface connector connected to the signal processor and the LED driver, the probe including LEDs, a photodiode, and a probe connector connected to the oximeter interface connector in normal use of the oximeter, the LEDs being responsive to LED drive signals from the LED driver and the photodiode generating SpO2 waveforms for delivery to the signal processor through the oximeter interface connector when the probe is attached to the human being, and wherein the testing instrument includes a housing, a probe testing connector mounted on the housing, and a simulator testing connector mounted on the housing, the method comprising the steps of:
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82. A method for testing either the continuity or the sensitivity or both of a pulse oximeter probe that has an LED circuit including red and IR LEDs, a photodiode circuit including a photodiode, and a probe connector, the method involving the use of a housing enclosing electrically activating sources and signal sensing circuitry and mounting a probe testing connector providing LED and photodiode terminals connected to the electrically activating sources and the signal sensing circuitry, the method comprising the steps of:
- 83. A method for isolating defects among certain parts of pulse oximeters by enabling said parts to be tested separately, each such oximeter having two principal parts, namely, a main instrument and a probe respectively connected to a main interface connector and a probe interface connector, the interface connectors being separately connected to each other in the normal operation of an oximeter when monitoring the SpO2 values of living tissue wherein the probe produces SpO2 waveforms of the living tissue being monitored and transmits those waveforms to the main instrument to indicate thereon certain characteristics of said waveforms, the method involving the use of a testing apparatus that includes a simulator that can be drive to generate simulated SpO2 waveforms corresponding to those produced by the probe in said normal operation and a signal processor driver capable of driving the main instrument of the oximeter like the probe does in said normal operation, the testing apparatus further including a probe driver-sensor unit capable of activating the probe and sensing responses therefrom, a housing enclosing the simulator, the signal processor driver, and the probe driver-sensor unit, first and second testing interface connectors mounted on the housing, a display mounted on the housing and connected to the probe driver-sensor unit to display indications of characteristics of said responses, and a microprocessor in the housing connected to the simulator, the probe driver-sensor unit, and the display for controlling the actions thereof, the method comprising the steps of:
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84. A method for isolating defects among certain parts of pulse oximeters by enabling said parts to be tested separately, each such oximeter having two principal parts, namely, a main instrument and a probe, each such main instrument including as subsidiary parts a signal processor and an LED driver connected to an main interface connector, and each such probe including as subsidiary parts an LED circuit including red and IR LEDs and a photodiode circuit including a photodiode, said circuits terminating in a probe interface connector, the interface connectors of a main instrument and a probe being separately interconnected in the normal operation of an oximeter when monitoring the SpO2 values of living tissue wherein the LED driver activates the LEDs which in turn activate the photodiode and cause the photodiode to produce SpO2 waveforms of the living tissue being monitored and to transmit those waveforms to the signal processor that in turn drives the display to indicate certain characteristics of said waveforms, the method involving the use of a testing apparatus that includes a simulator that can be driven to generate simulated SpO2 waveforms corresponding to those produced by the photodiode in said normal operation and a signal processor driver capable of driving the signal processor of the oximeter like the photodiode does in said normal operation, the testing apparatus further including a probe driver-sensor unit capable of activating the LED and photodiode circuits and sensing responses therefrom, a housing enclosing the simulator, the signal processor driver, and the probe driver-sensor unit, first and second testing interface connectors mounted on the housing, the first testing interface connector being connected to the simulator and the signal processor driver and the second testing interface connector being connected to the probe driver-sensor unit, a display mounted on the housing and connected to the probe driver-sensor unit to display indications of the characteristics of said responses, and a microprocessor in the housing connected to the simulator, the probe driver-sensor unit, and the display for controlling the actions thereof, the method comprising the steps of:
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85. The method of claim 85,
wherein if the probe interface connector is connected to the second testing interface connector, causing the probe driver-sensor to activate the LED and photodiode circuits with continuity signals thereby causing the responses to be indicative of the continuity of said circuits.
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88. A method for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs and a photodiode, comprising the steps of:
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89. The method of claim 89,
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90. A method for testing the sensitivity of a pulse oximeter probe which provides red and infrared LEDs and a photodiode, comprising the steps of:
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91. The method of claim 91,
Specification