CA1258494A - Automatic adjusting induction coil treatment device - Google Patents
Automatic adjusting induction coil treatment deviceInfo
- Publication number
- CA1258494A CA1258494A CA000477881A CA477881A CA1258494A CA 1258494 A CA1258494 A CA 1258494A CA 000477881 A CA000477881 A CA 000477881A CA 477881 A CA477881 A CA 477881A CA 1258494 A CA1258494 A CA 1258494A
- Authority
- CA
- Canada
- Prior art keywords
- coil
- coils
- sensing
- control means
- electrical energy
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
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Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N2/00—Magnetotherapy
- A61N2/02—Magnetotherapy using magnetic fields produced by coils, including single turn loops or electromagnets
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- Health & Medical Sciences (AREA)
- Engineering & Computer Science (AREA)
- Biomedical Technology (AREA)
- Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
- Radiology & Medical Imaging (AREA)
- Life Sciences & Earth Sciences (AREA)
- Animal Behavior & Ethology (AREA)
- General Health & Medical Sciences (AREA)
- Public Health (AREA)
- Veterinary Medicine (AREA)
- Electrotherapy Devices (AREA)
Abstract
ABSTRACT
Disclosed are arrangements for sensing the rate of change of magnetic flux density of a medical treatment coil and automatically adjusting pulses of electrical energy provided to the coil so as to properly provide therapy.
In one embodiment, a device includes a medical treatment coil, a pulse generator for producing pulses of electrical energy and supplying them to the coil, a sense coil for sensing the magnetic field produced by the coil, and a controller, responsive to the sensed magnetic field, for automatically generating a signal to the pulse generator circuitry to adjust the magnitude of the pulses. In another embodiment, the device includes first and second treatment coils and a multiplexer electrically connected to the coils for selecting either or both of the coils.
One of the coils is activated by electrical pulses from a pulse generator, A controller, electrically connected to the multiplexer, selects the other coil for sensing the strength of the magnetic field (dB/dt) produced by the first coil and for, based upon the sensed magnitude, sending a signal to the pulse generator indicating the magnitude of electrical pulses to be provided to the first coil.
Disclosed are arrangements for sensing the rate of change of magnetic flux density of a medical treatment coil and automatically adjusting pulses of electrical energy provided to the coil so as to properly provide therapy.
In one embodiment, a device includes a medical treatment coil, a pulse generator for producing pulses of electrical energy and supplying them to the coil, a sense coil for sensing the magnetic field produced by the coil, and a controller, responsive to the sensed magnetic field, for automatically generating a signal to the pulse generator circuitry to adjust the magnitude of the pulses. In another embodiment, the device includes first and second treatment coils and a multiplexer electrically connected to the coils for selecting either or both of the coils.
One of the coils is activated by electrical pulses from a pulse generator, A controller, electrically connected to the multiplexer, selects the other coil for sensing the strength of the magnetic field (dB/dt) produced by the first coil and for, based upon the sensed magnitude, sending a signal to the pulse generator indicating the magnitude of electrical pulses to be provided to the first coil.
Description
~;~5849~
-l- 66742-261 AUTOMATIC ADJUSTING INDUCTION COI~ TREATMENT DEVICE
BACKGROUND OF THE INVENTION
Field of the invention - The present invention relates to devices for automatically adjusting stimulating pulses provided to medical treatment induction coils.
Prior art - The treatment of the human body by means of magnetic field has enjoyed a long and varied history.
One current accepted medical treatment involving induction coils is the assistance in healing of broken bones by the induction of a current across the break through use of a magnetic field passing through the body.
One common configuration for such treatment is to arrange a pair of coils in a Helmholtz relation on opposite sides of the body, so that they are in a flux-aiding relation-ship. For example, a pair of coils is mounted on a cast on opposite sides of a ley in order to treat a fracture of the tibia.
- The size of the coil and the magnitude of the pulsed electrical energy provided to the coils depend upon the size of the bone being treated and the volume of human tissue which surrounds the bone and lies between treatment coils. For example, the coils used in treating a tibia fracture would naturally be larger than those used on the wrist.
In the prior art, the fitting of treatment coils involved custom design of a system for each patient. Coils would be selected and energy provided in a manner which would maximize treatment for the patient. This, of course, is a ~2~8494
-l- 66742-261 AUTOMATIC ADJUSTING INDUCTION COI~ TREATMENT DEVICE
BACKGROUND OF THE INVENTION
Field of the invention - The present invention relates to devices for automatically adjusting stimulating pulses provided to medical treatment induction coils.
Prior art - The treatment of the human body by means of magnetic field has enjoyed a long and varied history.
One current accepted medical treatment involving induction coils is the assistance in healing of broken bones by the induction of a current across the break through use of a magnetic field passing through the body.
One common configuration for such treatment is to arrange a pair of coils in a Helmholtz relation on opposite sides of the body, so that they are in a flux-aiding relation-ship. For example, a pair of coils is mounted on a cast on opposite sides of a ley in order to treat a fracture of the tibia.
- The size of the coil and the magnitude of the pulsed electrical energy provided to the coils depend upon the size of the bone being treated and the volume of human tissue which surrounds the bone and lies between treatment coils. For example, the coils used in treating a tibia fracture would naturally be larger than those used on the wrist.
In the prior art, the fitting of treatment coils involved custom design of a system for each patient. Coils would be selected and energy provided in a manner which would maximize treatment for the patient. This, of course, is a ~2~8494
-2- 66742-261 laborious process which involves initial visits for fitting and later visits for installation of the coils. The physician fitting the coils must take measurements and have a system custom designed.
What is needed in the art is a system which can automatically adjust the electrical energy provided to the coils to that therapy will be maximized.
SUMMARY OF THE INVENTION
The present invention involves means for sensing the rate of change of magnetic flux density of a medical treatment coil and automatically adjusting pulses of electric-al energy provided to the coil so as to properly provide therapy. In one embodiment, a device includes a medical -treat-ment coil, pulse generator means for producing pulses of elect-rical energy and supplying them to the coil, a sense coil for sensing the magnetic field produced by the coil, and a con-troller, responsive to the sensed magnetic field, for auto-matically generating a signal to the pulse generator circuitry to adjust the magnitude of the pulses.
In another embodiment, the device includes first and second treatment coils and a multiplexer electrically connected to the coils for selecting either or both of the coils. One of the coils is activated by electrical pulses from a pulse generator. A controller, electrically connected to the multiplexer, selects the other coil for sensing the strength of the magnetic field (dB/dt) produced by the first coil and for, based upon the sensed magnitude, sending a signal to the pulse generator means indicating the magnitude of electrical pulses to be provided to the first coil.
~L25849~
-2a- 66742-261 In accordance with a broad aspect of the invention there is provided a medical device for inducing electrical current within a patient's body by creating a magnetic field through the body comprising:
first coil for placement in a treatment relation to a patient's body;
second coil for placement in a second treatment relation to the patient's body so that the first coil and second coil are in a generally flux-aiding relation to each other;
driver circuitry for providing pulsed electrical energy to the first and second coils;
control means operably connected to the driver circuitry for controlling the magnitude of the electrical energy;
multiplexer means connected to the first coil and second coil and operably connected to the control means for selecting one coil; and the control means including means for indicating to the multiplexer means that one of the coils is selected for driving by the coil driver and the other of the coils is selected for sensing magnetic field induced by said one of the coils, and for automatically adjusting the magnitude of electrical energy produced by the driver circuitry based upon sensed magnetic field.
In accordance with another broad aspect of the invention there is provided a self-fitting electromagnetic bone growth stimulator comprising:
a first treatment coil for positioning adjacent ~25~3494 -2b- 66742-261 a patient's body;
a second treatment coil for positioning adjacent a patient's body in a flux-aiding relationship which creates a magnetic field through a portion of the patient's body;
pulse generation means electrically connected to the first coil and the second coil for providing pulses of electrical energy to the first coil and the second coil;
control means electrically connected to the pulse generating circuitry for transmitting a magnitude signal to th~ pulse generation means indicative of a magnitude of the pulses of electrical energy;
sensing circuitry electrically connected to the first and second coils for sensing a magnetic field at one coil, which was produced by the other coil and for producing a sensed field signal indicative of field strength to the control means/ the control means automatically adjusting the magnitude signal in response to the field strength signal.
In accordance with another broad aspect of the invention there is provided a device for automatically self-fitting an induction coil bone growth stimulator of the type having at least two coils for treating a patient comprising:
means for providing pulsed electrical energy to first and second coils;
means connected to the first and second coils for selecting one coil as a sense coil;
control means operably connected to the means for providing pulsed electrical energy and to the multiplexer means for indicating to the multiplexer means to select one coil for sensing, for sensing electrical current in the sense coil; and for automatically adjusting electrical energy - :1258~94 -2c- 66742-261 provided by the means for providing pulsed electrical energy.
BRIEF DESCRIPTION OF THE DRAWINGS
. _ _ Figure 1 is a fragmentary, partially cut-away, view of the leg of a human patient with first and second treatment coils mounted on a cast and feedback coils mounted within the treatment coils;
~258494 FIG. 2 ls d block did~ram o~ d medlcal Lr~dLm~
device including automatic adjustlng means of the present invention; and FIG. 3 is a layout of FlGs. 3a-3h, which are 5 electrical schematics of the devlce of FIG. 2.
- DETAILED DESCRIPTION OF THE PREFERRED EMBODlMENTS
An example of a trea~ment method using induction coils is illustrated in FIG. l where a leg 4 includes a bone 5 with a fracture. A cast 6 is mounted on leg 4 to IO immobilize it. Treatment coils 7 and 8 are mounted on opposite sides o~ leg 4 in a flux-aid1ng relationship so that a magnetic field extends through the center of both coils 7 and 8. Feedback coils 9 are small coils mounted on cast 6 within the center of coils 7 and 8.
Feedback coils 9 are illustrative of one embodiment of the present invention. Feedback coils 9 are used in this embodiment to sense the magnetic field produced by coils 7 and 8. In the preferred embodiment primarily described herein, separate feedbacks coils 9 are not us~d.
20 Instead, performance of colls 7 and 8 is checked by alternatively using one coil as d tredtment coil dnd ~he other coil dS a sense coil.
The block dia~ram of FIG. 2 illustrates the preferred embodiment in which coils 7 and 8 may each be used to 25 sense performance of the other. Th~s embodiment is centered around a microprocessor IO whlch lncludes a PROM, a latch and an address decoder.
A pair of coil driYers 12 prov1des pulses of electrical energy to treatment coils ~ and 8. An 30 overcurrent detection and latch circuit 16 senses when pulses provided by coil driver circultry 12 exceeds a specified maximum peak current.
Microprocessor IO communicates through first coil drive line 18 and second coil drlve line 20 with coil 35 driver circuitry 12. Should overcurrent detect and latch circuit 16 detect a threshold value put out by coil driver 4 ~Z~8494 circuitry 12, it communicdtes with microprocessor 10 through line 22, indicdting that the system is in overcurrent mode. Microprocessor 10 uses line 24 to clear the latch of overcurrent detect and latch circuitry 16.
S Such an overcurrent could be caused by such thlngs as a short ln a coil, a faulty coll, or a faulty cable.
The power to be used by coil driver circuitry 12 for producing pulses of electrical energy is supplied by cotl drive buffer 26 and energy storage capacitor 28. This 10 process also involves digital to dnalog converter 30.
Microprocessor 10 provides a digital signal indicdLive of desired pulse amplitude to di~ital to analog converter 30.
From this, digital to analog converter 30 creates an analog signdl to be used by coil drive buffer circuitry 15 26. Coil drive buffer circuitry 26 provldes regulated battery power to charge capacitor 28 to d controlled vol tage.
The digital signal from microprocessor 10 to digital 2ndlog circuitry 30 is provided once for each time the 20 unit is turned on. This value is stored ln the l~tch of the digital to analog converter 30.
Capdcitor 28 attempts to recharge continuously. Coil drive buffer circuitry 26 dCtS in d manner similar to a voltage regulator that attempts to regulate energy storage 25 capacitor 28 to a voltage determined by the analog output of digital analog converter 30. As a pulse from coil drive circuitry 12 lowers the charge on energy storage capacitor 28, the charging process starts agdin.
Coils 7 and 8 are connected to coil mu1tiplexer 32 30 which can select either coil for monitoring. Coil multiplexer 32 receives communication signals on line 34 from microprocessor 10. Microprocessor 10 signals along line 34 which coils to be selected by coil multiplexer 32.
For example, microprocessor 10 drives first coil 7 through 35 means of line la an(l coil driver 12 w~lile lndicating dl~ng line 34 that second coil 8 is to be sensed Vid coil multiplexer 32.
;8494 The output of coil multiplexer 32 is connec~ed along line 36 to a coil receive amplifier 38. Amplifier 38 is a differential amplifier which amplifies a signal on line 36 and puts out an amplified signal on line 40.
The amplified signal on line 40 is provided to an analog multiplexer 42. Multiplexer 42 is used to select various forms of analog ~nput to be lnterpreted by a microprocessor 10.
Coil current from coil driver circuitry 12 is sensed 10 on line 44 and provided to a coil current amplifier 46 which amplifies the signal and provides an amplified signal on line 48 to analog multiplexer 42. The coil current signal on line 44 comes through d current sensing resistor that is part of coil driver circuitry 12. In 15 this manner, total current through coils 7 and 8 is tested.
An additional input to analog multiplexer 42 is voltage from battery 50 which is provided on line 52.
Battery 50 is also directly connected to coil drive buffer 20 circuitry 26.
Ther~fore, analog multiplexer 42 provides a choice of three analog inputs: battery voltage from battery 50, coil voltage on line 40 from coil receive amplifier 38, and coil current on line 48 from coil current amplifier 25 46. Microprocessor 10 provides digltal slgnals on line 54 to indicate to analog mux 42 which uf these three inputs to select.
Whichever of the three analog inputs is selected in analog mux 42 is provided as output on line 56 to a 30 sampling analog to digital converter 5~. Analog to digital converter 58 converts the signal on line 56 to d digital signal for use by microprocessor 10. The digital signal is provided on line 60. A line 62 from microprocessor 10 instructs analog to digital converter 60 35 when to convert data. Analog to digital 60 converter is a sampling type of ùevice which requires a signal during a certain sampllng window as determined by microprocessor 1258~94 10. Therefore, voltage pulses are sampled at chosen points and times during pulse duration.
There are various system functions that can be ~ested by the three forms o~ -InpuL to analog mu1tiple~er 42. The 5 voltage read from c0il5 via coil multlple~er 32 is needed to determ~ne dt self-fit~ing time how far apart coils 7 and 8 are. It is also used to decide how to set Lhe drlve pulses through coil drive supply circuit 12 such that Lhe dB/dt or the rate of change of flux midway between 1~ treatment coils 7 and 8 is at the prescribed level.
The coi) current monitored on line 44 is used to tell which of two or more different types of coils is in use.
This is commonly done upon the start up of the system at self-fitting time. Different coils are of different 15 inductance. By monitoring the current towards the end of a treatment pulse, it determines which type of coil is in use. Additionally, this current is used to determine if the system is working properly. If there is a failure in one coil it could be recognized by sudnen drop in current 20 or, in some cases, by an increase in current in that coil.
Battery voltage is sensed along line 52 to know when to charge the ba~tery. It also indicates that there is battery failure. This type of system preferably uses 25 rechargeable batteries. If the batteries are being charged and the battery voltage doesn't increase after d period of time, it is known that there is a ba~tery failure.
The system is activated by patient switch 64 or 30 physician switch 66 which are both connected to microprocessor 10 and standby circuit and latch 68.
Patient switch 64 acts generally as an on/o~f switch.
Microprocessor 10 i~ maintained in a standby mode and is activated when patien~ switch 64 is depressed. ~he 35 standby mode maintains the volatile memory in RAM. When patient switch 64 is initidlly pushed, it causes standhy circuit and latch 68 to clear a stdndhy flip-flop putting the system out of standby mode. Standby circuit and latch 68 alerts microprocessor 10 via line number 70 that it is time for microprocessor 10 to come out of standby mode.
If the patient switch 64 is activated a second time, 5 it instructs the microprocessor 10 that its time to go back into standby. Microprocessor 10 then signals, via line 72, for the standby circuit and latch 68 to go back to standby.
Additionally, if ba~ery voltage drops too low, the 10 system goes into a standby state. In this embodiment, if the battery voltage drops below 10 vol~s, microprocessor 10 turns the system to standby.
Standby circuit and latch 68 is connected by line 74 to power switches 76. Bdttery 50 is connected to power 15 switches 76 by line 78. Power switches 76 regulate power to most of the circuitry of the unit. There are 5 volt and 12 volt switches to provide appropriate voltage to various parts of the circuit. Most of the circuitry will be shut off through power s~ltches 76 during stdndhy mode.
20 There are only a few components that are kept alive during standby, such as microprocessor 10.
Power sw~tches 76 include a 5 volt regula~or that steps the battery voltage down from about the nominal 12 volts to the 5 volt switched level.
Physician switch 66 can also take the system out of standby, clearlng the standby latch. Physician switch 66 is used to indicate to microprocessor 10, ~ia line 71, what mode the system is to be in. The physician initiates self-fitting mode by depressing physician switch 66, in ~0 this embodiment for a period of eight seconds. Also, various system messages are inspected by momentarily depressing physician switc~ 66.
A 16 character L~D display 80 is connected to microprocessor 10 by line 82. Display 80 ls used to 35 display messages during operation of the unit, including error messages.
-8- ~Z58~94 An energy recovery circuit B4 receives electricdl energy on line 86 from coil driver circuitry 12 as treatment coils 7 and 8 discharge. Energy recovery circuit 84 sends energy back along line 90 to energy 5 storage capacitor 28, for use ~n the next drive cycle.
Energy recovery circui~ 84 receives information from microprocessor 10 along line 88.
A beeper 90 is connected to receive signals from microprocessor 10. Beeper 90 is used for giving audible 10 signal of things such as low battery warnings.
CIRCUIT DES~R]PT~ON
Microprocessor 10 includes microprocessor Ull wh-lch ls a HD6303B processor manufactured by Hltachi. Thls Is an eight-bit CMOS low-power microprocessor.
15 Microprocessor 10 also includes latch U12, PROM U14, address decoder U13, as well as gating control 109ic consisting of U9B, U9C, and U9D. Latch U12 separates address information from data information. The PROM U14 address lines AO through A7 require address informa~ion.
20 Microprocessor Ull puts out both address and date information from pins 30-39 which are labeled Ao/Do-A7/D7. At various points in the timing cycle, information coming out on the combined address and da~a bus is either address information or data 25 lnformdtion. Latch U12 latches ln address informat~on during approprlate timing, as controlled by the latch enable input of 1atch U12 (pin 11) which is connected to the dddress strobe output on microprocessor Ull (pin 39).
Latch U12 is a 74HC373 device which is man~factured by 30 various companies.
PROM U14 stores a sequence of instructions used in controlling the system. PROM U14 is standard programmable read only memory which is eraseable by ultrdviolet light.
Address informa~ion comes to the microprocessor Ull 35 through address latch U12 and indlcates the pro~ram step.
The lower eight bits of address come via this la~ch. The ~25~3494 g upper five bits of address information come directly off the upper address bus which is only an address bus and not a combined address and data bus. This is on ports AB
throu9h A13-Clock enahle input on PROM U14 comes through the address decoder U13. Address decoder U13 is set up to decode an address of EXXX through FXXX. Any address In this range would enable PROM U14.
Data lines Do-D7 from PROM U14 have eight bits of 10 data information and are connected directly to the combined address and da~d bus of mlcroprocessor U11.
Microprocessor U11 controls timing functions, keeps track of treatment time, counts the number of treatment sessions, monitors error conditions, displays approprid~e 15 messages, and indicates errors in functioning of tne system.
The microprocessor Ull is connected to display ~0 through the address bus. For timing purposes, information sent to the display is sent dS dddreSS itlfOrlllatiOIl.
Microprocessor 11 iS the location in the circuit through which all information flows. Lines 18 and 20 for coil 7 and coil 8 are connected to ports 12 and 13 respectively of microprocessor 11. In this embodiment, - the digital components are primarily moun~ed on one board 25 and analog components on another. Line 18 comes in from a board-to-board connector. It is connected to voltdge translator U3. Line 18 enters U3 as a 0-5 volt logic level signal. This is also true of line 20, for coil 8.
Voltage translator U3 converts the 0-5 volt level to a 0-9 30 volt level. Pin number 3 of voltage translator U3 is connected to resistor R11 and pin ~ is connected to resistor R12, both of which are connected to ground.
Resistors R11 and R12 are pull down resistors to force pins 3 and 6 to a known state when power is switched off.
35 Voltage VCs is connec~ed to pin 1 of voltage translator U3. During standby condition VCs is removed. Pin 8 is the ground for voltdge transldtor U3.
1258~94 Pins 15 and 9 are connected to ground to disable section C
and D of voltage translator U3 whlch are not used. Only sections A and B are used. Output on pins 4 and 5 is stepped up. Ports E and F of voltage translator U3 are 5 the output locations for the translated voltage.
This output goes to huffers made up of U2A through U2D. Coil 7 and coil 8 are identically trea~ed interndlly 50 only one path will be described for sake of the simplicity of the description. The flrst coil 7 pa 10 yoes to d buffer made up of ampllfiers U2A and U2l3 connected in parallel which provide additional current drive. These are noninverting buffers. The low drive impedance from this buffer is needed to drive ~he gate of FET Q3 in order to increase the switching speed. The gate 15 has signiflcdnt capdcitance associated with it so a low drive impedance is needed to switch the capacitance in d short time. The gate is also connected through pull down resistor R7 to ground~ to be sure that the gate 1s pulled to ground durlng standby when FET q3 ls to remaln off.
The source of FEr Q3 as well as FET ~4 from the other path ls connected to resistor R9. Reslstor R9 is part of the current sensing clrcuit. Reslstor R9 is a four leaded .01 ohm resistor. There are four leads so that there are two leads for the hlgh current path and two 25 leads for sensing. The high current path is the source of FET n3 and FET Q4 on one side. The other slde is connected to the negatlve side of capdcitor C2 which in turn goes to analog ground. High curren~s go through thl 5 path. These currents can be up to 10 or 11 amps peak.
30 The other two leads of resistor R9 have a low current path which is connected to current dmplifier UlB and UlC. One lead ls connected through resistor R41 to the lnverting input of UlB, and the other low current lead is connected through resistor R20 to the non-inverting input of UlB.
35 Amplifier UlB is cnnnected in a differentlal amplifier scheme. The output of differential amplifier U18 goes to the noninverting input of amplifier UlC. The inverting 25~3494 input is connected both to ground throuyh resistor RlR and through R17 to provide feedback. Amplifier UlC is d single-ended input amplifier which provides additiondl gain from amplifier UlB. Output of amplifier UlC qoes to 5 a multiplexer U6.
The drain of FET Q3 i s connected to -one side of treatment coil L2 and the drain of power FEr Q4 is connected to one side of coil Ll.
Coil drive buffer 26 includes transistors Q1 and Q2, 10 amplifier UlA, and resistors Rl-RS and R12. A terminal of coil Ll and coil L2 is each connected to a common connection at the drain of transistor Ql, which is a series pass P-channel power FET transistor. The gate of transistor Ql is connected through transistor Q2 and 15 resistor R2. Base of transistor Q2 is connected through resistor R5, which is the output of amplifier UlA, which gets its reference input on the noninverting input pin 3 from digital to analog inverter 30 output. This is a signal from 0 to 2 1/2 volts. The digital to analo~
20 converter 30 is carrying the signal from microprocessor 11 indicating amplitude. This 0 to 2.5 volt signal comes to the noninverting input of amplifier UlA. The inverting input of dmplifier UlA is connected to ground through resistor R12. The inverting input is also connected 25 through resistor R4 and R3 back to the co~l drive supply off the drain of transistor Ql. R4 and R3 provide the feedback path. Resistor R3 allows fine adjustment of ~he coil drive amplitude for calibration.
Transistor Q2 provides one additiondl inversion.
30 Transistor Q2 acts together with amplifier U1 to provide gain. ~ransistor Q2 i5 driven into conduction and the more transistor Q2 conducts, the more the gate of transistor Ql Is driven to a lo~ stdte. Thls cduse~
incredsed voltage from source to qate of translstor Ql.
35 Because it is d P-chdnnel enhancement mode power FET, the hiqher the source to gd~e voltdge, the more trdnsistor Ql will be driven into conduction. Bdtteries are connected to the gate Vid pull Up resistor R1. Therefore the amount of voltage from source to gate of transistor Q1 determines the power that is provided to the coils Ll and L2. Buffer 26 is configured in a feedback circuit to maintain voltage 5 across capacitor C2, whlch is connected across from the common coil drive to analog ground. The voltage across C2 is to be maintained a constant level determined by the digital to analog ou~put dS controlled by microprocessor 10.
The circuit has provision for connecting a batLery charger Lo charge battery 50. The charger can be connected to the unit whlle the unlt ls provlding treatment output so battery SO can be charging a~ the same time the current is supplied to the circuit. Diode CR1 15 prevents current from flowing into the charger from battery 50 in the event that the charger should fail or output pins of the charger should short out. ~he positive side of the battery SO is connected through fuse Fl as a safety feature to prevent overheatlng ~n the event thdt 20 there is a short ln the system.
Coil current amplifler 46 lncludes ampl1flers Ul~ and UlC, reslstors R17, R18, Rl9, R20, R21 and R41. UlB Is conflgured as a simple differential ampl~fler ampllfying the differentlal voltage across the two senslng leads of 25 current sensing resistor R9. One senslng lead is connected to the inverting input of UlB through resistor R41 and another senslng lead is connected to the noninverting input of UlB through resistor R20. Resistor R21 completes d divlder network wlth reslstor R20.
30 Resistor Rl9 provides feedback from the output of UlB to the inverting input of U1B. The output of UlB is further amplified by noninverting amplifier UlC, whose gain is controlled by reslstor dlvlder network formed by reslstors R17 and R18. The output of UlC is connected ~ia line 48 35 to the analog multiplexer.
1258~94 ~ vercurrent detect and latch circuit 16 includes amplifier UlD, resistors Rl3 through R16, capacitor C3 and C4, and NAND gates U8B and U8C.
Amplifier UlD is configured dS a comparator. At 5 amplifier UlD, the circuit uses current sensing resistor R9 connected through resistor R57, wh1ch goes to the 1nvert1ng 1nput of UlD. The non1nvert1ng input of amplifier UlD is maintained d~ a fraction of flxed reference voltage URef. Voltage VRef is divided down lO by a voltage divider network consisting of resistors R13 and Rl6. Capacitor C4 provides filtering to minimize no1se on the noninverting input. Ampl1f1er UlB is configured as a comparator. The amplifier circuit is configured so the output of amplifier UlD will either be 15 in a high state or a low state. Resistor Rl4 pulls that output to ground when Vds is switched off. When Vds is on, the comparator is allowed to function normally. When the ~nverting input amplitude on pin 13 exceeds the noninverting input reference on pin 12, the 20 output of compdrator on pln 14 goes to yround or very near ground which puts out a signal at zero logic level. When this line ~oes low, a latch consist1ng ~AND gates U8B and U8C will be set. NAND ga~es U8B and U8C are configured in a set/reset latch configuration. An output of that 25 set/reset latch goes to microprocessor U1l. When output on pin 10 is in the low state, it 1nd1cates to the microprocessor on port 11 (pin 14) that the system is in an overcurrent state. Microprocessor 11 then, through software takes appropriate action. Another line coming 30 from microprocessor port 10 clears the overcurrent latch when pulsed low by microprocessor 11.
The overcurrent detect and latch clrcuit 16 disables coil drivers 12 by the enahle 1nput on pins 2 and 7 o~
voltage translator U3. When ~his p1n 1s low, indicating 35 overcurrent condi~ions, U3 outputs will be disabled, shutt1ng off co~l drivers 12. This overcurrent disdble Is a fast acting pa~hway that does not go through 12~8~94 microprocessor 11 so that coil driver circuitry 12 will be shut down immediately upon overcurrent condition.
Coil multiplexer 32 includes section C of multiplexer U6. Multiplexer U6 has three different sections used in 5 different portions of this circuitry. Section C includes pins 3, 4, 5 and 9. Pin 3 (CY) and pin 5 (CX) are connected to coils L1 and L2 via resistors R22 and R52.
The control for this section of multiplexer U6 comes from pin 9 (C). Input to pin 9 comes through a voltage level 10 translator U5 which is connected to microprocessor 11.
When pin 9 is low, pin 5 (CX) is connected to the common input pin 4. When pin 9 is high, then pin 3 (CY~ is connected to common pin 4.
The output of multiplexer 32 (FIG. 3d) is common pin 15 4 (C) to coil receiving amplifier 38 (FIG. 3b). In coil receiving amplifier 38, this input goes through resistor R40 to differential coil amplifier U4A at the inverting input. The noninverting input of amplifier U4 is connected through resistors R29 back to the common side of 20 the coils. Amplifier U4A is configured in a linear differential amplifier configuration and its output is an analog voltage proportional to the differential voltage across the receiving coil. The output of amplifier U4A
goes to the noninverting input of amplifier U4B. The 25 inverting input of amplifier U4A is tied to resistor 30 and to the noninverting input of U4B. Resistor R30 is a feedbac~ resistor from the output of amplifier U4A pin 8 to the inverting input pin 9, which is part of the differential amplifier configuration. The inverting input 30 of amplifier U4B goes through feedback resistor R31 from the output of amplifier U4B. Amplifier U4B provides additional gain off the first stage of amplification from amplifier U4A. Two stages of amplification are used to provide the required band wid~h and gain needed to 35 effectively reproduce the voltage waveform that is being monitored.
-l s- 12~8494 The output of amplifier U4B goes into multiplexer 42 which is another section of multiplexer U6. It enters pin 1 (BY) of multiplexer U6 which comprises analog mu1tiplexer 42. From there the signal goes to the pin 15 5 (BCOM), when multiplexer 42 is in the proper position, as controlled by lnput pin 10 (B) which ultlmately comes from microprocessor 11. When input at pin 10 is in the high state, pin 1 (BY) will be connected to pin 15 (BCOM). The output BCOM goes throu~h a filter network consisting of a 10 cdpacitors C7 and C25, resistors R38 and R39 and clamping diodes CR9 and CR10. The s~gnal eventually arrives at another section of the multiplexer whlch ts pin 13 (AY).
Pin 13 (AY) will be connected to pin 14 (ACOM) when the controlling input at pin 11 (A) is at a logical 1. This 15 control comes from microprocessor 11. Output from pin 14 (ACOM) is buffered by dmplifier U4D wh1ch is a unity gain amplifier. This amplifier provides low impedance dr~ve to the input of andlog to digital converter 58. Section C of multip1exer U6 is used to chuose one of two co1ls for d 20 voltdge readback. Section B either selects voltage input from coil amplifier U4B or selects lnput BX from the current amplifier. When control input B at pin IO of multiplexer U6 is at a O level, BX will then be connected to BCOM. The signal from BCOM output will now go through 25 the same input filter network as mentioned previously.
The signal is then ultimately connected to the analog to digital converter 58.
A line from battery 50 for sensiny battery voltage c~mes through the resistor dlvider network consisting of 30 resistors R43 and R44. Analog to digltal converter S8 only accepts voltages up to 5 volts, so battery voltage is divided down before being supplied to converter 58.
Divided down battery voltage is selected when input AX is connected to ACOM. Th~s occurs when pin ll (A) 1s set at 35 logic 0. When pin 11 tA) is at a log~c 1. the AY is connected to read current or voltages. Sampling analog to digital converter 58 includes converter U17. A siynal 125~349 from multlplexer 42 arrlves on pln 2 of conver~er U7 which is called VIN. Reference input on pln 1 comes from a 5 volt supply line. Capacitor C24 is connected from pin 1 to ground. Capacitor C24 provides fi1tering on the 5 reFerence input to minimize noise and r1pple on the line to provlde a stable reference lnput. Frequency d~vider U16 provldes a c10ck slgnal. Frequency dlvlder U16 ts d 2:1 frequency d1vlder. The base frequency ls supplled ~n pln 3 of dtvlder U16 wh~ch comes from enable lnpu~ pln 40 10 of mlcroprocessor 11. The baslc bus system clock runs dt 500 kllohertz. Dlvider U16 dlvldes thls down to a suitable frequency for converter U17.
Sampllng A to D converter U17 (FIG. 39~ ls initiated by pulling the write pin 15 low in con~unction with 15 forcing the pin 16 chlp select llne low. Pins 15 and 16 are controlled by microprocessor 11. Select pln 16 is brought low whenever any address in the range CXXX-DXXX
is decoded by address decoder U13. Connections from the mlcroprocessor 11 to converter U17 are on the common data 20 bus. This connectlon ls on bus lines Do-D7.
After a period of a few hundred microseconds, the conversion process will be complete and interrupt line pin 13 of converter U13 will pulse low indicating conversion is complete. At that time, microprocessor 11 reads 25 results of the conversion by causing read pin 14 of converter U17 to pulse low a)ong wlth select pin 16 of converter U17. The results of the conversion are then a~ailable on the data bus lines Do-D7.
Standby circuit and latch 68 (FIG. 3e) lncludes NAND
30 gates U8A and U8B and transistors Q10 and Qll . Transistor Q10 is a P-channel junction FET. Transls~or Qll is an enhancement mode power FET. The latch lncludes the two NAND gates U8A and U8B connected together in d reset/set latch configuration, which functions ln a manner slmilar 35 to the overcurrent latch 16. The output of the latch goes to the gate of power FET Qll. The source of transistor Qll is connected to ground. When the c~rcuit is in a standby state, pin 3 of U8 wlll be high at a logic l which turns on trdnsistor Qll, which in turn brlngs the drain very near to ground. This causes the reset input of mlcroprocessor 11 p1n 6 to be ln a low stale. At that 5 time the microprocessor 11 is in the reset condition. At the same time STBY latch would be in a low state which forces the microprocessor to be in the standby mode. At this time power consumption of microprocessor 11 wi I 1 be minimal. The internal clock is not running. The RAM
lO memory stays alive.
The input at pin 12 of NAND gate U8D comes from diode ~Rl5 and CR16 whlch are in turn connected to patient switch 64 and physician swi~ch 6~. When either swltch is depressed, the cathodes of dlodes CR15 or DR16 will be lS connected to ground, which ln turn connects the common anodes of dlodes CR15 and CRl6 to one dlode drop abov~
- ground. Thls in turn pulls pin 12, the standby latch clear lnput, to ground. When thls lnput ~s brough t~
ground, the not-standby pin 11 goes to d h1gh state and 20 the standby latch ls cleared. This actlon in turn stdrt~
the process of microprocessor 11 coming out of standby mode. The not-standby input (pin 7) to microprocessor 11 goes high.
Sllghtly later, the gate of trdnslstor Qll wlll go 25 low at pin 3, the opposite slde of the latch will be ~n the opposite staLe. The drain of trdnsistor Qll will then start ~olng high as determlned by an RC network of resistor 46 and capacitor C19. Thls wlll exponentially rise. Eventually this voltage causes the reset input of 30 Ull to go to the high state, and microprocessor 11 starts runnlng.
Translstor qlo provides a secondary low voltage detect circuit to force the standby latch to be set into standby mode when voltage on the gdte (which comes from - 35 YDD) is below a threshold~ When voltage VDD drops below the threshold gate voltage of translstor QlO, lt will conduct. The drain is connected to ground thus pulling pin 2 of U8 to Lhe low state which forces the standby latch into standby. Durin~ normal operation, the gate of trdnsistor Q10 is at a relatlvely high level around 12 volts. In that case, p~n 2 stays high unless 5 forced low by another input. The other input comes through diode CR13 and through a ~ultiplexer U10 ultimately from port 20 of microprocessor 11. Therefore, port 20 of microprocessor 11 has the ability to control or force the latch into standby as well. When port 20 pu~ses 10 low, it causes pin 2 of gate U8A to pulse low. Thls puls the system in standby.
The se~ of resistors U18A comprises pull up resistors used in various places in the circuit. These resistors pull up patient switches and pull up a set of input 15 conditions on chip U10. The function of multiplexer U10 is to initialize the microprocessor 11 in the proper state at the time of reset, but allow P20, P21, and P22 to be used elsewhere when not in reset.
Power switches 76 (FIG. 3d) include three different 20 switches. All switches are P-channel power MOS FET
transistors. Transistor Q5 controls the switched higher voltdge of approximately 12 volts whlch is called VDs.
When the gate of transistor Q5 is brough to a low state, transistor Q5 turns on so that VDs will be at 25 essentially the same voltage dS the higher 12 volt supply VDD. When the standby latch ls set, the gate of Q5 is brough high and the transistor ls turned off. Voltage is translated in the circuit by voltage controller U5 which serves as voltage translation from the 0-5 volt level of 30 microprocessor 11 to the 0-12 volt level required for controlling the gate of trans~stor Q5.
The other two power switches are transistors q6 and Q7 which control two switched 5 volt supplies. One is YCs from Q6 drain which is a 5 volt power use for the 35 majority of the circuit. The other vol~age comes from the drain of transistor Q7 and is the analog to digital reference voltage. This reference is also at 5 volts.
~258~4 The reference 5v is lsolated through a sepdrate swi~ch ~o minimize noise on the line. Translstors Q6 and Q7 dre turned on when the gates are brought low via microprocessor 11 ~hrough standby latch control.
Another portion of voltage control that is comprlsed by coil driver circuitry 12 includes amplifier U4C and resistors R32, R33, and R34. This is a 9 ~olt supply. A
cdpacitor C10 filters in order to minimize noise on the supply line. The three reslstors R32 through R34 form 10 part of the amplifier configuration of amplifier U4C.
Resistors R33 and R32 provide feedback. Resistor R34 is an isolation resistor which prevents loading the output of a amplifier U4C with high capacitance which could cause instability in the amplifier.
Beeper 90 includes power FET trans1stor Q8 and a small electromagnetic transducer SPl. Transducer SPl acts as a small speaker. Translstor Q8 ls swltched on and off at a rate determined by d dr~ve slgnal emltted from por~
14 of microprocessor 11. The drdln of q8 ~s connec~ed 20 through resistor R48 ~o transducer SPl. Reslstor R4a ls d current llmlting reslstor to contro) amount of drlve power to the speaker. Resls~or R49 is connected to p~n 17 and to the source of transistor Q8, and then to ground.
Resistor 49 acts as a pull down resistor so tha~ when the 25 system is ln standby the beeper wlll be off and drawlng no current.
PARTS LIST
Resistors (Kohm) Resistors (Kohm) Rl 51 R30 200 30 R2 10 R31 24.9 R3 10 (Pot~ R32 110 R4 31.6 R33 270 R6 1 R35 10 ~Pot) RB 1 R37 4.7 ~L2S8494 R9 .01 ohm R38 100 Rll 100 R40 49.9 R12 100 R41 16.2 10 R18 17.4 R48 100 Rl9 100 R49 100 R20 16.2 R50 5.1 ohm R22 49.9 R52 49.9 R24 50 (Pot) R54 10 ohm R25 63.4 RS5 100 Capacitors (microfarads) Capacitors (microfarads) Cl .1 C13 .1 C2 6800 C14 .1 25 C3 .1 C15 ~ .1 C4 .1 C16 .1 C5 10 C17 ~1 C6 .1 C18 .1 ~7 .1 Cl~ 2.2 30 C8 .1 C20 100 C9 10 C21 .1 C10 10 C22 100 pf Cll 22 pf C23 100 pf C12 22 pf C24 .1 C25 .001 -21- ~258494 Diodes CRl Axial lead 1 amp CR3 Zener transient suppressor IN6288 CR6 Schottky IN5711 CR7 lN5354B
CR8 Axial lead 1 amp 10 CR9 Schottky IN5711 CR10 Schottky IN5711 CRll Schottky IN5711 CR12 Schottky IN5711 CR13 Schottky IN5711 15 CR14 Schottky IN5711 CR15 Schottky IN5711 CR16 Schottky IN5711 CR17 Zener transient suppressor IN6288 Transistors 20 Ql P channel MOSFET
Q2 Silicon switch Q3 IRF530 power FET
Q4 IRf530 power FET
Q5 ZVPOlA34 25 Q6 ZVPOlA34 Q7 ZVPOlA34 Q8 VN0106N3 N channel MOSFET
Q10 J17~
30 Qll VN0106N3 Miscellaneous Chips U1 Quad op amp LM324 U3 CMOS quad level shift 40109 35 U4 Quad op amp LM324 1258~94 U5 CMOS quad level shift 40109 U7 LM2931T voltdge reyulator U8 CMOS Quad NAND CD 4011B
U9 Quad NAND gate 74HCOO
U11 Hitdchi HD6303B
U12 7411C373 latch U13 HCMûS decoder 74HC138 U14 Hitachi or Ferranti 27C64, 8Kx8 EPROM
U15 CMOS D to A converter 1008 U17 MSM5204 RS, OKI semlconductor SOFTWARE DESCRIPTION
As described above in the description of the circuit of the illustrated embodiment, microprocessor 10 controls 15 operation of the system.
Self-Fitting 1. At the start of self-fitting, check to see if physician switch 66 is depressed for eight seconds. If so, go on.
2. Display message "SELF-FITTING" and begin self-fitting procedure.
What is needed in the art is a system which can automatically adjust the electrical energy provided to the coils to that therapy will be maximized.
SUMMARY OF THE INVENTION
The present invention involves means for sensing the rate of change of magnetic flux density of a medical treatment coil and automatically adjusting pulses of electric-al energy provided to the coil so as to properly provide therapy. In one embodiment, a device includes a medical -treat-ment coil, pulse generator means for producing pulses of elect-rical energy and supplying them to the coil, a sense coil for sensing the magnetic field produced by the coil, and a con-troller, responsive to the sensed magnetic field, for auto-matically generating a signal to the pulse generator circuitry to adjust the magnitude of the pulses.
In another embodiment, the device includes first and second treatment coils and a multiplexer electrically connected to the coils for selecting either or both of the coils. One of the coils is activated by electrical pulses from a pulse generator. A controller, electrically connected to the multiplexer, selects the other coil for sensing the strength of the magnetic field (dB/dt) produced by the first coil and for, based upon the sensed magnitude, sending a signal to the pulse generator means indicating the magnitude of electrical pulses to be provided to the first coil.
~L25849~
-2a- 66742-261 In accordance with a broad aspect of the invention there is provided a medical device for inducing electrical current within a patient's body by creating a magnetic field through the body comprising:
first coil for placement in a treatment relation to a patient's body;
second coil for placement in a second treatment relation to the patient's body so that the first coil and second coil are in a generally flux-aiding relation to each other;
driver circuitry for providing pulsed electrical energy to the first and second coils;
control means operably connected to the driver circuitry for controlling the magnitude of the electrical energy;
multiplexer means connected to the first coil and second coil and operably connected to the control means for selecting one coil; and the control means including means for indicating to the multiplexer means that one of the coils is selected for driving by the coil driver and the other of the coils is selected for sensing magnetic field induced by said one of the coils, and for automatically adjusting the magnitude of electrical energy produced by the driver circuitry based upon sensed magnetic field.
In accordance with another broad aspect of the invention there is provided a self-fitting electromagnetic bone growth stimulator comprising:
a first treatment coil for positioning adjacent ~25~3494 -2b- 66742-261 a patient's body;
a second treatment coil for positioning adjacent a patient's body in a flux-aiding relationship which creates a magnetic field through a portion of the patient's body;
pulse generation means electrically connected to the first coil and the second coil for providing pulses of electrical energy to the first coil and the second coil;
control means electrically connected to the pulse generating circuitry for transmitting a magnitude signal to th~ pulse generation means indicative of a magnitude of the pulses of electrical energy;
sensing circuitry electrically connected to the first and second coils for sensing a magnetic field at one coil, which was produced by the other coil and for producing a sensed field signal indicative of field strength to the control means/ the control means automatically adjusting the magnitude signal in response to the field strength signal.
In accordance with another broad aspect of the invention there is provided a device for automatically self-fitting an induction coil bone growth stimulator of the type having at least two coils for treating a patient comprising:
means for providing pulsed electrical energy to first and second coils;
means connected to the first and second coils for selecting one coil as a sense coil;
control means operably connected to the means for providing pulsed electrical energy and to the multiplexer means for indicating to the multiplexer means to select one coil for sensing, for sensing electrical current in the sense coil; and for automatically adjusting electrical energy - :1258~94 -2c- 66742-261 provided by the means for providing pulsed electrical energy.
BRIEF DESCRIPTION OF THE DRAWINGS
. _ _ Figure 1 is a fragmentary, partially cut-away, view of the leg of a human patient with first and second treatment coils mounted on a cast and feedback coils mounted within the treatment coils;
~258494 FIG. 2 ls d block did~ram o~ d medlcal Lr~dLm~
device including automatic adjustlng means of the present invention; and FIG. 3 is a layout of FlGs. 3a-3h, which are 5 electrical schematics of the devlce of FIG. 2.
- DETAILED DESCRIPTION OF THE PREFERRED EMBODlMENTS
An example of a trea~ment method using induction coils is illustrated in FIG. l where a leg 4 includes a bone 5 with a fracture. A cast 6 is mounted on leg 4 to IO immobilize it. Treatment coils 7 and 8 are mounted on opposite sides o~ leg 4 in a flux-aid1ng relationship so that a magnetic field extends through the center of both coils 7 and 8. Feedback coils 9 are small coils mounted on cast 6 within the center of coils 7 and 8.
Feedback coils 9 are illustrative of one embodiment of the present invention. Feedback coils 9 are used in this embodiment to sense the magnetic field produced by coils 7 and 8. In the preferred embodiment primarily described herein, separate feedbacks coils 9 are not us~d.
20 Instead, performance of colls 7 and 8 is checked by alternatively using one coil as d tredtment coil dnd ~he other coil dS a sense coil.
The block dia~ram of FIG. 2 illustrates the preferred embodiment in which coils 7 and 8 may each be used to 25 sense performance of the other. Th~s embodiment is centered around a microprocessor IO whlch lncludes a PROM, a latch and an address decoder.
A pair of coil driYers 12 prov1des pulses of electrical energy to treatment coils ~ and 8. An 30 overcurrent detection and latch circuit 16 senses when pulses provided by coil driver circultry 12 exceeds a specified maximum peak current.
Microprocessor IO communicates through first coil drive line 18 and second coil drlve line 20 with coil 35 driver circuitry 12. Should overcurrent detect and latch circuit 16 detect a threshold value put out by coil driver 4 ~Z~8494 circuitry 12, it communicdtes with microprocessor 10 through line 22, indicdting that the system is in overcurrent mode. Microprocessor 10 uses line 24 to clear the latch of overcurrent detect and latch circuitry 16.
S Such an overcurrent could be caused by such thlngs as a short ln a coil, a faulty coll, or a faulty cable.
The power to be used by coil driver circuitry 12 for producing pulses of electrical energy is supplied by cotl drive buffer 26 and energy storage capacitor 28. This 10 process also involves digital to dnalog converter 30.
Microprocessor 10 provides a digital signal indicdLive of desired pulse amplitude to di~ital to analog converter 30.
From this, digital to analog converter 30 creates an analog signdl to be used by coil drive buffer circuitry 15 26. Coil drive buffer circuitry 26 provldes regulated battery power to charge capacitor 28 to d controlled vol tage.
The digital signal from microprocessor 10 to digital 2ndlog circuitry 30 is provided once for each time the 20 unit is turned on. This value is stored ln the l~tch of the digital to analog converter 30.
Capdcitor 28 attempts to recharge continuously. Coil drive buffer circuitry 26 dCtS in d manner similar to a voltage regulator that attempts to regulate energy storage 25 capacitor 28 to a voltage determined by the analog output of digital analog converter 30. As a pulse from coil drive circuitry 12 lowers the charge on energy storage capacitor 28, the charging process starts agdin.
Coils 7 and 8 are connected to coil mu1tiplexer 32 30 which can select either coil for monitoring. Coil multiplexer 32 receives communication signals on line 34 from microprocessor 10. Microprocessor 10 signals along line 34 which coils to be selected by coil multiplexer 32.
For example, microprocessor 10 drives first coil 7 through 35 means of line la an(l coil driver 12 w~lile lndicating dl~ng line 34 that second coil 8 is to be sensed Vid coil multiplexer 32.
;8494 The output of coil multiplexer 32 is connec~ed along line 36 to a coil receive amplifier 38. Amplifier 38 is a differential amplifier which amplifies a signal on line 36 and puts out an amplified signal on line 40.
The amplified signal on line 40 is provided to an analog multiplexer 42. Multiplexer 42 is used to select various forms of analog ~nput to be lnterpreted by a microprocessor 10.
Coil current from coil driver circuitry 12 is sensed 10 on line 44 and provided to a coil current amplifier 46 which amplifies the signal and provides an amplified signal on line 48 to analog multiplexer 42. The coil current signal on line 44 comes through d current sensing resistor that is part of coil driver circuitry 12. In 15 this manner, total current through coils 7 and 8 is tested.
An additional input to analog multiplexer 42 is voltage from battery 50 which is provided on line 52.
Battery 50 is also directly connected to coil drive buffer 20 circuitry 26.
Ther~fore, analog multiplexer 42 provides a choice of three analog inputs: battery voltage from battery 50, coil voltage on line 40 from coil receive amplifier 38, and coil current on line 48 from coil current amplifier 25 46. Microprocessor 10 provides digltal slgnals on line 54 to indicate to analog mux 42 which uf these three inputs to select.
Whichever of the three analog inputs is selected in analog mux 42 is provided as output on line 56 to a 30 sampling analog to digital converter 5~. Analog to digital converter 58 converts the signal on line 56 to d digital signal for use by microprocessor 10. The digital signal is provided on line 60. A line 62 from microprocessor 10 instructs analog to digital converter 60 35 when to convert data. Analog to digital 60 converter is a sampling type of ùevice which requires a signal during a certain sampllng window as determined by microprocessor 1258~94 10. Therefore, voltage pulses are sampled at chosen points and times during pulse duration.
There are various system functions that can be ~ested by the three forms o~ -InpuL to analog mu1tiple~er 42. The 5 voltage read from c0il5 via coil multlple~er 32 is needed to determ~ne dt self-fit~ing time how far apart coils 7 and 8 are. It is also used to decide how to set Lhe drlve pulses through coil drive supply circuit 12 such that Lhe dB/dt or the rate of change of flux midway between 1~ treatment coils 7 and 8 is at the prescribed level.
The coi) current monitored on line 44 is used to tell which of two or more different types of coils is in use.
This is commonly done upon the start up of the system at self-fitting time. Different coils are of different 15 inductance. By monitoring the current towards the end of a treatment pulse, it determines which type of coil is in use. Additionally, this current is used to determine if the system is working properly. If there is a failure in one coil it could be recognized by sudnen drop in current 20 or, in some cases, by an increase in current in that coil.
Battery voltage is sensed along line 52 to know when to charge the ba~tery. It also indicates that there is battery failure. This type of system preferably uses 25 rechargeable batteries. If the batteries are being charged and the battery voltage doesn't increase after d period of time, it is known that there is a ba~tery failure.
The system is activated by patient switch 64 or 30 physician switch 66 which are both connected to microprocessor 10 and standby circuit and latch 68.
Patient switch 64 acts generally as an on/o~f switch.
Microprocessor 10 i~ maintained in a standby mode and is activated when patien~ switch 64 is depressed. ~he 35 standby mode maintains the volatile memory in RAM. When patient switch 64 is initidlly pushed, it causes standhy circuit and latch 68 to clear a stdndhy flip-flop putting the system out of standby mode. Standby circuit and latch 68 alerts microprocessor 10 via line number 70 that it is time for microprocessor 10 to come out of standby mode.
If the patient switch 64 is activated a second time, 5 it instructs the microprocessor 10 that its time to go back into standby. Microprocessor 10 then signals, via line 72, for the standby circuit and latch 68 to go back to standby.
Additionally, if ba~ery voltage drops too low, the 10 system goes into a standby state. In this embodiment, if the battery voltage drops below 10 vol~s, microprocessor 10 turns the system to standby.
Standby circuit and latch 68 is connected by line 74 to power switches 76. Bdttery 50 is connected to power 15 switches 76 by line 78. Power switches 76 regulate power to most of the circuitry of the unit. There are 5 volt and 12 volt switches to provide appropriate voltage to various parts of the circuit. Most of the circuitry will be shut off through power s~ltches 76 during stdndhy mode.
20 There are only a few components that are kept alive during standby, such as microprocessor 10.
Power sw~tches 76 include a 5 volt regula~or that steps the battery voltage down from about the nominal 12 volts to the 5 volt switched level.
Physician switch 66 can also take the system out of standby, clearlng the standby latch. Physician switch 66 is used to indicate to microprocessor 10, ~ia line 71, what mode the system is to be in. The physician initiates self-fitting mode by depressing physician switch 66, in ~0 this embodiment for a period of eight seconds. Also, various system messages are inspected by momentarily depressing physician switc~ 66.
A 16 character L~D display 80 is connected to microprocessor 10 by line 82. Display 80 ls used to 35 display messages during operation of the unit, including error messages.
-8- ~Z58~94 An energy recovery circuit B4 receives electricdl energy on line 86 from coil driver circuitry 12 as treatment coils 7 and 8 discharge. Energy recovery circuit 84 sends energy back along line 90 to energy 5 storage capacitor 28, for use ~n the next drive cycle.
Energy recovery circui~ 84 receives information from microprocessor 10 along line 88.
A beeper 90 is connected to receive signals from microprocessor 10. Beeper 90 is used for giving audible 10 signal of things such as low battery warnings.
CIRCUIT DES~R]PT~ON
Microprocessor 10 includes microprocessor Ull wh-lch ls a HD6303B processor manufactured by Hltachi. Thls Is an eight-bit CMOS low-power microprocessor.
15 Microprocessor 10 also includes latch U12, PROM U14, address decoder U13, as well as gating control 109ic consisting of U9B, U9C, and U9D. Latch U12 separates address information from data information. The PROM U14 address lines AO through A7 require address informa~ion.
20 Microprocessor Ull puts out both address and date information from pins 30-39 which are labeled Ao/Do-A7/D7. At various points in the timing cycle, information coming out on the combined address and da~a bus is either address information or data 25 lnformdtion. Latch U12 latches ln address informat~on during approprlate timing, as controlled by the latch enable input of 1atch U12 (pin 11) which is connected to the dddress strobe output on microprocessor Ull (pin 39).
Latch U12 is a 74HC373 device which is man~factured by 30 various companies.
PROM U14 stores a sequence of instructions used in controlling the system. PROM U14 is standard programmable read only memory which is eraseable by ultrdviolet light.
Address informa~ion comes to the microprocessor Ull 35 through address latch U12 and indlcates the pro~ram step.
The lower eight bits of address come via this la~ch. The ~25~3494 g upper five bits of address information come directly off the upper address bus which is only an address bus and not a combined address and data bus. This is on ports AB
throu9h A13-Clock enahle input on PROM U14 comes through the address decoder U13. Address decoder U13 is set up to decode an address of EXXX through FXXX. Any address In this range would enable PROM U14.
Data lines Do-D7 from PROM U14 have eight bits of 10 data information and are connected directly to the combined address and da~d bus of mlcroprocessor U11.
Microprocessor U11 controls timing functions, keeps track of treatment time, counts the number of treatment sessions, monitors error conditions, displays approprid~e 15 messages, and indicates errors in functioning of tne system.
The microprocessor Ull is connected to display ~0 through the address bus. For timing purposes, information sent to the display is sent dS dddreSS itlfOrlllatiOIl.
Microprocessor 11 iS the location in the circuit through which all information flows. Lines 18 and 20 for coil 7 and coil 8 are connected to ports 12 and 13 respectively of microprocessor 11. In this embodiment, - the digital components are primarily moun~ed on one board 25 and analog components on another. Line 18 comes in from a board-to-board connector. It is connected to voltdge translator U3. Line 18 enters U3 as a 0-5 volt logic level signal. This is also true of line 20, for coil 8.
Voltage translator U3 converts the 0-5 volt level to a 0-9 30 volt level. Pin number 3 of voltage translator U3 is connected to resistor R11 and pin ~ is connected to resistor R12, both of which are connected to ground.
Resistors R11 and R12 are pull down resistors to force pins 3 and 6 to a known state when power is switched off.
35 Voltage VCs is connec~ed to pin 1 of voltage translator U3. During standby condition VCs is removed. Pin 8 is the ground for voltdge transldtor U3.
1258~94 Pins 15 and 9 are connected to ground to disable section C
and D of voltage translator U3 whlch are not used. Only sections A and B are used. Output on pins 4 and 5 is stepped up. Ports E and F of voltage translator U3 are 5 the output locations for the translated voltage.
This output goes to huffers made up of U2A through U2D. Coil 7 and coil 8 are identically trea~ed interndlly 50 only one path will be described for sake of the simplicity of the description. The flrst coil 7 pa 10 yoes to d buffer made up of ampllfiers U2A and U2l3 connected in parallel which provide additional current drive. These are noninverting buffers. The low drive impedance from this buffer is needed to drive ~he gate of FET Q3 in order to increase the switching speed. The gate 15 has signiflcdnt capdcitance associated with it so a low drive impedance is needed to switch the capacitance in d short time. The gate is also connected through pull down resistor R7 to ground~ to be sure that the gate 1s pulled to ground durlng standby when FET q3 ls to remaln off.
The source of FEr Q3 as well as FET ~4 from the other path ls connected to resistor R9. Reslstor R9 is part of the current sensing clrcuit. Reslstor R9 is a four leaded .01 ohm resistor. There are four leads so that there are two leads for the hlgh current path and two 25 leads for sensing. The high current path is the source of FET n3 and FET Q4 on one side. The other slde is connected to the negatlve side of capdcitor C2 which in turn goes to analog ground. High curren~s go through thl 5 path. These currents can be up to 10 or 11 amps peak.
30 The other two leads of resistor R9 have a low current path which is connected to current dmplifier UlB and UlC. One lead ls connected through resistor R41 to the lnverting input of UlB, and the other low current lead is connected through resistor R20 to the non-inverting input of UlB.
35 Amplifier UlB is cnnnected in a differentlal amplifier scheme. The output of differential amplifier U18 goes to the noninverting input of amplifier UlC. The inverting 25~3494 input is connected both to ground throuyh resistor RlR and through R17 to provide feedback. Amplifier UlC is d single-ended input amplifier which provides additiondl gain from amplifier UlB. Output of amplifier UlC qoes to 5 a multiplexer U6.
The drain of FET Q3 i s connected to -one side of treatment coil L2 and the drain of power FEr Q4 is connected to one side of coil Ll.
Coil drive buffer 26 includes transistors Q1 and Q2, 10 amplifier UlA, and resistors Rl-RS and R12. A terminal of coil Ll and coil L2 is each connected to a common connection at the drain of transistor Ql, which is a series pass P-channel power FET transistor. The gate of transistor Ql is connected through transistor Q2 and 15 resistor R2. Base of transistor Q2 is connected through resistor R5, which is the output of amplifier UlA, which gets its reference input on the noninverting input pin 3 from digital to analog inverter 30 output. This is a signal from 0 to 2 1/2 volts. The digital to analo~
20 converter 30 is carrying the signal from microprocessor 11 indicating amplitude. This 0 to 2.5 volt signal comes to the noninverting input of amplifier UlA. The inverting input of dmplifier UlA is connected to ground through resistor R12. The inverting input is also connected 25 through resistor R4 and R3 back to the co~l drive supply off the drain of transistor Ql. R4 and R3 provide the feedback path. Resistor R3 allows fine adjustment of ~he coil drive amplitude for calibration.
Transistor Q2 provides one additiondl inversion.
30 Transistor Q2 acts together with amplifier U1 to provide gain. ~ransistor Q2 i5 driven into conduction and the more transistor Q2 conducts, the more the gate of transistor Ql Is driven to a lo~ stdte. Thls cduse~
incredsed voltage from source to qate of translstor Ql.
35 Because it is d P-chdnnel enhancement mode power FET, the hiqher the source to gd~e voltdge, the more trdnsistor Ql will be driven into conduction. Bdtteries are connected to the gate Vid pull Up resistor R1. Therefore the amount of voltage from source to gate of transistor Q1 determines the power that is provided to the coils Ll and L2. Buffer 26 is configured in a feedback circuit to maintain voltage 5 across capacitor C2, whlch is connected across from the common coil drive to analog ground. The voltage across C2 is to be maintained a constant level determined by the digital to analog ou~put dS controlled by microprocessor 10.
The circuit has provision for connecting a batLery charger Lo charge battery 50. The charger can be connected to the unit whlle the unlt ls provlding treatment output so battery SO can be charging a~ the same time the current is supplied to the circuit. Diode CR1 15 prevents current from flowing into the charger from battery 50 in the event that the charger should fail or output pins of the charger should short out. ~he positive side of the battery SO is connected through fuse Fl as a safety feature to prevent overheatlng ~n the event thdt 20 there is a short ln the system.
Coil current amplifler 46 lncludes ampl1flers Ul~ and UlC, reslstors R17, R18, Rl9, R20, R21 and R41. UlB Is conflgured as a simple differential ampl~fler ampllfying the differentlal voltage across the two senslng leads of 25 current sensing resistor R9. One senslng lead is connected to the inverting input of UlB through resistor R41 and another senslng lead is connected to the noninverting input of UlB through resistor R20. Resistor R21 completes d divlder network wlth reslstor R20.
30 Resistor Rl9 provides feedback from the output of UlB to the inverting input of U1B. The output of UlB is further amplified by noninverting amplifier UlC, whose gain is controlled by reslstor dlvlder network formed by reslstors R17 and R18. The output of UlC is connected ~ia line 48 35 to the analog multiplexer.
1258~94 ~ vercurrent detect and latch circuit 16 includes amplifier UlD, resistors Rl3 through R16, capacitor C3 and C4, and NAND gates U8B and U8C.
Amplifier UlD is configured dS a comparator. At 5 amplifier UlD, the circuit uses current sensing resistor R9 connected through resistor R57, wh1ch goes to the 1nvert1ng 1nput of UlD. The non1nvert1ng input of amplifier UlD is maintained d~ a fraction of flxed reference voltage URef. Voltage VRef is divided down lO by a voltage divider network consisting of resistors R13 and Rl6. Capacitor C4 provides filtering to minimize no1se on the noninverting input. Ampl1f1er UlB is configured as a comparator. The amplifier circuit is configured so the output of amplifier UlD will either be 15 in a high state or a low state. Resistor Rl4 pulls that output to ground when Vds is switched off. When Vds is on, the comparator is allowed to function normally. When the ~nverting input amplitude on pin 13 exceeds the noninverting input reference on pin 12, the 20 output of compdrator on pln 14 goes to yround or very near ground which puts out a signal at zero logic level. When this line ~oes low, a latch consist1ng ~AND gates U8B and U8C will be set. NAND ga~es U8B and U8C are configured in a set/reset latch configuration. An output of that 25 set/reset latch goes to microprocessor U1l. When output on pin 10 is in the low state, it 1nd1cates to the microprocessor on port 11 (pin 14) that the system is in an overcurrent state. Microprocessor 11 then, through software takes appropriate action. Another line coming 30 from microprocessor port 10 clears the overcurrent latch when pulsed low by microprocessor 11.
The overcurrent detect and latch clrcuit 16 disables coil drivers 12 by the enahle 1nput on pins 2 and 7 o~
voltage translator U3. When ~his p1n 1s low, indicating 35 overcurrent condi~ions, U3 outputs will be disabled, shutt1ng off co~l drivers 12. This overcurrent disdble Is a fast acting pa~hway that does not go through 12~8~94 microprocessor 11 so that coil driver circuitry 12 will be shut down immediately upon overcurrent condition.
Coil multiplexer 32 includes section C of multiplexer U6. Multiplexer U6 has three different sections used in 5 different portions of this circuitry. Section C includes pins 3, 4, 5 and 9. Pin 3 (CY) and pin 5 (CX) are connected to coils L1 and L2 via resistors R22 and R52.
The control for this section of multiplexer U6 comes from pin 9 (C). Input to pin 9 comes through a voltage level 10 translator U5 which is connected to microprocessor 11.
When pin 9 is low, pin 5 (CX) is connected to the common input pin 4. When pin 9 is high, then pin 3 (CY~ is connected to common pin 4.
The output of multiplexer 32 (FIG. 3d) is common pin 15 4 (C) to coil receiving amplifier 38 (FIG. 3b). In coil receiving amplifier 38, this input goes through resistor R40 to differential coil amplifier U4A at the inverting input. The noninverting input of amplifier U4 is connected through resistors R29 back to the common side of 20 the coils. Amplifier U4A is configured in a linear differential amplifier configuration and its output is an analog voltage proportional to the differential voltage across the receiving coil. The output of amplifier U4A
goes to the noninverting input of amplifier U4B. The 25 inverting input of amplifier U4A is tied to resistor 30 and to the noninverting input of U4B. Resistor R30 is a feedbac~ resistor from the output of amplifier U4A pin 8 to the inverting input pin 9, which is part of the differential amplifier configuration. The inverting input 30 of amplifier U4B goes through feedback resistor R31 from the output of amplifier U4B. Amplifier U4B provides additional gain off the first stage of amplification from amplifier U4A. Two stages of amplification are used to provide the required band wid~h and gain needed to 35 effectively reproduce the voltage waveform that is being monitored.
-l s- 12~8494 The output of amplifier U4B goes into multiplexer 42 which is another section of multiplexer U6. It enters pin 1 (BY) of multiplexer U6 which comprises analog mu1tiplexer 42. From there the signal goes to the pin 15 5 (BCOM), when multiplexer 42 is in the proper position, as controlled by lnput pin 10 (B) which ultlmately comes from microprocessor 11. When input at pin 10 is in the high state, pin 1 (BY) will be connected to pin 15 (BCOM). The output BCOM goes throu~h a filter network consisting of a 10 cdpacitors C7 and C25, resistors R38 and R39 and clamping diodes CR9 and CR10. The s~gnal eventually arrives at another section of the multiplexer whlch ts pin 13 (AY).
Pin 13 (AY) will be connected to pin 14 (ACOM) when the controlling input at pin 11 (A) is at a logical 1. This 15 control comes from microprocessor 11. Output from pin 14 (ACOM) is buffered by dmplifier U4D wh1ch is a unity gain amplifier. This amplifier provides low impedance dr~ve to the input of andlog to digital converter 58. Section C of multip1exer U6 is used to chuose one of two co1ls for d 20 voltdge readback. Section B either selects voltage input from coil amplifier U4B or selects lnput BX from the current amplifier. When control input B at pin IO of multiplexer U6 is at a O level, BX will then be connected to BCOM. The signal from BCOM output will now go through 25 the same input filter network as mentioned previously.
The signal is then ultimately connected to the analog to digital converter 58.
A line from battery 50 for sensiny battery voltage c~mes through the resistor dlvider network consisting of 30 resistors R43 and R44. Analog to digltal converter S8 only accepts voltages up to 5 volts, so battery voltage is divided down before being supplied to converter 58.
Divided down battery voltage is selected when input AX is connected to ACOM. Th~s occurs when pin ll (A) 1s set at 35 logic 0. When pin 11 tA) is at a log~c 1. the AY is connected to read current or voltages. Sampling analog to digital converter 58 includes converter U17. A siynal 125~349 from multlplexer 42 arrlves on pln 2 of conver~er U7 which is called VIN. Reference input on pln 1 comes from a 5 volt supply line. Capacitor C24 is connected from pin 1 to ground. Capacitor C24 provides fi1tering on the 5 reFerence input to minimize noise and r1pple on the line to provlde a stable reference lnput. Frequency d~vider U16 provldes a c10ck slgnal. Frequency dlvlder U16 ts d 2:1 frequency d1vlder. The base frequency ls supplled ~n pln 3 of dtvlder U16 wh~ch comes from enable lnpu~ pln 40 10 of mlcroprocessor 11. The baslc bus system clock runs dt 500 kllohertz. Dlvider U16 dlvldes thls down to a suitable frequency for converter U17.
Sampllng A to D converter U17 (FIG. 39~ ls initiated by pulling the write pin 15 low in con~unction with 15 forcing the pin 16 chlp select llne low. Pins 15 and 16 are controlled by microprocessor 11. Select pln 16 is brought low whenever any address in the range CXXX-DXXX
is decoded by address decoder U13. Connections from the mlcroprocessor 11 to converter U17 are on the common data 20 bus. This connectlon ls on bus lines Do-D7.
After a period of a few hundred microseconds, the conversion process will be complete and interrupt line pin 13 of converter U13 will pulse low indicating conversion is complete. At that time, microprocessor 11 reads 25 results of the conversion by causing read pin 14 of converter U17 to pulse low a)ong wlth select pin 16 of converter U17. The results of the conversion are then a~ailable on the data bus lines Do-D7.
Standby circuit and latch 68 (FIG. 3e) lncludes NAND
30 gates U8A and U8B and transistors Q10 and Qll . Transistor Q10 is a P-channel junction FET. Transls~or Qll is an enhancement mode power FET. The latch lncludes the two NAND gates U8A and U8B connected together in d reset/set latch configuration, which functions ln a manner slmilar 35 to the overcurrent latch 16. The output of the latch goes to the gate of power FET Qll. The source of transistor Qll is connected to ground. When the c~rcuit is in a standby state, pin 3 of U8 wlll be high at a logic l which turns on trdnsistor Qll, which in turn brlngs the drain very near to ground. This causes the reset input of mlcroprocessor 11 p1n 6 to be ln a low stale. At that 5 time the microprocessor 11 is in the reset condition. At the same time STBY latch would be in a low state which forces the microprocessor to be in the standby mode. At this time power consumption of microprocessor 11 wi I 1 be minimal. The internal clock is not running. The RAM
lO memory stays alive.
The input at pin 12 of NAND gate U8D comes from diode ~Rl5 and CR16 whlch are in turn connected to patient switch 64 and physician swi~ch 6~. When either swltch is depressed, the cathodes of dlodes CR15 or DR16 will be lS connected to ground, which ln turn connects the common anodes of dlodes CR15 and CRl6 to one dlode drop abov~
- ground. Thls in turn pulls pin 12, the standby latch clear lnput, to ground. When thls lnput ~s brough t~
ground, the not-standby pin 11 goes to d h1gh state and 20 the standby latch ls cleared. This actlon in turn stdrt~
the process of microprocessor 11 coming out of standby mode. The not-standby input (pin 7) to microprocessor 11 goes high.
Sllghtly later, the gate of trdnslstor Qll wlll go 25 low at pin 3, the opposite slde of the latch will be ~n the opposite staLe. The drain of trdnsistor Qll will then start ~olng high as determlned by an RC network of resistor 46 and capacitor C19. Thls wlll exponentially rise. Eventually this voltage causes the reset input of 30 Ull to go to the high state, and microprocessor 11 starts runnlng.
Translstor qlo provides a secondary low voltage detect circuit to force the standby latch to be set into standby mode when voltage on the gdte (which comes from - 35 YDD) is below a threshold~ When voltage VDD drops below the threshold gate voltage of translstor QlO, lt will conduct. The drain is connected to ground thus pulling pin 2 of U8 to Lhe low state which forces the standby latch into standby. Durin~ normal operation, the gate of trdnsistor Q10 is at a relatlvely high level around 12 volts. In that case, p~n 2 stays high unless 5 forced low by another input. The other input comes through diode CR13 and through a ~ultiplexer U10 ultimately from port 20 of microprocessor 11. Therefore, port 20 of microprocessor 11 has the ability to control or force the latch into standby as well. When port 20 pu~ses 10 low, it causes pin 2 of gate U8A to pulse low. Thls puls the system in standby.
The se~ of resistors U18A comprises pull up resistors used in various places in the circuit. These resistors pull up patient switches and pull up a set of input 15 conditions on chip U10. The function of multiplexer U10 is to initialize the microprocessor 11 in the proper state at the time of reset, but allow P20, P21, and P22 to be used elsewhere when not in reset.
Power switches 76 (FIG. 3d) include three different 20 switches. All switches are P-channel power MOS FET
transistors. Transistor Q5 controls the switched higher voltdge of approximately 12 volts whlch is called VDs.
When the gate of transistor Q5 is brough to a low state, transistor Q5 turns on so that VDs will be at 25 essentially the same voltage dS the higher 12 volt supply VDD. When the standby latch ls set, the gate of Q5 is brough high and the transistor ls turned off. Voltage is translated in the circuit by voltage controller U5 which serves as voltage translation from the 0-5 volt level of 30 microprocessor 11 to the 0-12 volt level required for controlling the gate of trans~stor Q5.
The other two power switches are transistors q6 and Q7 which control two switched 5 volt supplies. One is YCs from Q6 drain which is a 5 volt power use for the 35 majority of the circuit. The other vol~age comes from the drain of transistor Q7 and is the analog to digital reference voltage. This reference is also at 5 volts.
~258~4 The reference 5v is lsolated through a sepdrate swi~ch ~o minimize noise on the line. Translstors Q6 and Q7 dre turned on when the gates are brought low via microprocessor 11 ~hrough standby latch control.
Another portion of voltage control that is comprlsed by coil driver circuitry 12 includes amplifier U4C and resistors R32, R33, and R34. This is a 9 ~olt supply. A
cdpacitor C10 filters in order to minimize noise on the supply line. The three reslstors R32 through R34 form 10 part of the amplifier configuration of amplifier U4C.
Resistors R33 and R32 provide feedback. Resistor R34 is an isolation resistor which prevents loading the output of a amplifier U4C with high capacitance which could cause instability in the amplifier.
Beeper 90 includes power FET trans1stor Q8 and a small electromagnetic transducer SPl. Transducer SPl acts as a small speaker. Translstor Q8 ls swltched on and off at a rate determined by d dr~ve slgnal emltted from por~
14 of microprocessor 11. The drdln of q8 ~s connec~ed 20 through resistor R48 ~o transducer SPl. Reslstor R4a ls d current llmlting reslstor to contro) amount of drlve power to the speaker. Resls~or R49 is connected to p~n 17 and to the source of transistor Q8, and then to ground.
Resistor 49 acts as a pull down resistor so tha~ when the 25 system is ln standby the beeper wlll be off and drawlng no current.
PARTS LIST
Resistors (Kohm) Resistors (Kohm) Rl 51 R30 200 30 R2 10 R31 24.9 R3 10 (Pot~ R32 110 R4 31.6 R33 270 R6 1 R35 10 ~Pot) RB 1 R37 4.7 ~L2S8494 R9 .01 ohm R38 100 Rll 100 R40 49.9 R12 100 R41 16.2 10 R18 17.4 R48 100 Rl9 100 R49 100 R20 16.2 R50 5.1 ohm R22 49.9 R52 49.9 R24 50 (Pot) R54 10 ohm R25 63.4 RS5 100 Capacitors (microfarads) Capacitors (microfarads) Cl .1 C13 .1 C2 6800 C14 .1 25 C3 .1 C15 ~ .1 C4 .1 C16 .1 C5 10 C17 ~1 C6 .1 C18 .1 ~7 .1 Cl~ 2.2 30 C8 .1 C20 100 C9 10 C21 .1 C10 10 C22 100 pf Cll 22 pf C23 100 pf C12 22 pf C24 .1 C25 .001 -21- ~258494 Diodes CRl Axial lead 1 amp CR3 Zener transient suppressor IN6288 CR6 Schottky IN5711 CR7 lN5354B
CR8 Axial lead 1 amp 10 CR9 Schottky IN5711 CR10 Schottky IN5711 CRll Schottky IN5711 CR12 Schottky IN5711 CR13 Schottky IN5711 15 CR14 Schottky IN5711 CR15 Schottky IN5711 CR16 Schottky IN5711 CR17 Zener transient suppressor IN6288 Transistors 20 Ql P channel MOSFET
Q2 Silicon switch Q3 IRF530 power FET
Q4 IRf530 power FET
Q5 ZVPOlA34 25 Q6 ZVPOlA34 Q7 ZVPOlA34 Q8 VN0106N3 N channel MOSFET
Q10 J17~
30 Qll VN0106N3 Miscellaneous Chips U1 Quad op amp LM324 U3 CMOS quad level shift 40109 35 U4 Quad op amp LM324 1258~94 U5 CMOS quad level shift 40109 U7 LM2931T voltdge reyulator U8 CMOS Quad NAND CD 4011B
U9 Quad NAND gate 74HCOO
U11 Hitdchi HD6303B
U12 7411C373 latch U13 HCMûS decoder 74HC138 U14 Hitachi or Ferranti 27C64, 8Kx8 EPROM
U15 CMOS D to A converter 1008 U17 MSM5204 RS, OKI semlconductor SOFTWARE DESCRIPTION
As described above in the description of the circuit of the illustrated embodiment, microprocessor 10 controls 15 operation of the system.
Self-Fitting 1. At the start of self-fitting, check to see if physician switch 66 is depressed for eight seconds. If so, go on.
2. Display message "SELF-FITTING" and begin self-fitting procedure.
3. Orive coils 7 and 8 for one second with 6 volts to allow settling.
4. Is the overcurrent latch set~ If not, go on to 25 step 6.
5. Display the message "CHECK COILS CHECK CABLES"
and return to step 2.
and return to step 2.
6. Is battery voltage inadequate~ If not inadequate, go on to step 9.
7. Initiate bad battery mode.
8. Go into standby mode and return to step 1.
9. Pulse coils for one second in burst pattern for settling.
10. Set up multiplexer 42 to read current.
11. Drive colls for one second to allow settling.
12584~4
12584~4
12. Put out a burst of 11 pules with current read during pulse 1 and vol~age read From alternating coils during the last 10 pulses. Save all values.
13. Is coil current too high? If not, go on to step 5 14. If too high, go to step 5.
14. Based on peak current is this d tlblal coil? lf so, go on to step 17.
15. Based on peak current is this a navicular coil?
If not, go to step 5.
If not, go to step 5.
16. If a navicular coil, reset drive voltage to 10 volts and redo the 11 pu~se sequence to get coil paralneter vdlues.
17. Is coil voltage within range? If so, go on to step 19.
18. If coil voltage out of range display "COILS TOO
CLOSE" or "COILS TOO FAR" as appropriate and go to step 2.
CLOSE" or "COILS TOO FAR" as appropriate and go to step 2.
19. Set digital to analog converter 58 using self-fitting look-up table values for specified coil
20 type.
20. Pulse dummy burst for 2 seconds for output amplitude settling.
20. Pulse dummy burst for 2 seconds for output amplitude settling.
21. Emit bursts of 11 pulses reading current on first pulse and coil voltages on alternate coils For ten 25 pulses.
22. Perform checks on new coil voltages. Read back and store average read back voltage and current for future reference during treatment.
23. Was an error detected after self-f~tting?
24. If error, display "SELF-FIT ERRORU and go to 2.
25. If no error, display "SELF-FIT O.K." and go on.
26. Begin treatment.
The look up table is a table cross referencing drive 35 voltage versus read back voltage. Read back values below a certain ~alue on the table are considered to show that coils are too far apart. Values above a certain level on 1~258494 the tabte are believed to show that the coils are too close together. A particular set of tables are established for each type of coll used on the system.
The therapy pulses provided in thls system are in 5 bursts. During normal output pulse generation, pins P12 and Pl~ are pulsed simultaneously to drlve output power FETS on and off. Pins P12 and Pl3 are pulsed high for 190 microseconds and low for 80 microseconds. Pulsln~ is continued for 21 pulses to complete the burst sequence.
10 Burst patterns are repeated at the rate of 15 H~. Pin Pl5 is pulsed as a logical "AND" of pins P12 and P13. That is, pin P15 is high whenever pins P12 and Pl~ are pulsed high.
Overcurrent Latch _ .
Perlodlcally, the condltlon of pln Pll ls checked for an overcurrent mode. Pln Pll should normally be a "1" to lndlcate normal operation. When p~n Pll ~s a "O", the output pulse generation is interrupted and the treatment tlmer ls stopped. The overcurrent latch ls reset by 20 pulslng pin P10 low. Pln P10 is pulsed low and then brought high during a return from standby sequence and following an overcurrent condition durlng a non-pulsed time period~ Pln P10 should be pulsed within 10 second of an overcurrent indication, but not less than 5 seconds 25 followlng an overcurrent indlcatlon.
Current ~easurément When coil current is measured, pin 22 is set high and pin 23 is set low. Pin 24 can be in elther state. During an output pulse sequence, a write ls done to analog to 30 digital converter 58 to start the sample and hold cycle 150 mlcroseconds after the ristng edge of the output pulse from pin P12 and P13. The analog to digltal converter 58 is read after appropriate time to allow completion o~
conversion. The converslon factor in this embodiment is 35 FFH ~full scale~ for current of 12 amperes.
-25 ~ 2 S ~ 9 Coil Voltage Measurement To measure the voltage induced in a coil, the pulse drive to the coil is shut off and the opposite coil is driven. For measuring coil 7 voltage, p~n P24 ls set low 5 and pins P22 and 23 are set high. Normal pulsing sequence is lnterrupted by pulsing only pin P13 hlgh and keeping pin P12 low for one pulse at the flrst pulse of a burst sequence. Then analog to dig~tal converter 58 is caused to sample and hold 90 microseconds after the leading edge 10 of the pin P13 pulse to sample coil voltage approximdtely at the pulse m~dpo~nt. The analog to dig~tal converter 58 is read after an appropriate delay. The conversion factor is FF (full scale) for a coil voltage of 1250mV. To measure coil 8 voltage, pln 24 is set high and pin P22 dnd 15 P23 are kept high. Pin P12 only ls pulsed and the above procedure is repeated.
Analog To Digital Multiplexer The multiplexer 42 controlled by pin P23 is switched at least 60ms prior to making a coil voltage or current 20 measurement to allow voltage at analog to digital conversion input to stabilize.
Current Check At least once every ~0 seconds, the Inicroprocessor measures the current in both coils pulsed at the 25 VDRIvE voltage. Current is measured on the first pulse of a burst sequence only. This current is compared with a reference current for the coils (ICOILS REF) prev~ously measured. I~ the current measurements are not within 15 percent of each 30 other, the message "CHECK COILS/CHECK CABLES" ls dlsplayed.
Field Strenght Check Field strength chec~s are performed during burst sequences. Approxlmd~ely once every 10 seconds (every 150 35 burst sequences) coil voltage ls measure~ from each coil ~258~9 on the start of four consecutive burst sequences (a total of 4 readings~. Two burst coil readln~s are compared with each other and two second coll readings are compared with each other. If the readings are not within 10 percent of 5 each other the followlng message is displayed:
"ELECTRICAL NOISE".
The two first coil readings are averaged and compared wi~h the averages of the two second coil readings. If the two averages compare within 15 percent of each other, the 10 treatment is continued. Otherwise the following message is displayed: "CHECK COILS/CHECK CABLES" .
Al 1 four readings are averaged and compared wlth d reference average. If they are within 15 percent of each other, tredtment ls continued. Otherwise the followiny 15 message is displayed: "COILS MISPLACED".
Total Elapsed Treatment Time Whenever the unlt is operating to provide a burst pattern output, an internal timer keeps track of total elapsed treatment time. The timer is stopped whenever an 20 error condition occurs and lt stops normal trea~ment output. Thls time is displayed when requested by the physiclan push button switch. The t~me ls rounded to the nearest hour for total elapsed treatment time.
Treatment Time Per Sess~on _ 2S Another timer ~eeps track oF the treatment tlme per session to a resolution of 0.1 hour. This time is displayed as part of the message " _._ TREAT HOUR".
Number Of Treatment Sessions A counter keeps track of the number of tlmes the unlt 30 ran for at )east 1/2 hour between d pat~ent sw~tch activation and a patient-act~vated of f cond~tion. Thus, a minimal treatment session is establlshed as 1/2 hour. The number of treatment sessions is d~splayed by proper activation of the physic-ian push button.
The look up table is a table cross referencing drive 35 voltage versus read back voltage. Read back values below a certain ~alue on the table are considered to show that coils are too far apart. Values above a certain level on 1~258494 the tabte are believed to show that the coils are too close together. A particular set of tables are established for each type of coll used on the system.
The therapy pulses provided in thls system are in 5 bursts. During normal output pulse generation, pins P12 and Pl~ are pulsed simultaneously to drlve output power FETS on and off. Pins P12 and Pl3 are pulsed high for 190 microseconds and low for 80 microseconds. Pulsln~ is continued for 21 pulses to complete the burst sequence.
10 Burst patterns are repeated at the rate of 15 H~. Pin Pl5 is pulsed as a logical "AND" of pins P12 and P13. That is, pin P15 is high whenever pins P12 and Pl~ are pulsed high.
Overcurrent Latch _ .
Perlodlcally, the condltlon of pln Pll ls checked for an overcurrent mode. Pln Pll should normally be a "1" to lndlcate normal operation. When p~n Pll ~s a "O", the output pulse generation is interrupted and the treatment tlmer ls stopped. The overcurrent latch ls reset by 20 pulslng pin P10 low. Pln P10 is pulsed low and then brought high during a return from standby sequence and following an overcurrent condition durlng a non-pulsed time period~ Pln P10 should be pulsed within 10 second of an overcurrent indication, but not less than 5 seconds 25 followlng an overcurrent indlcatlon.
Current ~easurément When coil current is measured, pin 22 is set high and pin 23 is set low. Pin 24 can be in elther state. During an output pulse sequence, a write ls done to analog to 30 digital converter 58 to start the sample and hold cycle 150 mlcroseconds after the ristng edge of the output pulse from pin P12 and P13. The analog to digltal converter 58 is read after appropriate time to allow completion o~
conversion. The converslon factor in this embodiment is 35 FFH ~full scale~ for current of 12 amperes.
-25 ~ 2 S ~ 9 Coil Voltage Measurement To measure the voltage induced in a coil, the pulse drive to the coil is shut off and the opposite coil is driven. For measuring coil 7 voltage, p~n P24 ls set low 5 and pins P22 and 23 are set high. Normal pulsing sequence is lnterrupted by pulsing only pin P13 hlgh and keeping pin P12 low for one pulse at the flrst pulse of a burst sequence. Then analog to dig~tal converter 58 is caused to sample and hold 90 microseconds after the leading edge 10 of the pin P13 pulse to sample coil voltage approximdtely at the pulse m~dpo~nt. The analog to dig~tal converter 58 is read after an appropriate delay. The conversion factor is FF (full scale) for a coil voltage of 1250mV. To measure coil 8 voltage, pln 24 is set high and pin P22 dnd 15 P23 are kept high. Pin P12 only ls pulsed and the above procedure is repeated.
Analog To Digital Multiplexer The multiplexer 42 controlled by pin P23 is switched at least 60ms prior to making a coil voltage or current 20 measurement to allow voltage at analog to digital conversion input to stabilize.
Current Check At least once every ~0 seconds, the Inicroprocessor measures the current in both coils pulsed at the 25 VDRIvE voltage. Current is measured on the first pulse of a burst sequence only. This current is compared with a reference current for the coils (ICOILS REF) prev~ously measured. I~ the current measurements are not within 15 percent of each 30 other, the message "CHECK COILS/CHECK CABLES" ls dlsplayed.
Field Strenght Check Field strength chec~s are performed during burst sequences. Approxlmd~ely once every 10 seconds (every 150 35 burst sequences) coil voltage ls measure~ from each coil ~258~9 on the start of four consecutive burst sequences (a total of 4 readings~. Two burst coil readln~s are compared with each other and two second coll readings are compared with each other. If the readings are not within 10 percent of 5 each other the followlng message is displayed:
"ELECTRICAL NOISE".
The two first coil readings are averaged and compared wi~h the averages of the two second coil readings. If the two averages compare within 15 percent of each other, the 10 treatment is continued. Otherwise the following message is displayed: "CHECK COILS/CHECK CABLES" .
Al 1 four readings are averaged and compared wlth d reference average. If they are within 15 percent of each other, tredtment ls continued. Otherwise the followiny 15 message is displayed: "COILS MISPLACED".
Total Elapsed Treatment Time Whenever the unlt is operating to provide a burst pattern output, an internal timer keeps track of total elapsed treatment time. The timer is stopped whenever an 20 error condition occurs and lt stops normal trea~ment output. Thls time is displayed when requested by the physiclan push button switch. The t~me ls rounded to the nearest hour for total elapsed treatment time.
Treatment Time Per Sess~on _ 2S Another timer ~eeps track oF the treatment tlme per session to a resolution of 0.1 hour. This time is displayed as part of the message " _._ TREAT HOUR".
Number Of Treatment Sessions A counter keeps track of the number of tlmes the unlt 30 ran for at )east 1/2 hour between d pat~ent sw~tch activation and a patient-act~vated of f cond~tion. Thus, a minimal treatment session is establlshed as 1/2 hour. The number of treatment sessions is d~splayed by proper activation of the physic-ian push button.
-27-Physician Push Button The physician push button swltch 66 overrides the display 80 when it is displaying patient information. The slngle push button serves four functions: (1) request 5 proper field strength, (2) request total time wlth therapy, (3) request total number of therapy sessions, and (4) reset therapy timer and counter and initialize self-fltting.
When physic~an swltch 66 is first actuated, display 10 80 displays the message "MA6. STRENGTH O.K.", if the unit is currently operating properly and self-fittlng has already occurred. If an error conditlon results, one of the following messages would be displayed just as if the system were in patient mode: "CHECK COILS/CHECK CABLES", 15 "ELECTRICAL NOISE", "SELF-FIT ERROR", or "COILS
MISPLACED".
A second activation of physician switch 66 causes the following message to be displayed: " _ _ _ TOTAL HOURS"
with the number of treatment hours inserted.
The third act1vatlon of the physlcian switch 66 causes the following display: "_ _ _ TX. SESSIONS", with the number of sessions inserted.
The fourth activation causes the unit to revert to the same action as ~he first activation ~o start the 25 sequence over again. If self-fitting has not occurred since the last power-up sequence, the physician switch, when depressed any number of tlmes, causes display of the message "START FITTlNG".
Pushlng and holding physician switch 66 at any time 30 for more than eight seconds causes the treatment hours timer and number of treatment sessions to reset. It then initiates a self-fittlng procedure and displays the message: "SELF-FITTING".
If the phys~cian switch 66 has not been actuated for 35 the last 60 seconds, display 80 automat~cally reverts to the normdl dlsplay mode for pat~ent information.
When physic~an swltch 66 is first actuated, display 10 80 displays the message "MA6. STRENGTH O.K.", if the unit is currently operating properly and self-fittlng has already occurred. If an error conditlon results, one of the following messages would be displayed just as if the system were in patient mode: "CHECK COILS/CHECK CABLES", 15 "ELECTRICAL NOISE", "SELF-FIT ERROR", or "COILS
MISPLACED".
A second activation of physician switch 66 causes the following message to be displayed: " _ _ _ TOTAL HOURS"
with the number of treatment hours inserted.
The third act1vatlon of the physlcian switch 66 causes the following display: "_ _ _ TX. SESSIONS", with the number of sessions inserted.
The fourth activation causes the unit to revert to the same action as ~he first activation ~o start the 25 sequence over again. If self-fitting has not occurred since the last power-up sequence, the physician switch, when depressed any number of tlmes, causes display of the message "START FITTlNG".
Pushlng and holding physician switch 66 at any time 30 for more than eight seconds causes the treatment hours timer and number of treatment sessions to reset. It then initiates a self-fittlng procedure and displays the message: "SELF-FITTING".
If the phys~cian switch 66 has not been actuated for 35 the last 60 seconds, display 80 automat~cally reverts to the normdl dlsplay mode for pat~ent information.
-28-Normal Patient Informat~on Dlspldy Mode Display 80, when no~ being overr~dden by physician switch 66, dlsplays the followlng message lf the unit is operating properly: " _._ TREAT. HOUR~. If the unit is 5 not operating properly, one of the error messages will be displayed.
If the self-fitting procedure has not been correctly initiated since the last power-up sequence, the "NOT
SELF-FITTED~ message is displayed. The uni~ will not 10 provide treatment output without self-fltting since the correct amplitude In not determined.
Patient On/Off Switch The flrst actuation of patient switch 64 brings Lhe unit out of standby mode. A second actuation causes - 15 standby mode when in patient mode. When the unit is powered up by a patient, the treatment time displayed starts from 0. If the patient switch 64 is pushed once while in physician mode~ the ~nit goes to patient mode.
Battery Voltage To read battery voltage, pin P22 is brought to 0.
The state of P23 and P24 is irrelevant. The analog to dlgital converter 58 ls read. The actual battery voltage is four tlmes the reading. Battery voltage ls periodlcally sampled a~ a time 1 to 30 milliseconds before 25 the start of the burst sequence.
When this sample voltage reads from 11.9 vol ts to 11.6 volts, the following message ~s displayed: "CHARGE
BATTERY". The unit keeps operating and the beeper is actuated once every minu~e.
When battery voltage reads from 11.6 volts to 10 volts, the following message is displayed: "CHARGE
BATTERY". The system discontinues treatment and the beeper ~s actuated once every 10 seconds.
When battery voltage falls below 10 volts, the 35 microprocessor is ca~sed to go lnto s~andby mode. If 10 lZ58~94
If the self-fitting procedure has not been correctly initiated since the last power-up sequence, the "NOT
SELF-FITTED~ message is displayed. The uni~ will not 10 provide treatment output without self-fltting since the correct amplitude In not determined.
Patient On/Off Switch The flrst actuation of patient switch 64 brings Lhe unit out of standby mode. A second actuation causes - 15 standby mode when in patient mode. When the unit is powered up by a patient, the treatment time displayed starts from 0. If the patient switch 64 is pushed once while in physician mode~ the ~nit goes to patient mode.
Battery Voltage To read battery voltage, pin P22 is brought to 0.
The state of P23 and P24 is irrelevant. The analog to dlgital converter 58 ls read. The actual battery voltage is four tlmes the reading. Battery voltage ls periodlcally sampled a~ a time 1 to 30 milliseconds before 25 the start of the burst sequence.
When this sample voltage reads from 11.9 vol ts to 11.6 volts, the following message ~s displayed: "CHARGE
BATTERY". The unit keeps operating and the beeper is actuated once every minu~e.
When battery voltage reads from 11.6 volts to 10 volts, the following message is displayed: "CHARGE
BATTERY". The system discontinues treatment and the beeper ~s actuated once every 10 seconds.
When battery voltage falls below 10 volts, the 35 microprocessor is ca~sed to go lnto s~andby mode. If 10 lZ58~94
-29-volts or less is measured on the first battery check after patient actuation, when coming out of standby mode, the following message is displayed: "CHARGE BA~TERY". The beeper goes on and o~f for 15 seconds before the system 5 goes back to standby mode.
Standby Mode Following a patient-actuated off condition, microprocessor 10 pulses pin P20 low to cause the standby flip-flop to set. Pin P20 should normally be in the high 10 state. Stdndby action removes the supply voltages from most of the clrcuitry to conserve power and extends battery life to hold the RAM contents. When a batLery voltage of less than 10 volts is detected, the s~andby flip-flop wil) a1so be set. The standby flip-flop is 15 cleared by activation of the patient switch 64 position switch 66.
B eeper The audible beeper 80 is pulsed for approximately 1 second each 10 seconds during dlsplay of the messdye dS
20 described elsewhere in thls section. The beeper ~s driven from pin P14 wi~h ~500 to 3000 Hz pulses at approxilnd~ely 50 percent duty cycle. Pin P14 will normally be placed in the low state when not actuating the beeper 90.
Error Condition Response An error condition resulting in an error message of "CHECK COILS/CHECK CP~BLES", "SELF-FITTING", "ELECTRICAL
NOISE" or "COILS MISPLACED" during normal patient opera~ion mode results in termination of output pulses for 10 seconds followed by burst sequences during which the
Standby Mode Following a patient-actuated off condition, microprocessor 10 pulses pin P20 low to cause the standby flip-flop to set. Pin P20 should normally be in the high 10 state. Stdndby action removes the supply voltages from most of the clrcuitry to conserve power and extends battery life to hold the RAM contents. When a batLery voltage of less than 10 volts is detected, the s~andby flip-flop wil) a1so be set. The standby flip-flop is 15 cleared by activation of the patient switch 64 position switch 66.
B eeper The audible beeper 80 is pulsed for approximately 1 second each 10 seconds during dlsplay of the messdye dS
20 described elsewhere in thls section. The beeper ~s driven from pin P14 wi~h ~500 to 3000 Hz pulses at approxilnd~ely 50 percent duty cycle. Pin P14 will normally be placed in the low state when not actuating the beeper 90.
Error Condition Response An error condition resulting in an error message of "CHECK COILS/CHECK CP~BLES", "SELF-FITTING", "ELECTRICAL
NOISE" or "COILS MISPLACED" during normal patient opera~ion mode results in termination of output pulses for 10 seconds followed by burst sequences during which the
30 error condition is retes~ed. If the error condition disappears, output pulses continue.
If any error condition (except low battery) continues during patient mode for more than 7 minutes, output pulses are terminated and the unit goes to standby.
30_ ~5~494 Checksum Test Each tlme the unlt 1s placed in operation after return from standby, a checksum test wlll be performed on PROM memory. If this is normal, operation will continue 5 as described. Otherwise the beeper wlll beep briefly and the unlt will go to standby mode.
What ls claimed is:
If any error condition (except low battery) continues during patient mode for more than 7 minutes, output pulses are terminated and the unit goes to standby.
30_ ~5~494 Checksum Test Each tlme the unlt 1s placed in operation after return from standby, a checksum test wlll be performed on PROM memory. If this is normal, operation will continue 5 as described. Otherwise the beeper wlll beep briefly and the unlt will go to standby mode.
What ls claimed is:
Claims (9)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A medical device for inducing electrical current within a patient's body by creating a magnetic field through the body comprising:
first coil for placement in a treatment relation to a patient's body;
second coil for placement in a second treatment relation to the patient's body so that the first coil and second coil are in a generally flux-aiding relation to each other;
driver circuitry for providing pulsed electrical energy to the first and second coils;
control means operably connected to the driver circuitry for controlling the magnitude of the electrical energy;
multiplexer means connected to the first coil and second coil and operably connected to the control means for selecting one coil; and the control means including means for indicating to the multiplexer means that one of the coils is selected for driving by the coil driver and the other of the coils is selected for sensing magnetic field induced by said one of the coils, and for automatically adjusting the magnitude of electrical energy produced by the driver circuitry based upon sensed magnetic field.
first coil for placement in a treatment relation to a patient's body;
second coil for placement in a second treatment relation to the patient's body so that the first coil and second coil are in a generally flux-aiding relation to each other;
driver circuitry for providing pulsed electrical energy to the first and second coils;
control means operably connected to the driver circuitry for controlling the magnitude of the electrical energy;
multiplexer means connected to the first coil and second coil and operably connected to the control means for selecting one coil; and the control means including means for indicating to the multiplexer means that one of the coils is selected for driving by the coil driver and the other of the coils is selected for sensing magnetic field induced by said one of the coils, and for automatically adjusting the magnitude of electrical energy produced by the driver circuitry based upon sensed magnetic field.
2. The device of claim 1, wherein the control means includes means for periodically sensing and for producing a warning signal if an improper field is sensed.
3. The device of claim 1, wherein the control means includes means for periodically sensing and for auto-matically adjusting during therapy.
4. A self-fitting electromagnetic bone growth stim-ulator comprising:
a first treatment coil for positioning adjacent a patient's body;
a second treatment coil for positioning adjacent a patient's body in a flux-aiding relationship which creates a magnetic field through a portion of the patient's body;
pulse generation means electrically connected to the first coil and the second coil for providing pulses of electrical energy to the first coil and the second coil;
control means electrically connected to the pulse generating circuitry for transmitting a magnitude signal to the pulse generation means indicative of a magnit-ude of the pulses of electrical energy;
sensing circuitry electrically connected to the first and second coils for sensing a magnetic field at one coil, which was produced by the other coil and for producing a sensed field signal indicative of field strength to the control means, the control means automatically adjusting the magnitude signal in response to the field strength signal.
a first treatment coil for positioning adjacent a patient's body;
a second treatment coil for positioning adjacent a patient's body in a flux-aiding relationship which creates a magnetic field through a portion of the patient's body;
pulse generation means electrically connected to the first coil and the second coil for providing pulses of electrical energy to the first coil and the second coil;
control means electrically connected to the pulse generating circuitry for transmitting a magnitude signal to the pulse generation means indicative of a magnit-ude of the pulses of electrical energy;
sensing circuitry electrically connected to the first and second coils for sensing a magnetic field at one coil, which was produced by the other coil and for producing a sensed field signal indicative of field strength to the control means, the control means automatically adjusting the magnitude signal in response to the field strength signal.
5. The device of claim 4, wherein the control means includes means for periodically sensing and for producing a warning signal if an improper field is sensed.
6. The device of claim 4, wherein the control means includes means for periodically sensing and for automatically adjusting during therapy.
7. A device for automatically self-fitting an induction coil bone growth stimulator of the type having at least two coils for treating a patient comprising:
means for providing pulsed electrical energy to first and second coils;
means connected to the first and second coils for selecting one coil as a sense coil;
control means operably connected to the means for providing pulsed electrical energy and to the multiplexer means for indicating to the multiplexer means to select one coil for sensing, for sensing electrical current in the sense coil; and for automatically adjusting electrical energy provided by the means for providing pulsed electrical energy.
means for providing pulsed electrical energy to first and second coils;
means connected to the first and second coils for selecting one coil as a sense coil;
control means operably connected to the means for providing pulsed electrical energy and to the multiplexer means for indicating to the multiplexer means to select one coil for sensing, for sensing electrical current in the sense coil; and for automatically adjusting electrical energy provided by the means for providing pulsed electrical energy.
8. The device of claim 7, wherein the control means includes means for periodically sensing and producing a warn-ing signal if an improper field is sensed.
9. The device of claim 7, wherein the control means includes means for periodically sensing and automatically adjusting during therapy.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US624,871 | 1984-06-27 | ||
| US06/624,871 US4548208A (en) | 1984-06-27 | 1984-06-27 | Automatic adjusting induction coil treatment device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1258494A true CA1258494A (en) | 1989-08-15 |
Family
ID=24503678
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000477881A Expired CA1258494A (en) | 1984-06-27 | 1985-03-29 | Automatic adjusting induction coil treatment device |
Country Status (2)
| Country | Link |
|---|---|
| US (1) | US4548208A (en) |
| CA (1) | CA1258494A (en) |
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- 1984-06-27 US US06/624,871 patent/US4548208A/en not_active Expired - Fee Related
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1985
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| US4548208A (en) | 1985-10-22 |
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