Not Applicable.
The present invention relates to switches and more particularly to switches which are responsive to magnet fields.
As is known in the art, there exists a relatively large number of commercially available devices having a base or stationary portion and a movable cover or door portion which include a magnet. For example, telephones, cellular telephones, notebook or laptop computers and refrigerators include magnets in the moveable door or cover portions. The covers are typically opened and closed and, in some cases, the magnets provide a magnetic force which maintains the cover or door in a particular position (e.g. a closed position).
Such devices can also include detectors or sensors which indicate when a door or cover is in an open or a closed position. For example, cellular telephones (cell phones) which are provided as so-called “flip phones,” include a base and a cover or “flip” portion. The cover has a magnet disposed therein. Disposed in the base portion of the cell phone is a sensor. When the cover is closed, the magnet is disposed over the sensor and the sensor detects the presence of the magnet's magnetic field. In response to the magnetic field, the sensor provides a signal which indicates that the cover is closed. Similarly, when the cover is open, the magnet (and hence the magnetic field) is removed from the sensor and the sensor provides a signal indicating that the cover is open.
In some applications, the sensor is provided as a Reed switch. The Reed switch is a mechanical type switch comprised of an evacuated glass tube having a series of metal fingers disposed therein. In response to the presence a magnetic field, the metal fingers are in mechanical contact thus providing a signal path having a short circuit impedance characteristic between the input and output terminals of the switch. Likewise, in the absence of a magnetic field, the mechanical fingers are not in contact thus providing a signal path having an open circuit impedance characteristic between the input and output terminals of the switch.
Reed switches have the advantage that the switch operates regardless of the orientation of the magnet with respect to the switch. That is the Reed switch need not be oriented in a particular manner with respect to the poles of the magnet. This allows for easy replacement of the magnet or the Reed switch since there is not physical relationship between them.
One problem with the Reed switch approach, however, is that the Reed switch is relatively large and expensive when compared with semi-conductor type switches. Also, the Reed switch is a mechanical type switch and thus is not as reliable as a solid state devices.
In view of the above problems with the prior art approach it has, in accordance with the present invention, been recognized that it would be desirable to provide a replacement for mechanical type switches such as Reed switches.
One problem with using a semiconductor switch in place of the Reed switch, however is that semiconductor devices, which include elements such as a Hall element, must be aligned in a particular manner with respect to the north and south poles of the magnet. If the magnet and Hall element are not properly oriented (i.e. the appropriate ends of the hall element are not aligned with the appropriate magnetic poles) then the semiconductor switch will not operate correctly. This leads to difficulties when it becomes necessary to replace the magnet or the semiconductor switch. For example, if a magnet must be replaced and neither the magnet nor the Hall element or switch are somehow coded so that it is known which end of the magnet to place at which end of the Hall element, then it is necessary to proceed by trial and error to determine how to install the replacement parts.
It would, therefore, be desirable to provide a reliable magnetic pole insensitive switch which can serve as a “drop-in” replacement for mechanical type switches such as Reed switches.
It would also be desirable to use a semiconductor switch including a Hall effect element as a drop in replacement for a Reed switch type device, however this requires the Hall element to be insensitive as to whether a north pole or south pole is being sensed.
In accordance with the present invention, a sensor for sensing an article which provides a magnetic field includes a magnetic-field-to-voltage transducer for generating at an output thereof a first signal voltage having a signal voltage level which is proportional to a magnetic field having a first polarity and a second signal voltage having a signal voltage level that is proportional to a magnetic field having a second different polarity and a window comparator having an input port coupled to the output port of the magnetic-field-to-voltage transducer to receive the first and second signal voltages and to provide an output signal having a first value when the article is within a first predetermined distance of the magnetic-field-to-voltage transducer regardless of the polarity of the magnetic field. With this particular arrangement, a drop in replacement for a Reed switch type device which is insensitive as to whether a north pole or south pole is being sensed is provided. By providing the comparator as a window or symmetrical comparator (i.e., a comparator having the same switching point for positive and negative magnetic fields) the sensor operates correctly regardless of the orientation of the magnet relative to the magnetic-field-to-voltage transducer.
In accordance with a further aspect of the present invention, a switch includes a Hall element and a threshold detector circuit having a substantially similar switching point for positive and negative magnetic fields. With this particular arrangement, a switch which utilizes a Hall effect device can operate correctly regardless of the orientation of the magnetic poles with respect to the Hall device. In one embodiment, the threshold circuit is provided as a comparator circuit.
The foregoing features of this invention as well as the invention itself may be more fully understood from the following detailed description of the drawings, in which:
The following description sets forth an exemplary embodiment in which the present invention may be used. Specifically, certain reference is made below to a cellular telephone (cell phone) application. It should be understood, however, that the present invention finds use in a wide variety of applications and devices and is not limited to the exemplary embodiment described below. For example, the invention may be used in any device or apparatus which uses a magnetic device in conjunction with a movable portion such as a movable cover or door including cellular and non-cellular telephones, notebook or laptop computers and refrigerators.
Referring now to
Disposed in the second end of the cover 14 is a magnetic article 18 such as a magnet. The magnet 18 has a first pole 18a and a second pole 18b. Depending upon how the magnet 18 is disposed in the cover 14 the first pole 18a may correspond to a north or south pole of the magnet and the second pole 18b will correspond to the other pole of the magnet.
Disposed in the base 12 is a semiconductor switch 20 which operates regardless of the orientation of the magnetic poles of magnet 18. One possible embodiment of the switch is described in detail below in conjunction with
The transducer provides a transducer output signal having a signal level which varies depending upon the orientation of the magnet 18 to the sensor. Thus, the transducer generates a first signal voltage having a signal voltage level which is proportional to a magnetic field having a first polarity and a second opposite signal voltage having an opposite signal voltage level that is proportional to a magnetic field having a second different polarity. In one embodiment, the transducer may be provided as a magnetic-field-to-voltage transducer.
Switch 20 also includes a comparator coupled to the transducer to receive the first and second signal voltages and to provide an output signal having a first value when the article is within a first predetermined distance of the magnetic-field-to-voltage transducer regardless of the polarity of the magnetic field. Thus, when the cover 14 is open the magnet 18 is displaced from the switch 20 and the switch 20 provides a switch signal having a first predetermined signal level regardless of the orientation of the magnet 18 with respect to the switch 20. Similarly, when the cover 14 is closed the magnet is proximate the switch 20 and the switch 20 provides a switch signal having a second predetermined signal level regardless of the orientation of the magnet 18 with respect to the switch 20.
The signal provided by switch 20 merely indicates whether the cover 14 is open or closed. Thus, when the cover is closed, the switch provides a first signal having a first value and when the cover 14 is open, the switch 20 provides a second signal having a second different value.
The signals provided by the switch 20 are coupled to a control circuit 22. The control circuit 22 implements, or causes to be implemented, certain functions depending upon the position of the cover 14 (i.e. depending upon whether the cover 14 is open or closed). For, example, when the cover is closed, switch 20 provides a signal to control circuit 22 so indicating and control circuit 22 may cause cell phone 10 to operate in a power saver mode.
Referring now to
The Hall effect device 30 acts as a magnetic-field-to-voltage transducer which generates at output terminals 31a, 31b a first signal voltage having a first signal level voltage which is proportional to a magnetic field having a first polarity and a second signal voltage having a second signal voltage level that is proportional to a magnetic field having a second different polarity. The comparator 32 receives the signals on terminals 31a, 31b.
It will be appreciated by those of ordinary skill in the art that other magnetic-field-to-voltage transducers may be used. As one example, the Hall effect device 30 may be replaced with a magneto-resistive bridge, including a magneto-resistive element and a bridge configuration, such as a Wheatstone bridge. The magneto-resistive element is a resistive device, such as a metallic thin film resistor, having a resistance that changes depending on the angle between the flux and the device. More particularly, the magneto-resistive element senses flux parallel to the plane of the device and normal to current flow.
The comparator 32 provides an output signal having a first value when the magnet 18 is within a first predetermined distance of the transducer 30 regardless of the polarity of the magnet 18. The comparator 32 provides an output signal having a second different value when the magnet 18 is not within the first predetermined distance of the transducer 30 regardless of the polarity of the magnet 18. Thus, regardless of whether the second end 18b of magnet 18 is a north or a south pole, the switch 20 provides a signal indicating whether the magnet 18 is proximate the sensor 14. Thus, the switch 20 provides, for example, an indication of whether the cover 14 (
Referring now to
The comparator 38 includes a first input terminal 38a coupled at input port 35b to the input voltage VIN and a second input terminal, 38b, coupled to a threshold voltage VTL at terminal 35c. An output terminal 38c of comparator 38 is coupled to provide the output voltage VOUT at the output terminal 35d.
In this particular embodiment, comparators 36, 38 are provided having a means for including hysteresis such that the reference or threshold voltages VTH, VTL can be represented as VTH+ and VTH− and VTL+ and VTL−, respectively. The values VTH+, VTH−, VTL+, VTL− represent the comparator switch points depending upon the value of the output voltage −VOUT. As indicated in
As can be seen in
If the output voltage VOUT is high and the input voltage VIN has a value greater than or equal to zero, when the input voltage VIN meets or exceeds the voltage VTH+, the output voltage switches from a value of VHIGH to VLOW and the switch point changes from VTH+ to VTH−. Thus the value of the output voltage VOUT will not switch from VLOW to VHIGH until the input voltage VIN reaches the value VTH−.
It should be appreciated that in other embodiments and applications it may be preferable to utilize comparators which do not have hysteresis and thus switching occurs at a single voltage level, namely VTH.
In operation, and with reference now to
If the magnetic field sensing circuit is provided as a Hall device, a signal voltage is provided. Assuming the input voltage VIN is at or near zero volts (i.e. VIN=0 volts), the output voltage VOUT is at a first predetermined voltage level VHIGH which may correspond for example to a so-called transistor-transistor-logic (TTL) high voltage level. In response to a magnetic field, the Hall device provides either a positive or a negative input voltage VIN. If the input voltage provided by the Hall device moves in a positive direction from zero volts toward the threshold voltage, VTH+, when the threshold voltage meets and/or exceeds the threshold voltage level VTH+, then the output voltage VOUT changes from the predetermined signal level, VHIGH to a second predetermined voltage level VLOW which may correspond for example to a so-called TTL low voltage level. When the input voltage moves past the threshold voltage VTH− in a negative-going direction, the output voltage changes from VLOW back to VHIGH.
Likewise, as the input voltage moves in a negative direction from zero volts and reaches and/or exceeds the threshold voltage −VTL+, the output voltage VOUT changes from the first value VHIGH to the second value VLOW. Similarly, as the input voltage VIN moves from −VTL+ and reaches and/or exceeds the voltage level −VTL−, the voltage level then changes from the output voltage level VLOW to VHIGH.
Referring now to
The sensing and control circuit 44 provides a comparator output signal at terminal 44a to a control terminal 50a of a switch circuit 50. In this embodiment, the switch circuit 50 is shown as a transistor switch and in particular is shown as a bi-polar junction transistor (BJT). In this case, the control terminal 50a corresponds to a base terminal of the transistor 50. A second terminal 50b of the transistor 50 is coupled through a resistor 52 to a power supply 54 and to an output terminal 40a. A third transistor terminal 50c is coupled to a first reference potential, here corresponding to ground. It should be noted that although the switch circuit 50 is here shown as a BJT, those of ordinary skill in the art will appreciate that other types of transistors may also be used. For example, in some embodiments, it may be preferable to use a field effect transistor (FET).
Depending upon the proximity of a magnetic article to the magnetic detection circuit, the output signal provided at the output terminal 40a has one of a first and a second voltage level. When the magnetic field detection circuit 46 senses a strong magnetic field (such as would be the case, for example, with the cover 14 in
Similarly, with the cover open, magnetic field detection circuit 46 senses a relatively weak magnetic field and the comparator 48 provides a low signal voltage at the control terminal 50a and thus biases transistor 50 into its non-conductive state. In its non-conductive state, the transistor 50 provides a signal path having a relatively high impedance characteristic between the transistor terminals 50b and 50c and thus causes the output voltage VOUT at output terminal 40a to be a high voltage.
Referring briefly to
Table I shows that when a magnetic field is detected, the comparator 48 provides a signal which biases the transistor 50 into its conductive state (i.e. the transistor is ON). This results in the signal level of the signal VOUT being low. Similarly, when no magnetic field is detected, the comparator 48 provides a signal which biases the transistor 50 into its non-conductive state (i.e. the transistor is OFF). This results in the signal level of the signal VOUT being high. It should be noted that column of Table I labeled “Comparator Output” refers to the output of the comparator 48 prior to the inverter circuit.
Referring now to
The Hall element 60 is mounted such that the Hall voltage increases or decreases based upon the proximity of a magnet (not shown) to the Hall element 60. Alternatively, the detector circuit of
The Hall voltage signal is manipulated by the window comparator circuitry 62 to produce an output signal VOUT which provides an indication of whether any magnetic particle is within a predetermined distance of the Hall element 60.
The differential input signal is coupled through a filter and level shifter circuit 64. It should be appreciated that in an alternative embodiment the filter and level shifter circuit 64 could be provided as part of the Hall element circuit 60 rather than as part of the comparator circuit 62. The appropriately filtered and level shifted signals are coupled from the filter and level shifter circuit 64 to respective ones of differential pair circuits 66a, 66b.
Each of the differential pair circuits 66a or 66b, are provided to accept signals generated by the interaction of Hall circuit 60 with a respective one of the north or south poles of a magnet. As shown in Table II, the relationship of the magnet polarity to the Hall effect device (i.e. the orientation of the north and south magnet poles with respect to the Hall device) determines the output values provided by each the two differential pair circuits.
The output signals provided by the differential pair circuits 66a, 66b are fed to respective ones of output amplifier stages 68a, 68b generally denoted 68. The output amplifier stages 68 convert the differential voltage provided from differential pair circuits 66a, 66b into a single ended voltage which drives the inverter the inverter circuit 70. Those of ordinary skill in the art appreciate, however, that inverter circuits can be driven with single or differential lines. Those of ordinary skill in the art will also appreciate when it is preferable to drive an inverter circuit with differential lines rather than a single line.
The signals are then fed to an output/buffer amplifier stage 70 which is coupled to the output port 62c of the comparator 62. Comparator circuit 62 also includes a circuit 76 which includes a plurality of current sources which provide control signals to differential pair circuits 66a, 66b and to buffer circuit 68a, 68b.
A temperature and voltage compensation circuit 80 includes a plurality of current sinks 72a-72c which allow the comparator 62 to operate properly while withstanding a relatively wide range of voltage and temperature changes.
This is particularly important in devices, such as cell phones for example, in which the normal operating voltage of the device is relatively low (to conserve battery power and to operate in a power conservation mode, for example). Such low normal operating voltages combined with varying temperature ranges and variations due to standard manufacturing processes used to fabricate circuits, makes it relatively difficult to maintain switch points of comparator 62. To overcome difficulties, a comparator bias circuit 80 allows the comparator 62 to withstand low voltages which change by plus and minus 20%. To maintain the switch points of comparator 62 fixed over this relatively wide range of voltages, the comparator bias circuit 80 provides compensation signals to comparator 62 to allow the comparator 62 to operate over a wide range of voltage, temperature and process variations.
The dash line 81 between the current source 72c and the output terminal 62c indicates that the output controls the current source 72c. A first output level causes current source 72c to produce a relatively low current and a second different output level causes signal source 72c to produce a relatively high current.
As discussed above in conjunction with
Table II below shows the output signal value VOUT and the operation of the differential pair comparator circuits 66a, 66b with respect to the magnetic field characteristics.
As noted above the comparator 62 is symmetrical and thus (as illustrated in
The symmetrical comparator 62 of the present invention provides several advantages including: similar operation for both polarities of a magnet and operation which is independent of power supply voltage.
The comparator 62 and the bias circuit 80 may be implemented as a single integrated circuit to thus provide a relatively compact semiconductor switch circuit which is magnetic pole insensitive.
Having described preferred embodiments of the invention, one of ordinary skill in the art will now realize further features and advantages of the invention from the above-described embodiments. It should be understood, therefore, that the foregoing is only illustrative of the principles of the invention and that various modifications can be made by those skilled in the art without departing from the scope and spirit of the invention. Accordingly, the invention is not to be limited by what has been particularly shown and described, except as indicated by the appended claims.
This application is a continuation of U.S. patent application Ser. No. 09/997,148, entitled MAGNETIC POLE INSENSITIVE SWITCH CIRCUIT, filed on Nov. 27, 2001 now U.S. Pat. No. 6,622,012 which is a continuation of U.S. patent application Ser. No. 09/338,668, entitled MAGNETIC POLE INSENSITIVE SWITCH CIRCUIT, filed on Jun. 22, 1999 now U.S. Pat. No. 6,356,741 which is a continuation-in-part application of U.S. patent application Ser. No. 09/156,939, entitled MAGNETIC POLE INSENSITIVE SWITCH CIRCUIT, filed on Sep. 18, 1998 now abandoned.
Number | Name | Date | Kind |
---|---|---|---|
4204158 | Ricouard et al. | May 1980 | A |
4349814 | Akehurst | Sep 1982 | A |
4355209 | Sabon et al. | Oct 1982 | A |
4745363 | Carr et al. | May 1988 | A |
4761569 | Higgs | Aug 1988 | A |
4859941 | Higgs et al. | Aug 1989 | A |
4966041 | Miyazaki | Oct 1990 | A |
5442283 | Vig et al. | Aug 1995 | A |
5493690 | Shimazaki | Feb 1996 | A |
5541562 | Fletcher et al. | Jul 1996 | A |
5666410 | McLane | Sep 1997 | A |
5686894 | Vig et al. | Nov 1997 | A |
5789915 | Ingraham | Aug 1998 | A |
5861796 | Benshoff | Jan 1999 | A |
5867021 | Hancock | Feb 1999 | A |
6014008 | Hartzell et al. | Jan 2000 | A |
6035211 | Rabe et al. | Mar 2000 | A |
6356741 | Bilotti et al. | Mar 2002 | B1 |
6622012 | Bilotti et al. | Sep 2003 | B1 |
Number | Date | Country |
---|---|---|
0631416 | Dec 1994 | EP |
62-48160 | Mar 1987 | JP |
62048160 | Mar 1987 | JP |
7-15493 | Jan 1995 | JP |
7-83699 | Mar 1995 | JP |
09-294060 | Nov 1997 | JP |
Number | Date | Country | |
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20040027772 A1 | Feb 2004 | US |
Number | Date | Country | |
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Parent | 09997148 | Nov 2001 | US |
Child | 10623974 | US | |
Parent | 09338668 | Jun 1999 | US |
Child | 09997148 | US |
Number | Date | Country | |
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Parent | 09156939 | Sep 1998 | US |
Child | 09338668 | US |