The systems and methods disclosed in this document relate generally to the field of control systems and more specifically to the field of detection of proximity as a means of control.
Control systems can include a variety of mechanisms and methods to detect proximity of a target object to a base. In some cases, the target object can be a human operator of an industrial machine such as a cutting tool or press. In other cases, the target object can be some item that may be moved or carried away. Other applications for which a need or desire to monitor proximity of some person or object relative to another position also exist or can be created.
During operation of an industrial machine, an operator may be positioned nearby to monitor and control its operation. At times, the operator may need to approach the industrial machine. In this case, the industrial machine can be equipped with a proximity sensing system that monitors the position of the operator. If the operator moves too close to the industrial machine during operation, or in other cases, too far away from the machine, the proximity detection system can power down the industrial machine to prevent harm to the operator.
In accordance with one embodiment, a detection system comprises a first base station, a first sensor, and a second sensor. The first base station defines a first detection area and comprises a first transmitter and a first communication receiver. The first transmitter is configured to transmit a first detection signal. The first communication receiver is configured to receive a first communication signal and a second communication signal. The first sensor includes a first unique identifier and is movable relative to the first base station. The first sensor comprises a first detector and a first communication transmitter. The first detector is configured to detect the first detection signal. The first communication transmitter is configured to selectively transmit the first communication signal together with the first unique identifier in response to the first detection signal. The second sensor includes a second unique identifier and is movable relative to the first base station. The second sensor comprises a second detector and a second communication transmitter. The second detector is configured to detect the first detection signal. The second communication transmitter is configured to selectively transmit the second communication signal together with the second unique identifier in response to the first detection signal. The first base station is configured to facilitate variation in the operation of a device based at least in part upon at least one of the first unique identifier and the second unique identifier.
In accordance with another embodiment, a detection system comprises a first base station, a second base station, a first sensor, and a second sensor. The first base station defines a first detection area and comprises a first transmitter and a first communication receiver. The first transmitter is configured to transmit a first detection signal. The first communication receiver is configured to receive a first communication signal and a second communication signal. The second base station defines a second detection area and comprises a second transmitter and a second communication receiver. The second transmitter is configured to transmit a second detection signal. The second communication receiver is configured to receive the first communication signal and the second communication signal. The first sensor includes a first unique identifier and is movable relative to the base station. The first sensor comprises a first detector and a first communication transmitter. The first detector is configured to detect at least one of the first detection signal and the second detection signal. The first communication transmitter is configured to selectively transmit the first communication signal together with the first unique identifier in response at least one of the first detection signal and the second detection signal. The second sensor includes a second unique identifier and is movable relative to the first base station. The second sensor comprises a second detector and a second communication transmitter. The second detector is configured to detect at least one of the first detection signal and the second detection signal. The second communication transmitter is configured to selectively transmit the second communication signal together with the second unique identifier in response to at least one of the first detection signal and the second detection signal. The first base station and the second base station communicate with each other at a frequency that is within the high frequency band.
In accordance with yet another embodiment a detection system comprises a base station, a first sensor, and a second sensor. The base station defines a detection area and comprises a transmitter and a communication receiver. The transmitter is configured to transmit a detection signal. The communication receiver is configured to receive a first communication signal and a second communication signal. The first sensor includes a first unique identifier and is movable relative to the base station. The first sensor comprises a first detector and a first communication transmitter. The first detector is configured to detect the detection signal. The first communication transmitter is configured to selectively transmit the first communication signal together with the first unique identifier in response to the detection signal. The second sensor includes a second unique identifier and is movable relative to the base station. The sensor comprises a second detector and a second communication transmitter. The second detector is configured to detect the detection signal. The second communication transmitter is configured to selectively transmit the second communication signal together with the second unique identifier in response to the detection signal. The first sensor and the second sensor communicate with the base station using time domain multiplexing.
The specification concludes with claims. To assist in the understanding of those claims, the following description is provided along with the accompanying drawings in which:
Specific examples of a detection system are described in detail in connection with the illustrations in
As illustrated in
The base station 20 can include a base station controller 33 coupled with the detection signal transmitter 26 and the communication signal receiver 32. The sensor 18 can include a sensor controller 35 coupled with the detection signal detector 28 and the communication transmitter 30. The base station controller 33 and the sensor controller 35 can facilitate transmission of the respective detection signal 22 and communication signal 24 and can control certain variables such as signal duration, signal frequency, or signal modulation, for example. The base station controller 33 and the sensor controller 35 can also facilitate reception of the communication signal 24 and the detection signal 22 such as through signal processing. In one possible implementation, the base station controller 33 and the sensor controller 35 can each include a digital signal processor (not shown).
The detection signal transmitter 26, detection signal detector 28, communication signal transmitter 30, and communication signal receiver 32 can include any of a variety of suitable antennas to detect or receive the detection signal 22 and the communication signal 24. For example, the detection signal transmitter 26 and communication signal transmitter 30 can each include a radio frequency transmit coil. The detection signal detector 28 and the communication signal receiver 32 can accordingly include RF antennas. The radiation patterns of the detection signal transmitter 26 and the communication signal transmitter 30 shown in
As described in further detail below, the sensor 18 can be moved relative to the base station 20. Movement of the sensor 18 can affect detection of the detection signal 22 by the sensor 18. For example, the detection signal 22 can be attenuated as it propagates from the base station 20. If the sensor 18 is too far away from the base station 20, the detection signal detector 28 may not receive the detection signal 22 such that the sensor 18 is unable to detect the detection signal 22. In one example, attenuation of the detection signal 22 can assist in defining a detection area 34, as illustrated in
The sensor 18 can be configured to selectively transmit the communication signal 24 to the base station 20 in response to the detection signal 22. In one example, if the detection signal 22 is not detected by the sensor 18, then the sensor 18 does not transmit the communication signal 24 back to the base station 20. However, if the sensor 18 detects the detection signal 22, the sensor 18 can transmit the communication signal 24 back to the base station 20.
Referring again to
In one specific example, as illustrated in
During operation of the industrial machine 40, the base station 20 can transmit the detection signal 22 to determine whether the operator 41 is within the exclusion zone. If the operator 41 remains outside of the exclusion zone, as illustrated in
In one example, as illustrated in
In another possible configuration, the base station 20 can be attached directly to the industrial machine 40. However, in other examples, the base station 20 can rest on an adjacent floor, can be attached to an adjacent wall, can be attached to the operator's chair, or can otherwise be associated with a base station in any of a variety of suitable alternative arrangements. In one possible example construction, the sensor 18 can be attached to an operator such as through attachment to the operator's clothing. In another, the sensor 18 can be additionally or alternatively integrated into a hand-held control device for the industrial machine 40. In such an arrangement, if the hand-held control device remains outside of the detection area 34, the operator 41 is free to control the industrial machine with the control device. However, once the control device enters the detection area 34, the base station 20 can disable further control of the industrial machine 40 from the hand-held control device while simultaneously facilitating interruption of power to the industrial machine 40.
It will be appreciated that the sensor 18 and the base station 20 can be used in any of a variety of applications. In one possible application, the sensor 18 and the base station 20 can be used in a retail sales environment to provide a notification of theft of merchandise. In such an application, the base station 20 can be coupled with an alarm system, such as an audible alarm, and a sensor (for example, the sensor 18) can be associated with each piece of merchandise within the store. The base station 20 can be located at a point of entrance to or egress from the store such that the detection area 34 of the base station 20 defines a theft zone outside of the store. The base station 20 can transmit the detection signal 22 to determine whether any of the merchandise is within the defined theft zone. If a piece of merchandise incorporating a sensor enters the theft zone, the communication signal 24 can be transmitted from the sensor (for example, the sensor 18) to the base station 20 and the base station 20 can actuate the alarm.
In another possible example, the sensor 18 and the base station 20 can be used for patient monitoring at a health care facility. In this example, the base station 20 can be coupled with an alarm system, such as a visual or audible alarm, and a sensor (for example, the sensor 18) can be associated with each occupant of the health care facility. The base station 20 can be located at each point of entrance to or egress from the health care facility such that the detection area 34 of the base station 20 defines an unauthorized exit zone outside of the health care facility. The base station 20 can transmit the detection signal 22 to determine whether any occupants are within the unauthorized exit zone. If an occupant wearing a sensor enters the unauthorized exit zone, the communication signal 24 can be transmitted from the sensor to the base station 20, and the base station 20 can facilitate operation of an alarm and may close or otherwise secure nearby doors.
The base station 20 can be configured to vary the size of the detection area 34. Power of the detection signal 22 can be changed to vary the size of the detection area 34. For example, the signal power of the detection signal 22 can be reduced or increased to respectively shrink or enlarge the detection area 34. In one embodiment, the signal power of the detection signal 22 can be selectively varied to facilitate selective sizing of the detection area 34.
As illustrated in
In the example of
Varying the signal power of the detection signal 22 can be achieved in any of a variety of manners. In various examples, the voltage of the detection signal transmitter 26 can be varied to vary the signal power of the detection signal 22, the current from the detection signal transmitter 26 can be varied to vary the signal power of the detection signal 22, the base station 20 can control a duty cycle of the detection signal 22 to vary the signal power of the detection signal 22, or the base station 20 can modulate a pulse width of the detection signal 22 to vary the signal power of the detection signal 22. Additionally or alternatively, if the detection signal transmitter 26 is coupled with a capacitor in a resonant tank configuration, then the base station 20 can control a frequency of the detection signal 22 to vary the signal power of the detection signal 22.
In another example, the size of the detection area 34 can be automatically and continuously varied between a minimum size and a maximum size (for example, a continuous range sweep). By identifying the particular size of the detection area 34 that induces transmission of the communication signal 24 from the sensor 18, the distance of the sensor 18 from the base station 20 can be determined. In this example, the location and size of the detection transmitter 26 can affect the size of the detection area 34. Therefore, the size and location of the detection signal transmitter 26 may be selected during manufacture to achieve a desired detection area 34.
In another example, the sensor 18 can be configured to vary the sensitivity of the detection signal receiver 28. Varying the sensitivity of the detection signal receiver 28 can change the proximity to the detection area 34 that the sensor 18 must achieve to detect the detection signal 22 at the detection signal receiver 26.
In still another example, the detection signal 22 can include a radio frequency (RF) signal having a frequency between about 100 kHz and about 150 kHz (conventionally called “low frequency” or LF). Such an RF signal may not be as easily attenuated or reflected by nearby objects (non-conductive and conductive objects) or environmental effects (such as atmospheric moisture) as can RF signals with a higher frequency. Such an RF signal may also employ magnetic field (inductive) coupling in the near field (for example, less than a distance of wavelength divided by 2*pi, but greater than a diameter of the detection signal transmitter 26) which can provide a field strength that drops off at between about 40 dB to about 60 dB per decade, as illustrated in
In one embodiment, the communication signal 24 can comprise an RF signal having a frequency between about 300 MHz and about 3 GHz (conventionally called “ultra-high frequency” or UHF). In another embodiment, the communication signal 24 can comprise an RF signal having a frequency between about 30 MHz and about 300 MHz (conventionally called “very high frequency” or VHF). In yet another embodiment, the communication signal 24 can comprise an RF signal having a frequency between about 3 MHz and about 30 MHz (conventionally called “high frequency” or HF). In still other embodiments, the communication signal 24 can comprise an RF signal having a frequency between about 3 MHz and about 3 GHz.
Integrity of the sensor 18 and the base station 20 can be monitored in any of a variety of suitable manners. For example, the sensor 18 can be configured to test both the detection signal receiver 28 and the communication signal transmitter 30 for an open circuit or short circuit. In another example, the base station 20 can be configured to test both the detection signal transmitter 26 and the communication signal receiver 32 for an open circuit or short circuit. In another example, a unique identifier, such as a serial number, can be modulated onto the detection signal 22. If the serial number modulated onto the detection signal 22 matches the serial number of the sensor 18, the sensor 18 can respond by transmitting the communication signal 24. In another example, the sensor 18 and base station 20 can be configured to repeat transmission of the respective detection signal 22 and communication signal 24. In yet another example, encryption or rolling code algorithms can be modulated onto the detection signal 22 and the communication signal 24.
The base station transceiver 146 and the sensor transceiver 148 can facilitate bidirectional communication between the base station 120 and the sensor 118. In one embodiment, bidirectional communication between the sensor 118 and the base station 120 can facilitate execution of a synchronization routine. In such an embodiment, the base station transceiver 146 can transmit the communication signal 143 to the sensor transceiver 148 and the sensor transceiver 148 can respond to the communication signal 143 by transmitting communication signal 124 back to the base station 120. Receipt of the communication signal 124 by the base station 120 can synchronize a future transmission of the communication signal 124 that may be initiated by detection of the detection signal 122. In another embodiment, bidirectional communication between the sensor 118 and the base station 120 can facilitate execution of a configuration routine. In such an embodiment, the base station transceiver 146 can transmit a detect-initiate command to the sensor 118. If the sensor transceiver 148 responds with an acknowledgment, the base station transceiver 146 can transmit configuration commands such as address settings, baud settings, or the like. In yet another embodiment, bidirectional communication between the sensor 118 and the base station 120 can facilitate execution of a securitization routine. In such an embodiment, the base station transceiver 146 can transmit an encrypted message to the sensor 118. If the sensor transceiver 148 responds with the proper response to the encrypted message, the identity of the sensor 118 can be verified and future transmissions from the sensor 118 can be trusted.
In yet another embodiment, bidirectional communication between the sensor 118 and the base station 120 can facilitate execution of a failure safety routine. In such an embodiment, a redundant detection area can be defined by the communication signal 143 in a similar manner as described above with the detection signal 22 and the detection area 34. If the communication receiver 144 of the sensor 118 receives the communication signal 143, the sensor 118 can respond by transmitting the communication signal 124 back to the base station 120. If the primary means of detection of the sensor 118 is interrupted (e.g., due to detection signal transmitter 22 failure), the failure safety routine can be executed to ensure proper detection of the sensor 118 by the base station 120.
In one possible implementation, the sensor 118 and the base station 120 can be included within a network of other sensors and base stations. In this case, the base station transceiver 146 and sensor transceiver 148 can facilitate duplex communication between the sensor 120 and the other sensors, between the base station 120 and the other base stations, and between the sensors and the base stations.
Any of a variety of suitable detection area shapes and sizes can be defined by a base station. It will also be appreciated that a base station can be configured to achieve any of a variety of proximity control schemes. For example, as illustrated in
In another example, as illustrated in
The second detection signal can define a second detection area 339 that defines the exclusion zone. To achieve elliptical shapes for the low-power, high-power, and emergency detection areas 334, 337, 339, the first and second detection signal transmitters can comprise directional antennas. During operation of the industrial machine 340, the base station 320 can alternate transmission of the low-power detection signal, the high-power detection signal, and the second detection signal to determine whether the operator 341 is within the emergency zone, the exclusion zone, or the inclusion zone.
If the operator is within the inclusion zone, the sensor 318 transmits the communication signal (e.g., 24) to the base station 318 in response to the high-power detection signal and the industrial machine 340 is free to operate. In addition, the operator is free to control the industrial machine 340 such as with a hand-held remote. If the operator moves into the exclusion zone but outside of the emergency zone, the sensor 318 can transmit the communication signal to the base station 320 in response to the second detection signal and the base station 320 can facilitate interruption of power to the industrial machine 340 to cease operation of the industrial machine 340. If the operator moves into the emergency zone, the sensor 318 can transmit the communication signal to the base station 320 in response to the low-power detection signal and the base station 320 can facilitate interruption of power to the industrial machine 340 to cease operation of the industrial machine 340.
In another embodiment, the sensor 18 can include a unique identifier (e.g., address) that can be transmitted together with the communication signal 24 (e.g., through modulation). When a plurality of the sensors 18 is communicating with the base station 20, the base station 20 can identify each sensor according to their unique identifier. Information about each of the sensors 18 can be logged in the base station 20 by way of a pre-loaded look-up table stored in non-volatile memory, for example. The base station 20 can be configured to facilitate variation in the operation of a device based at least in part upon the location of specific sensors relative to the detection area 34. In some examples, when an identified sensor (e.g., 18) is within or is outside of the detection area 34, the base station 20 can facilitate generation of an alarm, disablement of equipment or apparatus, allowing or disallowing access to a secured location, computer screen, program, or other electronically controlled information.
As illustrated in
The base stations, 420a, 420b, 420c can communicate with each other over a wired networks, wireless networks, or hybrid wired-wireless networks, for example, to facilitate effective communication and control among the base stations 420a, 420b, 420c. For example, each of the base stations 420a, 420b, 420c can notify the other base stations of the identity of any unique sensors within its detection area. When all the base stations 420a, 420b, 420c identify the same unique sensor, than the unique sensor is within the overlapping area of the detection areas 434a, 434b, 434c. In one embodiment, the base stations 420a, 420b, 420c can use a separate master, high frequency (HF) (e.g., between about 3 MHz and about 30 MHz) transceiver device that facilitates synchronization and facilitates monitoring of the responses from the unique sensors 418a, 418b, 418c. In one embodiment, to facilitate effective communication and control, the sensors 418a, 418b, 418c can communicate with the base stations 420a, 420b, 420c using time domain multiplexing (TDM) to reduce interference. In embodiments where a plurality of multi-base station systems are used and are proximate to each other, different frequencies in the HF band can be used for each multi-base station system to reduce interference. It will be appreciated that control over the associated device can be achieved by one of the base stations (e.g., a master base station) or through cooperation of more than one of the base stations or any other suitable control arrangement.
In another example, as illustrated in
While various examples of a proximity detection system have been illustrated by the above description and have been described in detail with respect to
This application is a continuation-in-part of co-pending U.S. patent application Ser. No. 12/611,726, filed Nov. 3, 2009, which claims priority to, and the full benefit of, U.S. Provisional Patent Application Ser. Nos. 61/110,866, filed Nov. 3, 2008, and 61/255,369, filed Oct. 27, 2009. The entire disclosures of these applications are incorporated into this document by reference as if fully rewritten below.
Number | Name | Date | Kind |
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7259671 | Ganley et al. | Aug 2007 | B2 |
8102269 | Boehm et al. | Jan 2012 | B2 |
Number | Date | Country | |
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61110866 | Nov 2008 | US | |
61255369 | Oct 2009 | US |
Number | Date | Country | |
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Parent | 12611726 | Nov 2009 | US |
Child | 13628147 | US |