The various embodiments described herein relate to tracking activity. In particular, embodiments described herein relate to a mechanical watch that tracks activity, e.g., to estimate a number of steps taken, an amount of time active, or an amount of time spent sleeping.
A mechanical watch typically includes a mainspring, a gear train, a balance wheel, an escapement, and an indicating dial. The mainspring stores mechanical energy for the watch. The gear train transfers the force of the mainspring to the balance wheel and measures the passage of time based upon the movement of the balance wheel. The balance wheel oscillates back and forth, with each swing taking the same amount of time to accurately measure time. The escapement mechanism keeps the balance wheel oscillating back and forth and, with each swing, allows the gear train to advance a set amount. The indicating dial, driven by the gear train, includes hands to display the measured time.
Mechanical watches may include additional functionalities, which are often referred to as complications. Exemplary complications include a chronograph/stopwatch, automatic winding, a power reserve indicator, an alarm, a calendar, etc. For example, a self-winding watch includes an eccentric weight, which rotates about a pivot point in response to movements of the user's wrist. This rotation is translated into the winding of the mainspring, e.g., via one or more gears and a pawl and ratchet arrangement.
The present invention is illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which:
Embodiments described herein include a mechanical watch that tracks activity of a wearer of the watch. For example, embodiments of the mechanical watch estimate a number of steps taken, an amount of time active, or an amount of time spent sleeping. As a result, embodiments described herein provide the functionality of a modern activity tracker in a traditional mechanical watch.
Mainspring 305 powers the watch and includes a spiral ribbon of spring steel inside cylindrical barrel 307. Cylindrical barrel 307 is illustrated with an open face to show mainspring 305, but would typically be enclosed. In one embodiment, one end of mainspring 305 is attached to barrel 307 and the other end of mainspring 305 is attached to arbor 310 about which barrel 307 rotates. Mainspring 305 is wound by rotating arbor 310 and drives the watch movement by rotating barrel 307. As a result, mainspring 305 powers the watch even when being wound. In one embodiment, a pinion (shown in
Rotor 205 is coupled to rotor gear 315 such that rotor gear 315 rotates as rotor 205 rotates. Rotor gear 315 is engaged with a winding gear arrangement. In one embodiment, the winding gear arrangement is a bi-directional gear arrangement that translates rotation of the rotor in each of both rotational directions into a single direction of rotation of an intermediate gear to wind mainspring 305. For example, the winding gear arrangement may include two outer gears 320-325, two inner gears 330-335 within outer gears 320-325, and rotor drive gear 340. Inner gears 330-335 are ratchet gears with sloped teeth and each includes a smaller pinion gear attached to one side. The interior of each of outer gears 320-325 includes ratchet pawls to enable outer gears 320-325 to operate as a one-way clutch. The teeth of rotor gear 315 mesh with the teeth of outer gear 320. When outer gear 320 is rotated counter-clockwise by the clockwise movement of rotor gear 315, one or more ratchet pawls on the interior of outer gear 320 cause inner gear 330 to rotate as well. This counter-clockwise rotation of inner gear 330 causes, via the pinion attached to inner gear 330, rotor drive gear 340 to rotate in a clockwise direction. When rotor gear 315 rotates counter-clockwise, outer gear 320 will turn clockwise. Given the sloped teeth of inner gear 330, the clockwise rotation of outer gear 320 will not engage inner gear 330. However, the teeth of outer gear 320 mesh with the teeth of outer gear 325. The clockwise rotation of outer gear 320 rotates outer gear 325 counter-clockwise. When outer gear 325 is rotated counter-clockwise, one or more ratchet pawls on the interior of outer gear 325 cause inner gear 335 to rotate counter-clockwise as well. This rotation of inner gear 335 causes rotor drive gear 340 to rotate in a clockwise direction. As a result, rotation of rotor gear 315 in both clockwise and counter-clockwise directions results in clockwise rotation of rotor drive gear 340. Rotor drive gear 340, directly or indirectly via one or more intermediate gears (e.g., intermediate gear 345), rotates arbor 310 and winds mainspring 305.
In an alternate embodiment, the mechanical watch includes a different winding gear arrangement. For example, the watch may use pawl levers to push and pull a gear, a switching rocker, or another configuration to implement bi-direction winding or single directional winding (and corresponding rotation of rotor drive gear 340).
In one embodiment, rotor drive gear 340 drives one or more additional gears. For example, rotor drive gear 340 may cause or control rotation of activity-tracking wheel(s) coupled to indicator(s) of physical activity 120/125. As illustrated, rotor drive gear 340 is engaged with gear 350. As described with reference to the embodiments herein, gear 350 may be a part of a sliding gear assembly, vertical clutch, or other gear arrangement that enables gear 350 to be moved between engagement with rotor drive gear 340 and disengagement with rotor drive gear 340. Various embodiments of tracking activity using the output of rotor drive gear 340 are described with further reference to
Embodiments of the watch further include crown 355 coupled to winding stem 360. Crown 355 and winding stem 360 are rotatable around the axis of winding stem 360 to implement one or more functionalities dependent on a position of crown 355 as moved along the axis of winding stem 360. For example, winding stem 360 is coupled to a clutch and one or more pinions (not shown). As crown 355 and winding stem 360 are pulled away from or pushed into the watch, one or more levers engage or disengage the pinion(s) such that rotation of crown 355 and winding stem 360 functions to, e.g., wind mainspring 305 or set the time by rotating hands 105-110. In one embodiment, a position of crown 355 along the axis of winding stem 360 enables one or more activity-tracking modes. For example, as described further herein, the position of crown 355 along the axis of winding stem 360 may cause a lever to engage a gear with rotor drive gear 340, a gear with a gear within the gear train, an inactivity timer wheel with a gear within the gear train, rotate a column wheel and/or locking lever, etc. In an alternate embodiment, the mechanical watch includes a secondary stem (e.g., not used for winding mainspring 305) or button to enable one or more the activity-tracking modes described herein. In one embodiment, a mode in which the watch tracks activity is entered, exited, or otherwise triggered in response to setting or turning on/off an alarm. For example, the manipulation of a stem or button may cause the watch to both turn on an alarm and enter a sleep tracking mode. As another example, the manipulation of a stem or button may cause the mechanical watch to both turn off an alarm and exit a sleep tracking mode. As described above, in one embodiment, entering a sleep tracking mode may also result in exiting a step (or other activity) tracking mode and exiting a sleep tracking mode may also result in entering the step (or other activity) tracking mode.
For example,
In one embodiment, the ratio of gears between rotor gear 315 and activity-tracking wheel 405 is selected to correspond to a correlation between movement of rotor 205 and steps taken. For example, data may be collected by a sample pool of users wearing both an electronic activity tracker, such as an activity tracker powered by Motion X®, and a mechanical watch including a gear assembly to measure rotations of a rotor (or to measure rotations of a gear driven by rotations of a rotor). Using the data of the sample pool, a correlation is determined between steps taken as measured by the electronic activity tracker (or other accurate activity tracker) and rotations of the rotor as measured by the mechanical watch. Based upon the correlation, the gearing ratio is selected such that a number of rotations of the rotor 205 rotate an activity-tracking wheel a corresponding amount to indicate the estimate of the number of steps taken by the wearer.
In one embodiment, activity-tracking wheel 405 is reset to zero in response to manual input or automatically in response to a time of the day. For example, column wheel 415 may rotate in response to user manipulation of a button or winding stem 360 or in response to a gear within the gear train reaching a particular position. In one embodiment, column wheel 415 rotates in response to the gear/wheel coupled to hour hand 110 rotating to a position corresponding to midnight.
Upon rotation of column wheel 415, one end of engagement lever 410 travels from a gap 425 to a resting position on a vertical column 420, as illustrated in
In one embodiment, activity-tracking wheel 405 is reset by a hammer or lever pressing against a cam attached to activity-tracking wheel 405. For example, upon rotation of column wheel 415, one end of hammer 440 travels from a gap 425 to a resting position on a vertical column 420. As a result, the other end of hammer 440 is pressed against heart-shaped cam 435 attached to activity-tracking wheel 405, which returns activity-tracking wheel 405 to a position in which activity indicator 125 attached to activity-tracking wheel 405 is returned to zero. Similar to engagement lever 410, hammer 440 is urged in the direction of column wheel 415 by a spring (not shown) and the rotation of column wheel 415 moves hammer 440 in the opposite direction, about pivot point (not shown), by overcoming the force of the spring.
In one embodiment, column wheel 415 is rotated incrementally such that engagement lever 410 and hammer 440 each respectively travel from one gap 425 to another gap 425. As a result, activity-tracking wheel 405 is disengaged from rotor drive gear 340, activity-tracking wheel 405 (and activity indicator 125) is reset to zero, and activity-tracking wheel 405 is reengaged with rotor drive gear 340, all in a single motion of column wheel 415.
In an alternate embodiment, activity-tracking wheel 405 (or gear 350) is a part of a vertical clutch that enables activity-tracking wheel 405 to be moved between engagement with rotor drive gear 340 and disengagement with rotor drive gear 340. Similarly, other sliding gear arrangements described herein may be implemented by a vertical clutch.
In one embodiment, the mechanical watch tracks a cumulative amount of time the wearer of the watch is active or asleep. For example, the time may be recorded in minutes. As described further herein, the time elapsed while the wearer is active or while the wearer is asleep is recorded by engaging and disengaging a gear with the gear train. For example, similar to gear 350, one or more gears 750 may be engaged with center wheel 715, the pinion of third wheel 720, or another gear within gear train (directly or via one or more intermediate gears) utilizing a gear ratio such that gear 750 is able to drive activity indicator 120/125 at a rotational speed that corresponds to minutes/hours active/asleep. Additionally, as described further below, one or more gears within the gear train may be used to drive other functionality of activity tracking components.
In one embodiment, rotation of column wheel 815 is driven by rotor drive gear 340 such that movement of rotor 205 is translated into the initiation or resuming of tracking time during which the wearer of the watch is active. Column wheel 815 is rotated incrementally such that engagement lever 810 travels from resting on a column (as illustrated in
In one embodiment, brake lever 830 prevents active time recording wheel 805 from rotating when disengaged from the gear train. For example, brake lever 830 may be urged against active time recording wheel 805 (as illustrated in
In one embodiment, active time recording wheel 805 is reset by hammer or lever 832 pressing against cam 834 attached to active time recording wheel 805. In one embodiment, active time recording wheel 805 is reset to zero in response to manual input or automatically in response to a time of the day. For example, similar to the description of
In one embodiment, lock 835 is urged (e.g., by a spring) into a gap between columns when column wheel 815 rotates. For example, the incremental rotation of column wheel described above results in an end of lock 835 traveling from resting on a column of column wheel 815 (as illustrated in
While lock 835 prevents subsequent rotations of rotor 205 from interrupting the time recorded by active time recording wheel 805 during continued movement, the mechanical watch unlocks column wheel 815 in response to inactivity of the wearer. In one embodiment, lock 835 is released in response to a threshold amount of time passing without a threshold amount of rotation of rotor 205. For example, mechanical watch may include inactivity timer wheel 840. Inactivity timer wheel 840 is coupled to engagement arm 845 and moved between engagement and disengagement with a gear within or coupled to the gear train (e.g., fourth wheel 725) in a similar manner to the other sliding gear arrangements described herein. For example, rotation of column wheel 850 is driven by rotor drive gear 340 such that a threshold amount of movement of rotor 205 is translated into engaging or disengaging inactivity timer wheel 840 with fourth wheel 725.
Similar to the description of
In one embodiment, column wheel 850 is rotated incrementally such that engagement lever 845 and hammer 860 each respectively travel from one gap to another gap in one incremental movement of column wheel 850. As a result, inactivity timer wheel 840 is disengaged from fourth wheel 725, inactivity timer wheel 840 is reset, and inactivity timer wheel 840 is reengaged with fourth wheel 725, all in a single motion of column wheel 850 caused by rotation of rotor 205.
In one embodiment, inactivity timer wheel 840 causes the release of lock 835 from column wheel 815. For example, inactivity timer wheel 840 may include pin 865 (or another raised feature) that is capable of moving lock 835 when inactivity timer wheel 840 is rotated into a corresponding position. For example, when engaged with fourth wheel 725, inactivity timer wheel 840 rotates and pin 865 on a surface of inactivity timer wheel 840 rotates from a reset position (shown in
In one embodiment, the unlocking of column wheel 815 causes an incremental rotation of column wheel 815. For example, an end of lock 835 may include gear teeth to engage with one-way gear 870. As pin 865 lifts lock 835, the teeth of lock 835 rotate the outer portion of one-way gear 870 in a clockwise direction. One or more ratchet pawls on the interior of the outer gear of one-way gear 870 cause the inner gear of one-way gear 870 to rotate as well. The rotation of the inner gear of one-way gear 870, in turn, rotates column wheel 815. Alternatively, lock 835 shares an axle with a gear (not shown) and that engages with one-way gear 870 (or another one-way clutch) such that rotation of lock 835 results in rotation of the gear and corresponding rotation of column wheel 815. As a result, lock 835 comes to rest on a column of column wheel 815 and movements of rotor 205 may rotate column wheel 815 again. Additionally, the rotation of column wheel 815 due to inactivity causes the sliding gear assembly to disengage activity time recording wheel 805 from third wheel 720, pausing the recording of active time until rotor 205 moves again. When lock 835 returns to a position within a gap of column wheel 815, however, the corresponding counter-clockwise rotation of the outer gear of one-way gear 870 does not engage the inner gear of one-way gear 870.
In one embodiment, rotation of column wheel 1015 is driven by rotor drive gear 340 such that movement of rotor 205 is translated into pausing the of tracking time during which the wearer of the watch is asleep. Column wheel 1015 is rotated incrementally such that engagement lever 1010 travels from resting on a column (as illustrated in
In one embodiment, brake lever 1030 prevents active sleep recording wheel 1005 from rotating when disengaged from the gear train. For example, brake lever 1030 may be urged against sleep time recording wheel 1005 (as illustrated in
In one embodiment, sleep time recording wheel 1005 is reset by hammer or lever 1032 pressing against cam 1034 attached to active time recording wheel 1005. In one embodiment, active time recording wheel 1005 is reset to zero in response to manual input. For example, similar to the description above, a column wheel (not shown) may rotate in response to user manipulation of a button or winding stem 360. Alternatively, user manipulation of a button or winding stem 360 may directly move lever 1032. In one embodiment, sleep time recording wheel 1005 is reset in response to crown 355 and winding stem 360 being pulled or pushed into a sleep mode position and/or rotation of crown 355 and winding stem 360.
In one embodiment, lock 1035 is urged (e.g., by a spring) into a gap between columns when column wheel 1015 rotates. For example, the incremental rotation of column wheel 1015 described above results in an end of lock 1035 traveling from resting on a column of column wheel 815 (as illustrated in
In one embodiment, lock 1035 is released in response to a threshold amount of time passing without a threshold amount of rotation of rotor 205. For example, the mechanical watch may include inactivity timer wheel 1040. Inactivity timer wheel 1040 is coupled to engagement arm 1045 and moved between engagement and disengagement with a gear within or coupled to the gear train (e.g., fourth wheel 725) in a similar manner to the other sliding gear arrangements described herein. For example, rotation of column wheel 1050 is driven by rotor drive gear 340 such that a threshold amount of movement of rotor 205 is translated into engaging or disengaging inactivity timer wheel 1040 with fourth wheel 725.
Similar to the description of
In one embodiment, column wheel 1050 is rotated incrementally such that engagement lever 1045 and hammer 1060 each respectively travel from one gap to another gap in one incremental movement of column wheel 1050. As a result, inactivity timer wheel 1040 is disengaged from fourth wheel 725, inactivity timer wheel 1040 is reset, and inactivity timer wheel 1040 is reengaged with fourth wheel 725, all in a single motion of column wheel 1050.
In one embodiment, inactivity timer wheel 1040 causes the release of lock 1035 from column wheel 1015. For example, inactivity timer wheel 1040 may include pin 1065 (or another raised feature) that is capable of moving lock 1035 when inactivity timer wheel 1040 is rotated into a corresponding position. For example, when engaged with fourth wheel 725, inactivity timer wheel 1040 rotates and pin 1065 on a surface of inactivity timer wheel 1040 rotates from a reset position in a counter-clockwise direction. If movement of rotor 205, and the corresponding rotation of column wheel 1050, does not reset inactivity timer wheel 1040, pin 1065 collides with lock 1035 and moves lock 1035 such that the locking end of lock 1035 is removed from the gap in column wheel 1015 (as shown in
In one embodiment, the unlocking of column wheel 1015 causes an incremental rotation of column wheel 1015. For example, an end of lock 1035 may include gear teeth to engage with one-way gear 1070. As pin 1065 lifts lock 1035, the teeth of lock 1035 rotate the outer portion of one-way gear 1070 in a clockwise direction. One or more ratchet pawls on the interior of the outer gear of one-way gear 1070 cause the inner gear of one-way gear 1070 to rotate as well. The rotation of the inner gear of one-way gear 1070, in turn, rotates column wheel 1015. Alternatively, lock 1035 shares an axle with a gear (not shown) and that engages with one-way gear 1070 (or another one-way clutch) such that rotation of lock 1035 results in rotation of the gear and corresponding rotation of column wheel 1015. As a result, lock 1035 comes to rest on a column of column wheel 1015 and movements of rotor 205 may rotate column wheel 1015 again. Additionally, the rotation of column wheel 1015 due to inactivity causes the sliding gear assembly to engage sleep time recording wheel 1005 with third wheel 720, starting or resuming the recording of time asleep until rotor 205 moves again. When lock 1035 returns to a position within a gap of column wheel 1015, however, the corresponding counter-clockwise rotation of the outer gear of one-way gear 1070 does not engage the inner gear of one-way gear 1070.
At block 1205, the computing device receives or captures an image of watch face 100. For example, a user may position a mobile phone camera to capture or receive an image of watch face 100 while running a software program implementing method 1200. In response to recognizing a watch face or receiving user input, the mobile phone camera captures the image.
At block 1210, the computing device identifies one or more hands on watch face 100. For example, the computing device utilizes an object recognition program to identify indicators 120 and 125. In one embodiment, the computing device also identifies minute hand 105 and hour hand 110. For example, the computing device may use the positions of minute hand 105 and hour hand 110 and a current time tracked by the computing device to determine the orientation of watch face 100. Alternatively, the computing device uses the relative positions of pivot points of indicators 120 and 125 within watch face 100 to determine the orientation of watch face 100. In one embodiment, the computing device also identifies demarcations of time 115 and/or demarcations of activity around indicators 120 and 125.
At block 1215, the computing device reads the position of the hands/indicators. For example, based upon a determined orientation of watch face 100 (using the relative positions of pivot points of indicators 120 and 125 within watch face 100) or based upon the recognition of the demarcations of activity around indicators 120 and 125, the computing device determines a value associated with the position of indicator 120 and/or indicator 125 in the image of watch face 100. In one embodiment, the computing device determines the top of the sub-dial(s) associated with indicator 120 and/or indicator 125 (e.g., the position normally associated with twelve o'clock on a watch or clock). Using the example above of a range of zero to ten thousand steps, indicator 125 may point to zero steps at a position normally associated with twelve o'clock, to 2,500 steps at a position normally associated with three o'clock, to 5,000 steps at a position normally associated with six o'clock, to 7,500 steps at a position normally associated with nine o'clock, and corresponding values in between. The computing device determines the relative position of indicator 120 and/or indicator 125 within the respective sub-dial(s) and maps that position to a corresponding value. For example, in
In one embodiment, the computing device utilizes a previous reading of indicator 120 and/or indicator 125 in the determining of the current reading of indicator 120 and/or indicator 125. For example, if the user is very active and takes more than 10,000 steps, indicator 125 may make more than a complete rotation of the corresponding sub-dial. If the computing device determines a previous reading of indicator 125 (within a threshold period of time, e.g., the same day) to be further along in clockwise rotation than the current reading, the computing device determines that indicator 125 has made a complete rotation. For example, if the computing device read indicator 125 a couple of hours earlier in the day as indicating the wearer of the watch had taken 7,500 steps and a current image of watch face 100 corresponds to the illustration of
At block 1220, the computing device stores the reading of indicator 120 and/or indicator 125 in memory. For example, previous readings may be used as described above. Additionally, the computing device may evaluate and/or compile readings to create reports and feedback for the user.
At block 1225, the computing device presents tracked steps, active time, or sleep time to the user based upon the stored readings. For example, the computing device may compare daily readings against readings history, goals, recommended values, etc. to generate reports, recommendations, etc.
Data processing system 1300 includes memory 1310, which is coupled to microprocessor(s) 1305. Memory 1310 may be used for storing data, metadata, and programs for execution by the microprocessor(s) 1305. Memory 1310 may include one or more of volatile and non-volatile memories, such as Random Access Memory (“RAM”), Read Only Memory (“ROM”), a solid state disk (“SSD”), Flash, Phase Change Memory (“PCM”), or other types of data storage. Memory 1310 may be internal or distributed memory.
Data processing system 1300 includes network and port interfaces 1315, such as a port, connector for a dock, or a connector for a USB interface, FireWire, Thunderbolt, Ethernet, Fibre Channel, etc. to connect the system 1300 with another device, external component, or a network. Exemplary network and port interfaces 1315 also include wireless transceivers, such as an IS 802.11 transceiver, an infrared transceiver, a Bluetooth transceiver, a wireless cellular telephony transceiver (e.g., 2G, 3G, 4G, etc.), or another wireless protocol to connect data processing system 1300 with another device, external component, or a network and receive stored instructions, data, tokens, etc.
Data processing system 1300 also includes display controller and display device 1320 and one or more input or output (“I/O”) devices and sensors 1325. For example, data processing system 1300 may include one or more touch inputs; buttons; one or more inertial sensors, accelerometers, gyroscopes, or a combination thereof; geolocation positioning systems; vibration motors or other haptic feedback devices; etc. In one embodiment, data processing system 1300 includes one or more sensors to track body temperature, heart rate, blood pressure, blood oxygen levels, electrical activity of the heart (electrocardiography), electrical activity of a skeletal muscle (electromyography), acoustic activity (e.g., breathing patterns), skin conductivity (galvanic skin response), and/or another non-invasively tracked biosignal.
Display controller and display device 1320 provides a visual user interface for the user. I/O devices 1325 allow a user to provide input to, receive output from, and otherwise transfer data to and from the system. I/O devices 1325 may include a mouse, keypad or a keyboard, a touch panel or a multi-touch input panel, camera, optical scanner, audio input/output (e.g., microphone and/or a speaker), other known I/O devices or a combination of such I/O devices.
It will be appreciated that one or more buses, may be used to interconnect the various components shown in
Data processing system 1300 may be a personal computer, tablet-style device, a personal digital assistant (PDA), a cellular telephone with PDA-like functionality, a Wi-Fi based telephone, a handheld computer which includes a cellular telephone, a media player, an entertainment system, a fitness tracker, or devices which combine aspects or functions of these devices, such as a media player combined with a PDA and a cellular telephone in one device. As used herein, the terms computer, device, system, processing system, processing device, and “apparatus comprising a processing device” may be used interchangeably with data processing system 1300 and include the above-listed exemplary embodiments.
It will be appreciated that additional components, not shown, may also be part of data processing system 1300, and, in certain embodiments, fewer components than that shown in
An article of manufacture may be used to store program code providing at least some of the functionality of the embodiments described above. Additionally, an article of manufacture may be used to store program code created using at least some of the functionality of the embodiments described above. An article of manufacture that stores program code may be embodied as, but is not limited to, one or more memories (e.g., one or more flash memories, random access memories—static, dynamic, or other), optical disks, CD-ROMs, DVD-ROMs, EPROMs, EEPROMs, magnetic or optical cards or other type of non-transitory machine-readable media suitable for storing electronic instructions. Additionally, embodiments of the invention may be implemented in, but not limited to, hardware or firmware utilizing an FPGA, ASIC, a processor, a computer, or a computer system including a network. Modules and components of hardware or software implementations can be divided or combined without significantly altering embodiments of the invention.
In the foregoing specification, the invention has been described with reference to specific exemplary embodiments thereof. Various embodiments and aspects of the invention(s) are described with reference to details discussed herein, and the accompanying drawings illustrate the various embodiments. The description above and drawings are illustrative of the invention and are not to be construed as limiting the invention. References in the specification to “one embodiment,” “an embodiment,” “an exemplary embodiment,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but not every embodiment may necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Furthermore, when a particular feature, structure, or characteristic is described in connection with an embodiment, such feature, structure, or characteristic may be implemented in connection with other embodiments whether or not explicitly described. Additionally, as used herein, the term “exemplary” refers to embodiments that serve as simply an example or illustration. The use of exemplary should not be construed as an indication of preferred examples. Blocks with dashed borders (e.g., large dashes, small dashes, dot-dash, dots) are used herein to illustrate optional operations that add additional features to embodiments of the invention. However, such notation should not be taken to mean that these are the only options or optional operations, and/or that blocks with solid borders are not optional in certain embodiments of the invention. Numerous specific details are described to provide a thorough understanding of various embodiments of the present invention. However, in certain instances, well-known or conventional details are not described in order to provide a concise discussion of embodiments of the present inventions.
It will be evident that various modifications may be made thereto without departing from the broader spirit and scope of the invention as set forth in the following claims. For example, the methods described herein may be performed with fewer or more features/blocks or the features/blocks may be performed in differing orders. Additionally, the methods described herein may be repeated or performed in parallel with one another or in parallel with different instances of the same or similar methods.
Number | Name | Date | Kind |
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2082843 | Mathez | Jun 1937 | A |
3541781 | Bloom | Nov 1970 | A |
4322609 | Kato | Mar 1982 | A |
7862226 | Bracher | Jan 2011 | B2 |
20150085622 | Carreel | Mar 2015 | A1 |
20150289802 | Thomas | Oct 2015 | A1 |
Number | Date | Country |
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377738 | Jan 1964 | CH |
668349 | Dec 1988 | CH |
697528 | Nov 2008 | CH |
Entry |
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