Patent Publication Number: US-9907150-B2

Title: Low power battery mode for wireless-enabled device prior to commissioning

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a continuation of U.S. patent application Ser. No. 15/215,038, filed on Jul. 20, 2016, the entire disclosure of which is incorporated herein by reference. 
    
    
     TECHNICAL FIELD 
     The disclosed subject matter relates to a battery powered control device, for example, for wirelessly controlling a luminaire or the like. More specifically, the control device conserves battery power by entering and/or remaining in a low power mode before a wake-up operation activates the device to allow for commissioning. 
     BACKGROUND 
     Recently, battery powered devices (e.g. switches, sensors, etc.) have been developed to control luminaires, for example, using wireless communications with the controlled devices. In order to conserve battery life between manufacturing of the control device and installation of the control device, conventional solutions have physically disconnected the battery from the electronics of the control device, typically, in one of two configurations. 
     In a first configuration, a non-conductive pull-tab is inserted (during manufacturing) between the batteries and one or more of the power terminals of the device itself. In order to install these types of control devices and enable normal operation, the installer has to physically pull the tab out for the device to become powered for the first time. 
     In a second configuration, batteries are simply not included in the device during the manufacturing process. In order to install these types of control devices, the installer has to physically insert batteries into the device for the device to become powered for the first time. 
     SUMMARY 
     There is room for improvement over the typical configurations outlined above. 
     Additional objects, advantages and novel features of the examples will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following and the accompanying drawings or may be learned by production or operation of the examples. The objects and advantages of the present subject matter may be realized and attained by means of the methodologies, instrumentalities and combinations particularly pointed out in the appended claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The drawing figures depict one or more implementations in accord with the present concepts, by way of example only, not by way of limitations. In the figures, like reference numerals refer to the same or similar elements. 
         FIG. 1  is a high-level functional block diagram of a system of one or more communication networks between luminaires, battery powered lighting control devices, and other network enabled devices for use in or communication with a lighting control system. 
         FIG. 2  is a flow chart/state diagram that may be helpful in explaining operation of a battery powered wireless lighting control device, such as a wall switch or a standalone sensor, in a system like that in  FIG. 1 . 
         FIG. 3  shows a block diagram of the internal components of an example of a luminaire as may be used in the system in  FIG. 1 . 
         FIG. 4  shows a block diagram of the internal components of an example of a battery powered wall switch. 
         FIG. 5  shows a block diagram of the internal components of a battery powered sensor. 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description, numerous specific details are set forth by way of examples in order to provide a thorough understanding of the relevant teachings. However, it should be apparent to those skilled in the art that the present teachings may be practiced without such details. In other instances, well known methods, procedures, components, and/or circuitry have been described at a relatively high-level, without detail, in order to avoid unnecessarily obscuring aspects of the present teachings. 
     The various examples disclosed herein relate to battery powered lighting control devices, such as a wireless wall switch or a wireless sensor (e.g. for occupancy sensing). The examples conserve battery power and extend battery life by entering or remaining in a very low power mode before commission. While in that mode, a lighting control device example is awakened only by detection of a predetermined stimulus, such as a button press for a wall switch or detection of some motion by an occupancy sensor. 
     The first prior configuration outlined in the background, using the non-conductive pull tab to conserve battery power before installation, is potentially error prone because it allows the tab to be prematurely pulled out therefore wasting precious battery life. If there is a problem pulling out the tab, e.g. due to tearing, the tab pull may leave a non-conductive remnant between contacts and thereby prevent battery connection after the pull. This type error may prevent activation of the control device, which in turn causes difficulties/added expense if the control device fails to operate at or following installation. The non-conductive pull tab configuration also is expensive as the cost to make and install the tab adds to the overall cost of the control device. 
     The prior technique relying on battery insertion at installation to conserving battery power is labor intensive due to the installer having to manually install batteries in every device during installation. Errors may also arise if the installer does not insert the batteries in the correct orientation or damages one or more of the connection terminals of the control device during the battery installation process. 
     Also, the typical techniques disconnect the battery only until the time of installation at a premises where the control device will operate. Once installed, the electronics may consume power. The lighting system as a whole, with active ability of a wall switch or sensor to control other devices (e.g. luminaires), may not be operational for some further period, for example, until luminaires are installed and the luminaires and the control device are commissioned to communicate and work together. In such a scenario, the control device electronics have unnecessarily consumed power during the time between installation and commissioning. 
     Examples are discussed below that improve on techniques to conserve battery power of a wireless lighting control device, for example, before installation and/or before commissioning, in a manner to alleviate one or more of the deficiencies outlined above. To save battery life, a wireless battery operated control device remains in a low power mode and is awakened for commissioning, for example by a button press (e.g. for a wall switch) or motion or audio sensing (e.g. for an occupancy sensor or the like). When awakened, the control device enters its commissioning mode with the radio transceiver active, e.g. for a short period of time. If the lighting control device is not commissioned within that time interval, it may reenter the sleep mode. Conversely, if successfully commissioned during the active time period, the lighting control device is ready for normal operations. 
     With the temporary activation, based on a button press or condition sensing, batteries can be installed and fully connected during manufacture. There is no need to install batteries in the control device at the installation site and no battery tabs to remember to pull or to pull without damaging before installation and operation. The button press or condition sensing approach may also allow an installer to stimulate the lighting control device and see some pilot light activity to confirm that the control device is functional, yet the lighting control device can reenter its sleep mode and conserve power until someone else commissions the device, possibly at a much later time. 
     As outlined above, the lighting control device with the battery power conservation feature may be used to control operation of luminaires. Luminaires (e.g. light fixtures, floor or table lamps, or other types of lighting devices for artificial illumination) are widely used in various residential, commercial and industrial settings for providing illumination in both interior and exterior spaces. For example, a retail store may install multiple luminaires in the ceiling for illuminating products and walking area throughout store. The luminaires discussed in the examples may be installed or otherwise located in our about a particular premises. Although the premises may be a single property and associated building structure, the term premises is used in the examples to also encompass installations and/or operations of the luminaires at more than a single site or building, such as campus. 
     The term “luminaire” as used herein is intended to encompass essentially any type of device that processes power to generate light, for example, for illumination of a space intended for use of or occupancy or observation, typically by a living organism that can take advantage of or be affected in some desired manner by the light emitted from the device. However, a luminaire may provide light for use by automated equipment, such as sensors/monitors, robots, etc. that may occupy or observe the illuminated space, instead of or in addition light for an organism. A luminaire, for example, may take the form of a table lamp, ceiling light fixture or other lighting device that incorporates a source, where the source by itself contains no intelligence or communication capability (e.g. LEDs or the like, or lamp (“regular light bulbs”) of any suitable type). Alternatively, a lighting device or luminaire may be relatively dumb but include a source device (e.g. a “light bulb”) that incorporates the intelligence and communication capabilities described herein. In most examples, the luminaire(s) illuminate a service area to a level useful for a human in or passing through the space, e.g. regular illumination of a room or corridor in a building or of an outdoor space such as a street, sidewalk, parking lot or performance premises served by a lighting system may have other lighting purposes, such as signage for an entrance or to indicate an exit. Of course, the luminaires may be configured for still other purposes, e.g. to benefit human or non-human organisms or to repel or even impair certain organisms or individuals. 
     The lighting control devices implementing the battery conservation feature examples as described herein may be battery powered wireless wall switches, battery powered wireless occupancy sensors, battery powered wireless sensors configured to detect other lighting related conditions (e.g. ambient light characteristics) or other types of control devices configured to wirelessly communicate with lighting system elements about events or the like as may impact control of system luminaires. As outlined above, each luminaire includes a light source. The light source may be any type of light emitting unit, including but not limited to light emitting diodes (LEDs), incandescent or fluorescent lamps, halogen or halide lamps, neon tubes, etc. In the examples described herein, the luminaires also have smart capabilities. For example, the luminaires include a processor as well as radio frequency (RF) transceivers to perform wireless communications with other luminaires and other wireless devices (e.g. Wall Switches, Sensors, Smartphones, Access Points, etc.). To work with and control such luminaires in a controlled lighting system, a wall switch or sensor type lighting control device typically includes a compatible RF transceiver. The lighting control device may also include a processor, memory and firmware or other programming to configure the lighting control device to operate as outlined herein. 
     The term “coupled” as used herein refers to any logical, physical or electrical connection, link or the like by which signals produced by one system element are imparted to another “coupled” element. Unless described otherwise, coupled elements or devices are not necessarily directly connected to one another and may be separated by intermediate components, elements or communication media that may modify, manipulate or carry the signals. 
     Reference now is made in detail to the examples illustrated in the accompanying drawings and discussed below. To appreciate the pre-commissioning battery saver feature, in context, it may be helpful to first consider an example of a lighting control system using wireless communications, in which some of the wireless enabled lighting control devices use battery power.  FIG. 1  illustrates examples of some elements of a wirelessly controlled lighting system  1  as well as examples of some other network enabled devices for use in or for communication with the lighting control system  1 . 
     The lighting system  1  example of  FIG. 1  includes one or more luminaires  10 A to  10 N installed in a premises location (e.g. residential/commercial setting). In this example, each of the luminaires  10  includes a light source as well as a lighting control device, where the lighting control device is represented by a sensor and control module in the examples of luminaires  10 A and  10 N or by a control module (without its own sensor) in the example of luminaire  10 B. The lighting control device for a luminaire may be incorporated within the respective luminaire as shown, or such a device may be implemented separately and coupled to control the respective luminaire. Although shown as one such control device/module for each luminaire, any one of these lighting control devices/modules may be coupled to two or more luminaires (e.g. if the control device is implemented as a power pack or plug load controller). Such lighting control devices in or associated with luminaire  10  are configured to communicate with each other and/or with other lighting control devices represented in the drawing by wall switch  20  and standalone sensor  21 . 
     The concepts discussed herein are applicable to devices of a lighting system  1  that utilizes a single communication channel or band, for example, in which the lighting control devices have transceivers configured to operate over a single channel or band. The concepts, however, are applicable to systems and devices that utilize a larger number of channels, possibly in two or more RF bands. Hence, in the example of  FIG. 1 , luminaires  10 , wall switch  20 , sensor  21  and any other lighting control devices (such as plug load controllers and power packs) communicate control related messages over a control band forming a logical wireless control network  5 . In specific examples discussed in more detail later, the wireless control network  5  uses a 900 MHz (sub-GHz) frequency band. In such a multi-band example, the system also uses one or more different channels or bands to form a logical wireless commissioning network  7 . In specific examples discussed in more detail later, the wireless commissioning network  7  uses a 2.4 GHz, such as the band assigned for BlueTooth Low Energy (BLE). In such an implementation, a variety of control messages are transmitted over the band of the wireless control network  5 , including, for example, messages to turn lights on/off and possibly to dim lights up/down, set scene (e.g., a predetermined light setting), and to indicate sensor trip events. The other band, used for the commissioning network  7  in the example, carries various messages related to commissioning and maintenance of the wireless lighting system  1 ; however no control messages pass over this commissioning network. Logically, the communications over the control band and the commissioning band may be thought of/referred to as a wireless control network  5  and a wireless commissioning network  7 . 
     When the system  1  is fully operational, each lighting control device  10 ,  20 ,  21  wirelessly sends and/or receives lighting control related messages over the wireless control network  5 . Before such normal operations, however, each lighting control device  10 ,  20 ,  21  is commissioned to operate as an element of the system  1  via communications over the wireless commissioning network  7 . In the example shown, the system  1  is provisioned with a mobile device  25  that includes a commissioning/maintenance application  22  for commissioning and maintenance functions of the lighting control system  1 . For example, the mobile device  25  enables mobile commissioning, configuration, and maintenance functions. The mobile device  25  may be a tablet, PDA or smartphone type of device with human interfacing mechanisms sufficient to perform clear and uncluttered user directed operations. The mobile device  25  runs mobile type applications, including the commissioning/maintenance application  22  on iOS7, Android KitKat, Windows 10 operating system or the like. Execution of the commissioning/maintenance application  22  on the mobile device  25  supports commissioning of devices for operation as elements of the lighting system  1 . 
     In addition to luminaires  10 A to  10 N, wall switch  20  and sensor  21 , a gateway  50  may also be in communication with wireless control network  15  and/or the commissioning network  7 . If provided, such a gateway  50  allows a luminaire, any standalone sensors and wall switch(es) to communicate with external devices such as server  65  and personal computer or other user terminal device  60  via a wide area network (WAN)  55 . This configuration could essentially allow a server  65  or terminal device  60  to commission, monitor and/or control the luminaires, sensor(s) and wall switch(es)  106  at the premises. 
     Web enabled (cloud) services for facilitating commissioning and maintenance activities also may be provided via the mobile device  25 . The commissioning/maintenance application  22  of the mobile commissioning device  25  interfaces with the cloud services via the gateway  50  and the WAN  55  to acquire installation and configuration information for upload to luminaires  10 , wall switches  20 , sensors  21 , etc. The installation and configuration information is received by mobile device  25  from the gateway  55 . 
     After the installer (e.g. electrician) initially installs luminaires  10 , sensor  21  and wall switch  20 , the luminaires  10  are powered from the AC mains at the premises. Battery powered control devices such as the sensor  21  and the wall switch  20 , however, remain for long periods in the deep sleep mode awaiting activation for commissioning. The same or a different technician initiates a pairing and commissioning process to configure the system to support wireless communications for normal lighting control, e.g. between the lighting control devices  20 ,  21  and the luminaires  10 . The pairing and commissioning process, for example, may involve an individual Bluetooth pairing of a mobile device  25  (e.g. a tablet or smartphone) with each system element  10 ,  20 ,  21  to enable communications related to commissioning. For battery powered wireless lighting control devices, such as the sensor  21  and the wall switch  20 , this involves input of a predetermined stimulus to wake each such device from its deep sleep mode for pairing with the mobile commissioning device  25  in the example. 
     At a high level, the commissioning of the elements  10 ,  20 ,  21  during respective paired communications essentially enables the technician to configure each of the various elements so as to create a relationship between the battery powered wireless lighting control devices  20 ,  21  and the luminaires  10  that allows for wireless control of the luminaires  10  after successful commissioning. For example, once the commissioning process is properly complete, sensor  21  or wall switch  20  will be able to control (e.g. turn ON/OFF) some number N luminaires  10  ( 10 A- 10 N in the drawing) automatically, by sensing occupancy or by detecting a user request via button operation. 
     In a more specific example, for a system encompassing a number of rooms or other areas of a premises, groups of system elements are formed during commissioning of the lighting control system. All members of a group are logically connected together over the control band of the wireless control network, which in our example is a sub-GHz control network. A group may be defined by an assigned RF channel and a lighting control group identifier. In such an implementation, the luminaires and control devices of the group subscribe to group communication “channels” defined by assigned RF channel and assigned group ID. Effectively, the system elements in the group only listen for/react to messages on the RF channel with the identifier (ID) of the subscribed group channel that designate the lighting control group of which each control device in a luminaire  10  or other wireless lighting control device  20  or  21  is a member. A group can be further divided to address control to specific control zones within the group defined by a control zone identifier. Zone communications are managed as addressable features at run time. 
     Each lighting control group will have a group monitor or manger. Typically, one of the luminaires is commissioned as the group monitor, and one or more of the other luminaires are commissioned to take over the group monitor functions in the event of failure of a designated group monitor. The configuration of luminaires as group monitor and backup(s) is part of the process for commissioning the luminaires  10 A to  10 N in the group. 
     Due to limited available full-power operation times due to battery power limitations, lighting control devices such as wall switch  20  and sensor  21 , are not commissioned to act as the group monitor in the example. The lighting control devices  20 ,  21 , however, are commissioned to communicate with the active group monitor as well as other luminaires in the particular group. Further discussions will concentrate on control device wake-up and commissioning, e.g. for such group control operations. 
     The wireless control network  5  distributes control messages and events, network management messages and events, health and failover events; and the commissioning network  7  distributes messages about commissioning and maintenance communications, such as firmware update distributions and group membership changes. Of note for purposes of further discussion of installation and commissioning, the commissioning process configures the group members to listen to/use the RF channel and ID of the group, configures luminaires as the group manager and possible backup(s) and configures other group members to communicate with the group monitor. Since the luminaires draw power from AC mains, the transceivers and control electronics can be adequately powered at all times before, during and after commissioning. Battery powered devices, however, operate in one or more low power modes at different times to conserve battery power. In particular, battery powered wireless lighting control devices, such as sensor  21  and wall switch  20 , frequently operate in or remain in a deep sleep mode (minimal power consumption state) until awakened for commissioning. 
     For example, if the battery powered wireless lighting control device is a wall switch  20  that includes a button, a user press of the button generates the trigger signal that stimulates the processor to wake up the wall switch  20  from the deep sleep mode. Once commissioned, the processor responds to user activation of the button to control the luminaire(s)  10  in the assigned group to turn ON/OFF. If the control device is an occupancy sensor  21 , the device includes an appropriate detector, which in this example, is configured to detect motion. In that case, the processor of device is configured to wake up the occupancy sensor from the deep sleep mode upon suitable motion detection, and once commissioned, to control the luminaire(s)  10  in the assigned group to turn ON based on further detected motion. Luminaires may turn OFF if there is no indication of occupancy from such a sensor for some set period of time. 
     In the examples, the battery powered wireless lighting control device may be configured for surface mounting on or recessed mounting in a wall or other architectural panel of a premises to be illuminated by the lighting system. A wall switch  20  often is mounted to a wall, for convenient user access. An occupancy sensor  21  or the like may be similarly wall mounted but often is mounted on a ceiling or the like. 
     Batteries may be installed and fully connected to the electronics of the lighting control device  20  or  21  as part of the manufacturing process. The processor is configured to keep the device in the deep sleep mode from manufacturing of the battery powered wireless lighting control device, for example, until activated in expectation of commissioning. 
     The processor may transition the device  20  or  21  back to the deep sleep mode, for example, in the event a wake-up fails to result in a successful commissioning of the device. In a more specific example, the processor transitions the device  20  or  21  back to the deep sleep mode at a predetermined time interval after wake-up in event of no commissioning of the device before expiration of the predetermined time interval. 
     In operation examples, upon awakening from the deep sleep mode, the processor and the RF transceiver consume battery power necessary to complete the commissioning of the device. Upon successful commissioning of the device, however, the device including the processor and the RF transceiver, enters a normal lighting control mode awaiting a lighting related input via the detector or the button. In the example, the lighting control device enters its normal operating state for wireless lighting control functions once commissioned; although in that normal operation mode, the device uses various power states to perform the necessary actions yet preserve battery life. One power state within normal operations will be a full ON mode in which all elements/functions of the lighting control device are powered and actively available. One other state that may be entered at various times of normal (post commissioned) operations may be a somewhat low power state awaiting a button press or condition sensing, in response to which the device will power up the appropriate transceiver for control signal transmissions. The normal operation low power state, however, may or may not be as low in power consumption as the deep sleep mode before commissioning. 
     It may be helpful to consider the states and process of such a lighting control device in somewhat more detail, with reference to the diagram of  FIG. 2 . 
     In step  100 , the wall switch  20  and/or sensor  21  is initially operating in a deep sleep mode, for example, consuming current less than or equal to 5 micro-amperes. In some examples, the battery powered lighting control device may consume less than 1 micro-amps of current. This deep sleep mode is set during manufacturing of the switch and/or sensor. In order to be awoken from this deep sleep mode, a stimulus must be input to the respective device. The wall switch  20 , for example, therefore may only consume power if any needed only to detect activation of the push button. The sensor, for example, may only consume sufficient power to operate a timer to infrequently wake up enough of the device functions to operate the detector to sense for motion detection in the vicinity of the lighting control device. Stimulus for wake-up, for example, may involve detection of a button press, detection of an audio condition or pattern, detection of motion, detection of a specific motion profile (e.g. gesture or the like). 
     By way of somewhat more detailed examples, a button on a wall switch  20  must be pressed or pressed and held for a predetermined time period; or a sensor  21  must detect some type of motion in its vicinity to be awoken from deep sleep. This type of stimulus will wake the wall switch  20  or the sensor  21  respectively from the deep sleep mode such that the respective device can transmit an active beacon in step  102  (i.e. the processor of the lighting control device applies power to the BlueTooth RF transceiver of the lighting control device). This active beacon is a wireless transmission of an advertising packet or the like to indicate to other Bluetooth enabled devices in the vicinity that the wall switch  20  or sensor  21  is attempting to essentially connect (i.e., pair itself) with another device. Although referred to in the singular as a beacon, it should be understood that the advertising packet or other signal transmission for this purpose may be transmitted a number of times (e.g. around 5 to 10 times per second) for some period while the transceiver is in the mode looking for a device with which to pair, for commissioning purposes at this point in our example. Luminaires and other wall switches  20  and/or sensor  21  will not respond to the pairing request/advertisement, however, a Bluetooth enabled mobile device  25  of a technician seeking to commission the wall switch  20  and/or sensor  21  may respond. 
     The wall switch  20  or the sensor  21  (after transmitting the active beacon) determines in step  104  if it has been paired with a commissioning device  25 . If it is paired successfully, then processor of the lighting control device  20  or  21  completes a commissioning process in step  106  by exchanging information (identity information, etc.) with the commissioning device  25 . Although not shown in the flow diagram for the control device states in  FIG. 2 , each luminaire will go through its own pairing and commissioning procedure. After the commissioning process takes place for all elements of the particular zone or group, the wall switch  20  and/or the sensor  21  is now configured to control the luminaires  10 A to  10 N in the group. 
     Once commissioned, the wall switch  20  and/or the sensor  21  enters a normal sleep mode in step  108  and awaits an input stimulus before it awakes and performs its normal lighting control functions in step  110 . For example, after the commissioning process, the wall switch  20  may wake up due to one of the buttons being pressed in order to turn ON/OFF or other operations (e.g. dimming, scene selection, programming, etc.) of the luminaires  10 A to  10 N of the particular group. Similarly, the sensor  21 , upon detecting motion via the infrared detector or the like, may transmit a control signal to turn ON/OFF luminaires  10 A to  10 N of the particular group. It should also be noted that each commissioned battery powered lighting control device  20  or  21  may wake up periodically, for example, to check for changes such as firmware updates or other messages held for the control device by the group monitor. The normal sleep mode may consume somewhat more power than the deep sleep mode implemented prior to commissioning, particularly when considered over an interval of time that may involve more frequent wake-ups for check-in, in comparison to the deep sleep mode before commissioning. 
     To fully appreciate the present concepts, it may be useful to discuss examples of the luminaires, wall switches and sensors in somewhat more detail. 
     An example of a luminaire  10 B is shown in  FIG. 3  where the luminaire  10 B includes a light source  210 , a micro-controller unit (MCU)  204  that has an internal processor configured as a central processing unit (CPU)  214 , a memory  216  and a non-volatile memory  218 . The processor and associated memory in the example  10 B of the luminaire are components of the MCU, which is a microchip device that incorporates the CPU as well as one or more memories. The MCU may be thought of as a small computer or computer like device formed on a single chip. Alternatively, the processor and memory may be implemented as separate components, e.g. by a microprocessor, ROM, RAM, flash memory, etc. 
     Also included in the example  10 B of the luminaire is a power distribution unit  202  receiving power from an external alternating current (AC) power source  212 . A driver for the light source may be provided, e.g. to convert mains power to suitable voltage and current levels for the particular type of source, although the driver is omitted from  FIG. 3  for convenience. 
     This example of the luminaire  10 B includes the capabilities to communicate over two different radio frequency (RF) bands, although the concepts discussed herein are applicable to control devices that communicate with luminaires and other system elements via a single RF band. Hence, in the example, the luminaire  10 B includes a 900 MHz transceiver  206  for sending/receiving control signals, as well as a 2.4 GHz transceiver  208  (e.g. BlueTooth Low Energy (BLE)) for sending/receiving pairing and commissioning messages. In such an implementation a variety of controls are transmitted over the 900 MHz control band of the wireless control network  5 , including, for example, turn lights on/off, dim up/down, set scene (e.g., a predetermined light setting), and sensor trip events. The other band, 2.4 GHz for BLE in the example, carries various messages related to commissioning and maintenance of the wireless lighting system, however no controls pass over this commissioning network  7 . 
     Although the two RF transceivers and the MCU are shown separately, the elements of the luminaire may be implemented in a more integrated manner, e.g. with the RF transceivers integrated into the MCU  204 , with one RF transceiver for multiple bands, with the MCU implemented as an integral component of one or the other of the RF transceivers, etc. 
     In the example of  FIG. 3 , luminaire  10 B is shown as having one processor  214 , for convenience. In some instances, such a lighting device may have multiple processors. For example, a particular device configuration may utilize a multi-core processor architecture. Also, some of the other components, such as the communications interfaces, may themselves include processors. 
     The lighting control device or module of the luminaire  10 B includes the MCU  204  (with the processor and memory) as well as the wireless transceiver(s). If the module also operated as a sensor, such a lighting control device would also include a detector and associated circuitry to operate the particular detector and interface the detector to the MCU  204 . 
     In general, the MCU  204  of the lighting control device in the luminaire  10 B controls the various components of the luminaire. For example, MCU  204  controls RF transceivers  206  and  208  to communicate with other RF devices (e.g. wall switches, sensors, commissioning device, etc.). In addition, the MCU  204  controls the light source  210  to turn ON/OFF automatically, or at the request of a user. In addition, MCU  204  controls other aspects of operation of the light source  210 , such as light output intensity level, associated color characteristic(s) of the light output, focus and/or beam steering of the light output, etc. 
     In order to perform the pairing and commissioning process and communicate with the luminaires  10 A to  10 N, examples of the wall switch  20  and sensor  21  for operation in the system  1  example of  FIG. 1  also have wireless transmission/reception capabilities as well as a processor (e.g. in an MCU) or other control electronics. For example, as shown in the example of  FIG. 4 , a wall switch  20  includes a power distribution unit  312 , MCU  204 , and wireless transceivers  206  and  208 , which are all somewhat similar to the various components shown in the luminaire of  FIG. 3 . 
     In addition, however, wall switch  20  includes an internal battery  302  that powers the electronics of the wall switch  20 . Battery  302  is generally installed in wall switch  20  during manufacturing. Battery  302  may be any type of battery including an alkaline battery, nickel cadmium battery, lithium ion battery, etc. In addition to battery  302 , wall switch  20  may also include at least one button  304  (e.g. push button, rocker switch, etc.) that allows a user to interact with the wall switch. Responses to actuation of the button  304  are supported by drive/sense circuitry  306  which interfaces button  304  to the MCU  204 . 
     Optionally, the wall switch  20  may also include light emitting diodes (LEDs)  310  as well as LED driver circuitry  308  to support the LEDs. These LEDs may be used as pilot lights to allow wall switch  20  to output visual indicators to the user of the wall switch  20 . For example, in a lighting control operational mode, a LED may be activated for a short time in response to a button press by a user. Before commissioning, activation of a LED in response to a button press shows an installer or other technician that the wall switch has power, is operational and/or is ready for commissioning. 
     Sensor  21  shown in block diagram in  FIG. 5  may be an occupancy sensor using a motion detector, that includes at least one of an infrared (IR) detector, an ultrasonic detector, or a microwave detector, an image detector, or the like. Although the system  1  may use similar sensor implementations for detection of other control responsive functions, e.g. detection of ambient light intensity or color characteristics, for purposes of further discussion of an example of the sensor  21 , the description concentrates on a sensor  21  configured to detect motion. 
     The internal components of the sensor example are shown in  FIG. 5  where sensor  21  includes several components similar to those of the wall switch  20 . The similar components include a power distribution unit  312 , MCU  204 , wireless transceivers  206  and  208 , internal battery  302 , and possibly LEDs  310  and LED driver circuitry  308 . However, sensor  21  also includes sensor circuitry  402  and an associated detector  403 . The physical condition detector in the example is a device to generate a signal in response to detection of a particular stimulus condition, such as an Infrared or visible light sensitive photodiode for motion detection or the like. The sensor circuitry  402  includes electronics to operate and/or respond to output of the detector to provide appropriate information to the higher level logic, in this example of the MCU  204 . As discussed above, in a motion sensor implementation, the detector  403  may include a particular type of motion sensor (IR photodiode or other IR detector, visible light photodiode or other visible light photocell, imager, etc.). The sensor circuitry  402  in turn provides any drive signals under control of the MCU  204  and formats any outputs from the particular motion detector for input to the MCU  204 . 
     Similar to wall switch  20 , battery  302  is installed in the sensor  21  during the manufacturing of the sensor. 
     Physical installation of the wall switch  20  and/or sensor  21  is performed by an installer (e.g., an electrician, a lay person, etc.) in a residential and/or commercial application. For example, assuming a luminaire  10  shown in  FIG. 1  is installed in a particular area of a commercial store, the installer (store employee) may install at least one wall switch  20  and/or at least one sensor  21  in that particular area. The installation process could be performed by mounting the wall switch  20  and sensor  21  either directly to the wall (i.e., surface mount), or recessing wall switch  20  and/or sensor  21  into the wall or ceiling or the like (i.e., recessed mount). Since wall switch  20  and sensor  21  do not require external AC power (i.e. they are battery powered), a lay person could easily and safely perform the installation by screwing the physical wall switch  20  and/or sensor  21  to the wall (or any surface for that matter) using screws, bolts, adhesive backing, etc. In the example shown in  FIG. 1 , wall switch  20  may be mounted to the wall at a standard height of a conventional wall switch, and sensor  21  may be mounted on the wall at a height closer to the ceiling of the room or in the ceiling itself such that any movement in the particular area can be detected by sensor  21 . 
     One benefit of this battery power conservation approach, over conventional techniques, is that each sensor  21  or wall switch  20  (upon manufacturing), already includes an internal battery which does not require a pull tab in order to ensure the battery life is not wasted. In order to ensure the life of battery  302 , the wall switch  20  or the sensor  21  includes a power distribution unit  312  and/or appropriate programming of the MCU  204  that ensures that only minimal battery power is utilized when the device is not in use, and especially prior to the commissioning process (i.e. the time between manufacturing and installation and/or commissioning). 
     Essentially, the wall switch  20  and sensor  21  (upon being manufactured) are automatically entered into a “deep sleep” mode. This deep sleep mode provides minimal power (e.g., less than 5 micro-amps) to MCU  204  which essentially allows the MCU to determine if a button  304  has been pushed on the wall switch  20  or determine if motion has been detected by sensor circuitry  402 . It should be noted, that during this deep sleep mode, power is not supplied to the RF transceivers, LEDs or any other non-essential electronics. 
     An example of the commissioning and control process of wall switch  20  will now be described in detail. Upon manufacturing, wall switch  20  initially operates in the deep sleep mode, thus consuming minimal power. Upon installation in a particular setting, wall switch  20  does not communicate with any other device, because it is still in the deep sleep mode. However, after receiving a stimulus (i.e., when a user pushes button  304 ), drive sense circuitry  306  of the wall switch sends a trigger signal to MCU  204 . MCU  204  then sends a control signal to power distribution unit  312  in order to awake the device  20  from the deep sleep mode. This allows more power from battery  302  to be supplied not only to MCU  204  but also to other electronics within the wall switch such as the RF transceivers  206 ,  208  and any LEDs  310 . 
     Upon awaking from the deep sleep mode, MCU  204  controls RF transceiver  208  to transmit an active beacon. Assuming use of BlueTooth for commissioning, the MCU  204  powers the BlueTooth transceiver, which sends an initial packet one or more times with a unique key. This beacon transmission may include the identity of the wall switch and effectively is a request to pair for another wireless device such as a commissioning device  25  to pair with the wall switch. Assuming a commissioning device  25  is in the vicinity of wall switch  20  at wake-up, the device  25  responds to the beacon signal; and an exchange of messages ensues in accordance with the BlueTooth protocol for pairing. 
     When the wall switch  20  is successfully paired with commissioning device  25 , a commissioning process takes place. The commissioning process includes the exchange of other information between the devices. Upon successful commissioning, the wall switch  20  is now configured to control a luminaire  10 . The commissioning process may be implemented in a variety of procedures using a variety of protocols, once the wall switch  20  is paired with the commissioning device  25 . At a high level, the lighting control device  20  or  21  provides information about the device to the commissioning device  25 , which the commissioning device  25  includes in a control group table that device  21  is e.g building for the group that will include the lighting control device  20  or  21 . The commissioning device  25  provides to the lighting control device  20  or  21  any provisioning or configuration information that the device  20  or  21  may need to operate on the wireless control network as a control device of the particular group, such as the assigned RF channel and the identifier (ID) of the subscribed group channel that designates the lighting control group to which the lighting control device  20  or  21  will belong when the system is fully commissioned and operational. 
     Thus, wall switch  20  will enter a normal operations mode after commissioning. Unless activated for luminaire control, the wall switch  20  initial entry into the normal operations mode often will involve entry into a hibernate state appropriate for normal lighting related operations in which the wall switch waits for further stimulus from the user. Different sleep or hibernate states/modes will have various peripherals of the integrated process powered off at various lower power levels for the device. In hibernate, memory is refreshed, timers are running, and one or more pin inputs to the circuitry are active, for example, allowing the wall switch  20  to wake up on a button press detection. Other elements are powered down. The deep sleep mode used before commissioning may be the same mode or a similar mode with somewhat more or a somewhat less of the device operational. For example, the deep sleep mode may have the same components active as in the hibernate mode and/or have additional higher frequency oscillators available, as compared to the hibernate mode. 
     The stimulus from the user may be the user pressing the ON or OFF button on wall switch  20  in order to turn ON or OFF luminaire  10 . Assuming the user pushes the ON button on wall switch  20 , MCU  204  of wall switch  20  then instructs RF transceiver  206  to transmit a control signal to luminaire  10  and/or the luminaire designated as the group monitor. This control signal instructs luminaire  10  to turn ON light source  210 . When the user wants to turn OFF luminaire  10 , the user simply presses the OFF button on wall switch  20 , at which point wall switch  20  instruct RF transceiver  206  to transmit another control signal to luminaire  10  and/or the luminaire designated as the group monitor instructing luminaire  10  to turn OFF light source  210 . After performing these control functions, the wall switch  20  will reenter the normal sleep mode and await further stimulus from the user. 
     An example of commissioning sensor  21  and then controlling luminaire  10  will now be described in detail. As already described, when sensor  21  is manufactured it enters a deep sleep mode thus conserving battery power from battery  302 . However, upon installation and receiving stimulus, MCU  204  of sensor  21  instructs power distribution unit  312  to supply the battery power  302  to other electronics such as RF transceivers  206 ,  208  and LEDs  310 . 
     The stimulus of sensing in device  21  is somewhat different than by the wall switch  20 , because sensor  21  may not have any buttons to press. The stimulus to sensor  21  may simply be that detector  403  sensor circuitry  402  sense motion in the vicinity of sensor  21  or a combination of motion along with some other stimulus. For example, if the device has multiple sensors, for example audio and motion sensors, a predetermined audio signal (e.g. tone, song, chirps, etc.) would be capable of waking up the device alone or in combination with detected motion. In a multiple sensor configuration, for example, the processor may be configured to awake the device from the deep sleep mode in response to a combination of the trigger signal from the sensor and a predetermined signal from the other sensor, or responsive to detection of either one or both of the predetermined audio signal or motion. 
     Thus, in the deep sleep mode, minimal power is provided to sensor circuitry  402  in order to detect motion. This motion that serves as the predetermined stimulus to wake up the device  21  for possible commissioning may be configured to be any motion, a specific pattern of motion (e.g. a particular movement about a room or a particular gesture, and/or motion for a specific amount of time), in order for the sensor circuitry  402  to send a trigger signal to MCU  204  which triggers the sensor  21  to awake from the deep sleep mode and begin beaconing. 
     Once sensor device  21  awakes from the deep sleep mode due to the trigger, MCU  204  controls BlueTooth transceiver  208  to transmit an active beacon. This active beacon is then received a commissioning device  25  and the two become paired. The sensor  21  and commissioning device  25  then perform the commissioning process where they exchange information between one another. After the commissioning process is completed successfully, sensor  21  is configured to control a luminaire  10 . 
     During operation (after commissioning), sensor  21  may detect motion of a user within its vicinity. Once detector  403  and sensor circuitry  402  detect this motion, the circuitry  402  sends a trigger signal to MCU  204  which triggers MCU  204  to control RF transceiver  206  to send an appropriate control signal to luminaire  10  and/or the luminaire designated as the group monitor. The control signal sent to luminaire  10  may instruct luminaire  10  to turn ON light source  210  due to motion being detected in the vicinity (i.e., a person is in the room). After a certain amount of time, when detector  403  and sensor circuitry  402  do not detect any other motion in the vicinity, MCU  204  of sensor  21  may make a determination that the user has left the room. If this determination is made, MCU  204  instructs the RF transceiver  206  to send another control signal to luminaire  10  and/or the luminaire designated as the group monitor instructing luminaire  10  to turn OFF light source  210 . At this point, the MCU  204  of sensor  21  enters the normal sleep mode and awaits further stimulus. 
     By manufacturing wall switch  20  and sensor  21  with an internal battery, an installer does not need to insert a battery into each of these devices upon installation. This minimizes installation time/cost and prevents users from stealing the batteries. In addition, by placing the sensor  21  and the wall switch  20  in the deep sleep mode upon manufacturing, an additional physical pull tab is not necessary. This reduces errors during installation as well as reduces manufacturing costs. Essentially, sensor  21  and wall switch  20  stay in a deep sleep mode where they consume very minimal battery power until awoken from the deep sleep mode by a stimulus. This stimulus is received through an interaction with these devices (i.e., pushing buttons on the wall switch, the sensor detecting motion in the room, etc.). This overall process ensures that the battery life of battery  302  and wall switch  20  and sensor  21  is extended as long as possible. 
     It will be understood that the terms and expressions used herein have the ordinary meaning as is accorded to such terms and expressions with respect to their corresponding respective areas of inquiry and study except where specific meanings have otherwise been set forth herein. Relational terms such as first and second and the like may be used solely to distinguish one entity or action from another without necessarily requiring or implying any actual such relationship or order between such entities or actions. The terms “comprises,” “comprising,” “includes,” “including,” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. An element preceded by “a” or “an” does not, without further constraints, preclude the existence of additional identical elements in the process, method, article, or apparatus that comprises the element. 
     Unless otherwise stated, any and all measurements, values, ratings, positions, magnitudes, sizes, and other specifications that are set forth in this specification, including in the claims that follow, are approximate, not exact. They are intended to have a reasonable range that is consistent with the functions to which they relate and with what is customary in the art to which they pertain. 
     While the foregoing has described what are considered to be the best mode and/or other examples, it is understood that various modifications may be made therein and that the subject matter disclosed herein may be implemented in various forms and examples, and that they may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim any and all modifications and variations that fall within the true scope of the present concepts.