Patent Description:
In some cases, the outdoor appliances may have electronic controls. Thus, instead of having a manual dial to adjust the amount of gas being introduced at the burner, an electrical control is set or adjusted by the user. The electrical control then interacts with a solenoid or other electro-mechanical component to regulate the flow of gas to the burner. Still, however, as is the case with manual dials and nobs, the user of the outdoor appliance has to be present at the grill to make changes to settings on the grill.

To overcome this problem, some newly-manufactured outdoor appliances have been equipped with Bluetooth radios. These Bluetooth radios allow communication with nearby electronic devices including cell phones or tablets of the appliance's owner. Range limitations to the Bluetooth radio, however, necessitate that the user of the appliance still be within a certain proximity of the appliance. Once outside this proximity, the user no longer has any communication with the appliance, and thus cannot control any functionality related to the appliance. Moreover, even when connected to a mobile device, the appliance has very limited options as to what can be controlled over Bluetooth. Indeed, the appliance has no access to any information or control signals beyond the user's mobile device. <CIT> relates to a grill controller device. <CIT> relates to a cooking appliance. <CIT> relates to a system and method for home control and automation. <CIT> relates to an air-conditioning system.

Embodiments described herein are directed to communicating with and controlling operation of electronically-controlled appliances. In one embodiment, a provided computer system includes the following: a receiver that receives inputs from computing systems including a first input indicating that a electronically-controlled appliance is permitted to communicate with the cloud computing platform. The computer system further includes a notification generator that generates notifications that are to be sent to software applications. The software applications are configured to control functions of the electronically-controlled appliance.

The computer system further includes a transmitter that sends generated notifications to the software applications. A generated notification may indicate that the cloud computing platform is communicably connected to the electronically-controlled appliance. The receiver receives a second input from the software application indicating that various functions are to be performed on the electronically-controlled appliance. In response, the transmitter sends instructions to the electronically-controlled appliance to perform the specified functions. These functions are then interpreted and carried out by a hardware controller on the electronically-controlled appliance.

In another embodiment, a computer system performs a method for controlling an electronically-controlled appliance including receiving a first input from a computing system indicating that an electronically-controlled appliance is permitted to communicate with a cloud computing platform. The computer system generates a notification that is to be sent to a software application, where the software application is configured to control functions of the electronically-controlled appliance. The computer system transmits the generated notification to the software application, where the generated notification indicates that the cloud computing platform is communicably connected to the electronically-controlled appliance. The computer system then receives a second input from the software application indicating that specified functions are to be performed on the electronically-controlled appliance, and transmits instructions to the electronically-controlled appliance to perform the specified functions. These functions are then interpreted and carried out by a hardware controller on the electronically-controlled appliance.

In yet another embodiment, a cloud computing platform is provided for communicating with and controlling operation of electronically-controlled appliances. The cloud computing platform includes the following: a receiver that receives inputs from other computing systems including a first input indicating that an electronically-controlled appliance is permitted to communicate with the cloud computing platform. The receiver receives a second input indicating that specified functions are to be performed by the electronically-controlled appliance. Within the cloud computing platform, a control signal generator is provided which generates control signals that are to be sent to the electronically-controlled appliance. The control signals are configured to control functions of the electronically-controlled appliance according to the received second input. A transmitter is also provided within the cloud computing platform which transmits the generated control signals to the electronically-controlled appliance for performance of the specified functions. The functions are then interpreted and carried out by a hardware controller on the electronically-controlled appliance.

Additional features and advantages will be set forth in the description which follows, and in part will be apparent to one of ordinary skill in the art from the description, or may be learned by the practice of the teachings herein. Features and advantages of embodiments described herein may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. Features of the embodiments described herein will become more fully apparent from the following description and appended claims.

To further clarify the above and other features of the embodiments described herein, a more particular description will be rendered by reference to the appended drawings. It is appreciated that these drawings depict only examples of the embodiments described herein and are therefore not to be considered limiting of its scope. The embodiments will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:.

Embodiments described herein may implement various types of computing systems. These computing systems are now increasingly taking a wide variety of forms. Computing systems may, for example, be mobile phones, electronic appliances, laptop computers, tablet computers, wearable devices, desktop computers, mainframes, and the like. As used herein, the term "computing system" includes any device, system, or combination thereof that includes at least one processor, and a physical and tangible computer-readable memory capable of having thereon computer-executable instructions that are executable by the processor.

A computing system typically includes at least one processing unit and memory. The memory may be physical system memory, which may be volatile, non-volatile, or some combination of the two. The term "memory" may also be used herein to refer to non-volatile mass storage such as physical storage media or physical storage devices. If the computing system is distributed, the processing, memory and/or storage capability may be distributed as well.

As used herein, the term "executable module" or "executable component" can refer to software objects, routines, methods, or similar computer-executable instructions that may be executed on the computing system. The different components, modules, engines, and services described herein may be implemented as objects or processes that execute on the computing system (e.g., as separate threads).

As described herein, a computing system may also contain communication channels that allow the computing system to communicate with other message processors over a wired or wireless network. Such communication channels may include hardware-based receivers, transmitters or transceivers, which are configured to receive data, transmit data or perform both.

Embodiments described herein also include physical computer-readable media for carrying or storing computer-executable instructions and/or data structures. Such computer-readable media can be any available physical media that can be accessed by a general-purpose or special-purpose computing system.

Computer storage media are physical hardware storage media that store computer-executable instructions and/or data structures. Physical hardware storage media include computer hardware, such as RAM, ROM, EEPROM, solid state drives ("SSDs"), flash memory, phase-change memory ("PCM"), optical disk storage, magnetic disk storage or other magnetic storage devices, or any other hardware storage device(s) which can be used to store program code in the form of computer-executable instructions or data structures, which can be accessed and executed by a general-purpose or special-purpose computing system to implement the disclosed functionality of the embodiments described herein. The data structures may include primitive types (e.g. character, double, floating-point), composite types (e.g. array, record, union, etc.), abstract data types (e.g. container, list, set, stack, tree, etc.), hashes, graphs or other any other types of data structures.

As used herein, computer-executable instructions comprise instructions and data which, when executed at one or more processors, cause a general-purpose computing system, special-purpose computing system, or special-purpose processing device to perform a certain function or group of functions.

Those skilled in the art will appreciate that the principles described herein may be practiced in network computing environments with many types of computing system configurations, including, personal computers, desktop computers, laptop computers, message processors, hand-held devices, multi-processor systems, microprocessor-based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, mobile telephones, PDAs, tablets, pagers, routers, switches, and the like. The embodiments herein may also be practiced in distributed system environments where local and remote computing systems, which are linked (either by hardwired data links, wireless data links, or by a combination of hardwired and wireless data links) through a network, both perform tasks. As such, in a distributed system environment, a computing system may include a plurality of constituent computing systems.

Those skilled in the art will also appreciate that the embodiments herein may be practiced in a cloud computing environment.

Still further, system architectures described herein can include a plurality of independent components that each contribute to the functionality of the system as a whole. This modularity allows for increased flexibility when approaching issues of platform scalability and, to this end, provides a variety of advantages. System complexity and growth can be managed more easily through the use of smaller-scale parts with limited functional scope. Platform fault tolerance is enhanced through the use of these loosely coupled modules. Individual components can be grown incrementally as business needs dictate. Modular development also translates to decreased time to market for new functionality. New functionality can be added or removed without impacting the core system.

Referring to the figures, <FIG> illustrates an environment <NUM> in which at least one embodiment described herein may be employed. The environment <NUM> includes a cloud computing platform <NUM>. The cloud computing platform <NUM> may include any number of local or distributed computer systems. The cloud computing platform <NUM> includes at least one hardware processor <NUM> and physical system memory <NUM>. The cloud computing platform <NUM> further includes modules for performing a variety of different functions.

For instance, the communications module <NUM> may be configured to communicate with other computing systems (e.g. mobile computing device <NUM>). The communications module <NUM> may include any wired or wireless communication means that can receive and/or transmit data to or from other computing systems such as wired or wireless network interface cards. The communications module <NUM> may be configured to interact with databases, mobile computing devices (such as mobile phones or tablets), electronically-controlled appliances (e.g. <NUM>), embedded computing systems or other types of computing systems.

In one embodiment, the cloud computing platform <NUM> may be configured to communicate with mobile computing device <NUM> (e.g. a smart phone, laptop, tablet or wearable device) and/or with electronically-controlled appliance <NUM>. The mobile computing device <NUM> may also be able to communicate with the electronically-controlled appliance <NUM>, either directly or through the cloud computing platform <NUM>. The electronically-controlled appliance <NUM> may be any type of appliance or device that is electronically-controlled. For example, any device that is controlled by an electronic hardware controller <NUM> would be an electronically-controlled appliance <NUM>. The electronic hardware controller <NUM> may include computer memory that has instructions stored thereon for controlling the appliance or device.

In one example embodiment, the electronically-controlled appliance <NUM> is a grill or smoking appliance, although the embodiments described herein are not limited to such. The grill/smoker may be operated by the electronic hardware controller <NUM>. The controller <NUM> may be configured to control temperature, control cooking cycles, control fuel burn rate, monitor ambient temperature, or perform other functions. In some cases, the electronic hardware controller <NUM> may include or be communicatively connected to a radio such as a Bluetooth or WiFi radio that can wirelessly communicate with other computing systems (e.g. <NUM> and <NUM>). The electronic hardware controller <NUM> may control these communications, and may present a display to a user. The display may include a variety of information, including a graphical user interface (GUI) that allows interaction from an appliance user.

The cloud computing platform <NUM> may be configured to interact with the electronically-controlled appliance <NUM> through the communications module <NUM>. The cloud computing platform <NUM> further includes a receiver for receiving inputs from the mobile computing device <NUM>. A software application <NUM> running on the mobile computing device <NUM> may include a GUI for controlling the electronically-controlled appliance <NUM>. The GUI may provide various notifications, alerts, buttons, fields, prompts or other elements that allow monitoring and control of the electronically-controlled appliance <NUM>.

In one embodiment, the cloud computing platform <NUM> is provided for communicating with and controlling operation of electronically-controlled appliances such as appliance <NUM>. The cloud computing platform <NUM> has hardware elements including a processor <NUM>, memory <NUM>, a receiver <NUM>, a transmitter <NUM>, various communication radios in the communications module <NUM>, and other hardware elements. The receiver <NUM> may be configured to receive inputs from computing systems (including mobile computing device <NUM>) such as first input <NUM> indicating that an electronically-controlled appliance is permitted to communicate with the cloud computing platform <NUM>.

The cloud computing platform <NUM> also includes a notification generator <NUM> configured to generate notifications (e.g. <NUM>) that are to be sent to software applications such as software application <NUM> running on mobile computing device <NUM>. The software application <NUM> may be configured to control functions <NUM> of the electronically-controlled appliance <NUM>. A transmitter <NUM> is also part of the cloud computing platform <NUM>. The transmitter <NUM> may be configured to send a generated notification <NUM> to software application <NUM>, where the notification indicates that the cloud computing platform <NUM> is communicably connected to the electronically-controlled appliance <NUM>.

The receiver <NUM> may then receive a second input <NUM> from the software application <NUM> indicating that certain functions are to be performed on the electronically-controlled appliance <NUM>. Upon receiving such an input, the transmitter sends control instructions <NUM> to the electronically-controlled appliance <NUM> to perform the specified functions. The functions are then interpreted and carried out by an electronic hardware controller on the electronically-controlled appliance <NUM> according to the control instructions <NUM>.

These control instructions <NUM> may include, for example, an indication that a certain amount of fuel pellets are to be added to a smoker's combustion area, or that a specified amount of fuel (such as propane) is to be burned by a grill, or that a specified internal temperature is to be reached and maintained. The software application <NUM> may send a notification of availability to the cloud computing platform <NUM> to indicate whether the electronically-controlled appliance <NUM> is available or not to receive such control instructions <NUM>.

If the notification of availability indicates that the electronically-controlled appliance <NUM> is currently available to receive instructions, the software application <NUM> may provide a user interface <NUM> for a user to interact with. Through this user interface, the user can control the appliance <NUM>. The user interface may provide many different functions <NUM> that are controllable using the user interface. As mentioned above, these functions <NUM> may include substantially any function that the electronically-controlled appliance <NUM> is capable of (or is modified to be capable of) performing. For grill and smokers, this may include controlling burn rate, temperature, cooking cycle, fuel dispensing, controlling timers, accessing recipes, displaying probe temperatures or alerts, turning the device on or off, or other functions.

Other electronically-controlled appliances <NUM> such as ovens, refrigerators, blenders, toasters, dishwashers, coffee machines, mixers, bread makers, washers and dryers or other appliances may also be controlled using the software application <NUM> in a manner that is the same as or similar to that used to control a grill or smoker. The software application <NUM> may provide a notification of availability for the appliance <NUM>, and the application may display a user interface for controlling functions of that appliance. As inputs are received from a user, an instruction generator in the application <NUM> may generate instructions that are specific to the appliance, and that are interpretable and understandable by the appliance <NUM>. These control instructions <NUM> are then sent to the electronically-controlled appliance <NUM> to control the functions <NUM> specified by the user.

In some cases, a user may control whether the electronically-controlled appliance <NUM> is permitted to communicate with the cloud computing platform <NUM> or with other computing systems such as mobile computing device <NUM>. The electronically-controlled appliance <NUM> may send an indication to the cloud computing platform <NUM>, indicating that it wishes to communicate with one or more mobile computing devices <NUM> (for example, to download a recipe). A user may provide input indicating whether the electronically-controlled appliance <NUM> is permitted to communicate with the mobile computing device <NUM> or not. If such communication is permitted by the user, the electronically-controlled appliance <NUM> may communicate with an access point <NUM> (such as a router) that permits flow of data between the appliance <NUM> and the cloud computing platform <NUM> and/or between the appliance <NUM> and the mobile computing device <NUM>.

The cloud computing platform <NUM> further includes an advertisement generating module <NUM>. The advertisement generating module <NUM> may generate advertisements <NUM> which are sent to the electronically-controlled appliance <NUM>. The advertisements may be based on the user's use of the appliance, or may be based on a sale that might interest the user (such as a sale on brisket), or may be based on analytics. Indeed, the cloud computing platform <NUM> includes an analytics module <NUM> configured to perform analytics on usage data. The analytics module <NUM> may, for example, perform statistical analyses on usage data received from the appliance <NUM>. Then, based on the statistical analysis, the advertisement generating module <NUM> can generate an advertisement that would be most likely to be relevant to the user, based on their appliance usage.

Other modules such as the remote diagnostics module <NUM> and control signal generator <NUM> may also be included in the cloud computing platform <NUM>. The remote diagnostics module <NUM> may analyze usage data and determine what problems are currently occurring on the appliance. The remote diagnostics module <NUM> may also analyze the appliance usage data and determine what problems are likely to occur based on the user's use of the appliance. A control signal generator <NUM> may be used by the cloud computing platform <NUM> to generate control instructions <NUM> that are sent to the electronically-controlled appliance <NUM> to perform specified functions <NUM>. The control instructions <NUM> are interpretable by the appliance's electronic hardware controller <NUM>. Once interpreted, the functions are carried out on the appliance according to the instructions <NUM>.

<FIG> illustrates an embodiment in which a smoker <NUM> is controlled via a smart phone <NUM> (or rather via a software application running on the smart phone). The smart phone <NUM> may communicate with a cloud service <NUM> which, in turn, communicates with the smoker <NUM>. The cloud service <NUM> may provide data storage along with other features. The data storage may store, for example, recipes used by the smoker <NUM> to smoke meats, vegetables, fruits or other food items. Using the cloud service <NUM>, a customer or user may use their phone <NUM>, tablet, laptop, desktop or other computer system to control the functions of the smoker <NUM>.

The functionality may include smoker/grill monitoring including monitoring of the internal temperature, external ambient air temperature, probe temperature (e.g. from probes that communicate wirelessly), and alerts that may be raised by the grill or smoker. Other controls may include adjusting the temperature by adding more fuel, or allowing the existing fuel (such as pellets) to burn down so as to reduce the temperature, turning the device on or off or turning certain components on or off, controlling the timer or custom cooking cycles, or monitoring probe temperature alerts. Many more controls may be provided on the smart phone <NUM>, and the amount and type of controls may be updated over time to add new functionality.

As control inputs are received at the smart phone <NUM> (or other electronic device), they are passed to the cloud service <NUM> via a wired or wireless data transmission. The control inputs are then passed to the smoker/grill <NUM> directly or via an access point such as a WiFi router. In this manner, a user may be able to control their smoker/grill from substantially any location that has internet access. In some cases, the user may even be able to ignite the smoker/grill <NUM> remotely, while in other cases, such functionality may be disabled unless the user is within a specified distance of the grill, as determined by a GPS or Bluetooth geofence.

<FIG> illustrates an environment similar to that of <FIG> in which a cloud service <NUM> links various devices including a smoker/grill <NUM> and a smart phone <NUM> or other electronic computing device. The cloud service <NUM> is also connected to various other services and systems including, but not limited to, data analytics, third party advertising, remote diagnostic services, eCommerce services, social media, customer service assistance and others. For example, usage data for the smoker/grill <NUM> may be uploaded to the cloud service <NUM> and stored in the global data storage.

This usage data (such as when the smoker was turned on, how long was it turned on, what temperature did it reach, what was the average internal temperature, what was the average external temperature, what cooking/smoking recipe was used, what controls were used and when or other operational usage data) may be analyzed by an analytics engine in combination with data from other users. As such, usage data from many different users may be logged and analyzed to identify broad patterns of use. These analytics may then be used to refine and improve future smokers or grills, or may be used for other purposes such as providing advertising.

In one example, the cloud service may track users' usage of the smoker/grill, and may determine which products or recipes may be of interest to a given user based on similarities between their usage of the grill and other's usage. The usage data may also be used to perform remote diagnostics of the smoker/grill <NUM>. For instance, the usage data may indicate that a user's grill temperature exceeded a normal operating temperature (e.g. due to a grease fire). As such, certain parts may have failed or may be likely to fail due to the extreme heat. Other usage data may indicate different problems that may be likely to occur as a result of how the user is using their grill. Usage data may also be sent to social media announcing successful implementation of a recipe, or announcing to party guests that a specified meat is smoking and will be ready at a certain time. Many other social media implementations may also be used as provided by the cloud service <NUM>.

<FIG> illustrates an application workflow <NUM> for a software application such as application <NUM> of <FIG>. The application may run on a mobile device such as a phone or tablet or wearable device, or may be run on a desktop computing system or may be run through a web browser. It will be understood that the application workflow <NUM> is one example of an application workflow, and other embodiments and implementations are possible.

The application workflow <NUM> includes a home menu <NUM> that, on launch, shows the status of the grill (or other electronically-controlled appliance), the status of any probes in use, the status of any timers in use and any alerts. A first time setup may walk a user through connecting the grill to an access point (such as a WiFi access point), and linking the mobile device to the grill. The first time setup may also take the user through a tutorial on how to use the grill, or at least certain components of the grill. The home menu <NUM> may show any or all of the following: grill temperature, probe temperature, timer (if running), active alerts (e.g. a low pellet alert or an empty hopper alert), current cook cycle, current cook time-to-completion, startup delay time, or other information.

The application may have many different tabs and menus, including one or more of the following: a control menu <NUM> that allows users to control the grill's target temperature, control the grill's target probe temperatures, set or restart timers, set startup delays, remotely start or turn grill off, set alerts or perform other functionality. A cook cycles menu <NUM> may be provided which allows users to select from different cooking cycles (i.e. pre-programmed cooking routines that control temperature for a specified amount of time to cook or smoke the food item in a certain manner), save cooking cycles, upload cooking cycles to a cloud service (e.g. <NUM> of <FIG>), provide the user a play-by-play indicator of what is occurring during a cooking cycle, implement a certain cook cycle for a given food, browse and download recipes and/or cook cycles, provide access to a food warming cycle that keeps the food at a certain temperature for a specified time, or perform other functions.

The cook cycles menu <NUM> may have one or more submenus including a cook cycle creation menu <NUM>. The cook cycle creation menu <NUM> may allow a user to create his or her own custom cooking cycle. The custom cooking cycle can specify a given time to begin and end, a certain temperature to hold or change to throughout the cycle, various customizable triggers or conditions that may cause changes to the cooking cycle such as shortening or lengthening the cooking time, or increasing or decreasing internal grill temperature for a given length of time. The cook cycle creation menu <NUM> may allow a user to push the customized cooking cycle to the grill and have the grill begin implementation of the cycle. This customized cooking cycle may also be saved directly on the grill or in the cloud service <NUM>.

Other menus provided on the application workflow may include a settings menu <NUM>. The settings menu may allow a user to set up WiFi, Bluetooth or communication means on the grill. The settings menu <NUM> may also allow configuration settings to be accessed and changed. The settings menu <NUM> may further provide tutorial as well as other appliance- or application-specific settings that may be changed using the settings menu. A map menu or tab <NUM> may be provided which gives access to local retailers including pellet sellers or distributors, local butchers or farms for meat or vegetables, local events including barbeques or tailgate parties, or locations of nearby grill distributors. The map menu <NUM> may also provide other information that is specific to the appliance, such as a repair shop that specializes in repairs for that appliance.

A social media menu <NUM> may be provided which allows users to upload photos, recipes, videos or other media which may be of interest to other users. The social media tab may allow the user to post images or status updates to social media websites, including location pins, updates from the grill itself or other information. As such, the social media menu <NUM> allows users to share their grilling/smoking experience with others.

A recipes menu <NUM> allows users to browse recipes available online or through the cloud service <NUM>. When browsing these recipes, the user may select to download the recipes to their phone or other device. These recipes can be collected in a library and shared via social media. Users can sort the recipes, add their own recipes, add pictures to others' recipes or otherwise interact with the recipe database. A store menu <NUM> allows a user to purchase pellets, propane or other fuel, purchase sauces, rubs, grill accessories, grill parts or full grills/smokers. The store may be expanded to allow the purchase of food items or other items that may be used in conjunction with the grill. The concepts described above will be explained further below with regard to method <NUM> of <FIG>.

In view of the systems and architectures described above, methodologies that may be implemented in accordance with the disclosed subject matter will be better appreciated with reference to the flow chart of <FIG>. For purposes of simplicity of explanation, the methodologies are shown and described as a series of blocks. However, it should be understood and appreciated that the claimed subject matter is not limited by the order of the blocks, as some blocks may occur in different orders and/or concurrently with other blocks from what is depicted and described herein. Moreover, not all illustrated blocks may be required to implement the methodologies described hereinafter.

<FIG> illustrates a flowchart of a method <NUM> for communicating with and controlling operation of electronically-controlled appliances. The method <NUM> will now be described with frequent reference to the components and data of environment <NUM>.

Method <NUM> includes receiving a first input from one or more computing systems indicating that at least a first electronically-controlled appliance is permitted to communicate with a cloud computing platform (<NUM>). For example, cloud computing platform <NUM> may receive first input <NUM> from mobile computing device <NUM> indicating that electronically-controlled appliance <NUM> is permitted to communicate with the cloud computing platform. The cloud computing platform <NUM> may thus be apprised that the electronically-controlled appliance <NUM> will be sending data requests to the platform or will otherwise be attempting to communicate with the platform. In some cases, the communication may include requesting to download a recipe or custom cooking cycle.

Method <NUM> further includes generating a notification that is to be sent to a software application, the software application being configured to control one or more functions of the electronically-controlled appliance (<NUM>). The notification generator <NUM> of the cloud computing platform <NUM> may generate notification <NUM> which is sent to be sent to the software application <NUM> of the mobile computing device <NUM>. The notification <NUM> indicates that the cloud computing platform is communicably connected to the electronically-controlled appliance <NUM>. After this notification <NUM> is generated, the transmitter <NUM> of the cloud computing platform <NUM> transmits the generated notification to the software application <NUM> (<NUM>).

Method <NUM> also includes receiving a second input from the software application indicating that one or more specified functions are to be performed on the electronically-controlled appliance (<NUM>). For instance, the receiver <NUM> of the cloud computing platform <NUM> may receive second input <NUM> from the mobile computing device <NUM>. The second input specifies functions <NUM> that are to be performed on the electronically-controlled appliance <NUM>. The functions may include adjusting the temperature by increasing or decreasing burn rate, monitoring internal or external temperatures, monitoring wireless probes, adjusting or setting timers, or performing other functions applicable to the appliance. The transmitter <NUM> then transmits control instructions <NUM> to the electronically-controlled appliance <NUM> to perform the specified functions <NUM> (<NUM>). The functions <NUM> are interpreted and carried out by an electronic hardware controller on the electronically-controlled appliance <NUM>.

The receiver <NUM> of the cloud computing platform <NUM> may further receive portions of data including ambient temperature data for the environment in which the electronically-controlled appliance <NUM> resides. For example, a grill or smoker may record the ambient air temperature using a temperature sensor on the outside of the appliance. The ambient air temperature may be monitored throughout the cooking cycle, and may lead to a change in operation. For example, the control instructions <NUM> may be altered by the cloud computing platform <NUM>, prior to transmission to the electronically-controlled appliance <NUM>, to compensate for the ambient air temperature. For instance, on a hotter day, the cooking cycles may be adjusted to avoid overheating the meat or other food, while on a colder day, the cooking cycles may be adjusted upwards to burn hotter so as to maintain the desired temperature. Other adjustments may also be made based on the ambient air temperature.

The electronic hardware controller <NUM> of the electronically-controlled appliance <NUM> may be configured to receive food temperature data from a digital thermometer. The digital thermometer may be communicably connected to the hardware controller <NUM> of the grill and/or to the cloud computing platform <NUM>. The digital probes may be configured to interact with the cloud computing platform regardless of which grill or other appliance it is used with. In some cases, prior to transmitting the control instructions <NUM>, the cloud computing platform adjusts the control instructions to further include an alert based on the food temperature data.

For instance, the hardware controller <NUM> may communicate with the digital thermometer, and set alerts based on probe temperature. When the alerts are triggered, the electronic hardware controller <NUM> communicates with the cloud computing platform <NUM> and/or the mobile computing device <NUM>. Moreover, a user can use the software application <NUM> on the mobile computing device <NUM> to monitor probe temperatures, internal temperatures, and/or ambient temperatures using the software application <NUM> on the mobile computing device <NUM>.

At least in some embodiments, the cloud computing platform <NUM> may be configured to communicate directly with the electronically-controlled appliance via an access point <NUM> within range of the electronically-controlled device <NUM>. A user of the mobile computing device <NUM> may use the software application <NUM> to grant permission for the electronically-controlled device <NUM> to communicate directly with the cloud computing platform <NUM>. As such, the electronically-controlled device <NUM> may send and receive data from the cloud computing platform <NUM> through a wired or wireless access point <NUM>. In other cases, the cloud computing platform <NUM> may communicate with the electronically-controlled appliance <NUM> through the software application <NUM> provided on the mobile computing device <NUM>. The software application <NUM> relays communications (i.e. indirect communication <NUM>) between the cloud computing platform <NUM> and the electronically-controlled appliance <NUM>.

In addition to facilitating communication between the mobile device <NUM> and the electronically-controlled device <NUM>, the cloud computing platform <NUM> may also provide services such as advertising services. The cloud computing platform <NUM> includes an advertisement generating module <NUM> configured to generate advertisements <NUM> for transmission to the electronically-controlled appliance <NUM> or to the software application <NUM> running on the mobile device <NUM>. The advertisement generating module may, for example, access information from local retailers including grocery stores. Based on grill or smoker usage data, the cloud computing platform <NUM> may determine which ads would be most interesting to a user, and may send those advertisements <NUM> to the software application <NUM> or to the grill directly. The advertisements <NUM> may be tailored for users of the electronically-controlled appliance <NUM> based on usage information for the user and potentially based on nearby user's appliance usage.

Indeed, the cloud computing platform <NUM> may receive usage data from many different electronically-controlled devices including device <NUM>. This usage data may be used for a variety of purposes, including generating targeted advertising. The usage data may also be used by the analytics module <NUM>. The analytics module <NUM> may be configured to analyze the usage data associated with the electronically-controlled appliances and generate appliance-related analytics for the electronically-controlled appliance(s). The usage data may include wattage drawn by a hot rod, time turned on, temperature (internal and external), indications of how the user cooks, when they cook, what recipes they use, etc. The analytics data may generally show, for a specific user or for a grouping of users, how the users are using their grills or other appliances.

In one example, the analytics data is used to verify or void a warranty claim. For instance, if a user had a grease fire in the grill causing the internal temperature to exceeded <NUM> degrees Fahrenheit, the cloud computing platform <NUM> would know what had occurred, and would know that the warranty was voided due to the excessive temperature. Contrariwise, if a user makes a warranty claim and their usage has been within normal parameters, the warranty claim may be verified and fulfilled.

The cloud computing platform <NUM> may further include a remote diagnostics module <NUM> that is configured to perform remote diagnostics on the electronically-controlled appliance <NUM>. The remote diagnostics module <NUM> may access the user's usage data to predict failures for certain components of the electronically-controlled appliance <NUM>. If the appliance has been mistreated or heavily used in a certain manner, the remote diagnostics module <NUM> may be able to determine that a component failure is likely and may prompt the user (via a display on the grill such as that shown in <FIG> or via the software application <NUM>) to replace the component or at least indicate that a failure may be imminent. The remote diagnostics module <NUM> may also be able to determine why a given part isn't working based on the appliance's usage information.

<FIG> illustrates an embodiment of a smoker <NUM> which is an electronically-controlled device. The smoker <NUM> has one or more manual controls <NUM> such as buttons or knobs, as well as a display <NUM>. The display may be a touchscreen display that allows a user to provide input. The display <NUM> may include electronic controls such as buttons or sliders or input fields that allow users to adjust settings on the smoker <NUM>. One input field may be a "Custom Smoking Options" field <NUM> that allows users to input their own customized smoking cycles or modify existing smoking cycles. These smoking cycles may apply to certain meats or to certain recipes and may be used to achieve a certain result. The display <NUM> may include other controls including a "Download Recipes" button <NUM> that allows users to download recipes directly to the smoker <NUM> through the access point <NUM> or through the software application <NUM>. The display <NUM> may also include a place to display advertisements <NUM>, a timer <NUM>, or other items which may be useful to an appliance user.

Additionally or alternatively, an embodiment of a cloud computing platform is provided (e.g. <NUM> of <FIG>) for communicating with and controlling operation of electronically-controlled appliances (e.g. <NUM>). The cloud computing platform <NUM> has a hardware processor <NUM>, a receiver <NUM> configured to receive inputs from other computing systems including a first input <NUM> indicating that the electronically-controlled appliance <NUM> is permitted to communicate with the cloud computing platform. The receiver <NUM> also receives a second input <NUM> indicating that various specified functions <NUM> are to be performed by the electronically-controlled appliance <NUM>.

The cloud computing platform <NUM> also includes a control signal generator <NUM> configured to generate control signals <NUM> that are to be sent to the electronically-controlled appliance <NUM>. The control signals <NUM> are configured to control functions <NUM> of the electronically-controlled appliance <NUM> according to the second input <NUM>. The platform <NUM> also includes a transmitter <NUM> that transmits the generated control signals <NUM> to the electronically-controlled appliance <NUM> for performance of the specified functions <NUM>. These functions are then interpreted and carried out by an electronic hardware controller <NUM> on the electronically-controlled appliance <NUM>.

In some cases, the cloud computing platform <NUM> may further include or be communicatively connected to a data store in which recipes, custom smoking patterns, and user appliance usage data are stored. The cloud computing platform <NUM> may be configured to access selected recipes from the data store and generate control signals for the electronically-controlled appliance according to the recipe. Indeed, the control signal generator <NUM> may generate control signals <NUM> based on a recipe, such that the food is smoked by the appliance <NUM> according to a smoke pattern specified in the recipe.

In this manner, a user can simply load a recipe on his or her mobile device <NUM> and provide that recipe to the cloud computing platform <NUM> where the control signal generator <NUM> will automatically access the recipe, generate control instructions <NUM> and send them to the electronically-controlled appliance <NUM>. The appliance's hardware controller will then receive the control instructions, interpret them and carry them out. Accordingly, as a result of the control instructions, the grill/smoker may ignite and begin a smoking cycle, a timer may be set, alerts may be established and other fuel may begin to be fed into the combustion area. As such, multiple physical and computer-related results may occur based on the user's input at the mobile device <NUM>. At least in some cases, these control instructions <NUM> may be overridden by the manual controls (<NUM> of <FIG>) or by the electronic controls <NUM>.

In some embodiments, the cloud computing platform <NUM> may be configured to access user appliance usage data from a data store. The platform <NUM> may then use this usage data to generate advertisements <NUM> for the appliance user based on the appliance usage data, and further transmit the generated advertisements to the electronically-controlled appliance <NUM> or to a software application <NUM> running on the user's mobile electronic device <NUM>. The advertisements may be tailored to the user, or may be general announcements that may be of interest to owners of that appliance.

Claim 1:
A system comprising an electronically controlled smoker or grill (<NUM>, <NUM>, <NUM>) and a cloud computing platform (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>),
wherein the smoker or grill (<NUM>, <NUM>, <NUM>) comprises:
one or more manual controls such as buttons or knobs (<NUM>, <NUM>),
a display (<NUM>) allowing a user to input customized smoking cycles or modify existing smoking cycles,
and the cloud computing platform (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>) is configured for communicating with and controlling operation of the smoker or grill (<NUM>, <NUM>, <NUM>),
the cloud computing platform (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>) comprising a hardware processor (<NUM>), a receiver (<NUM>) configured to receive inputs from a smart phone (<NUM>) including a first input indicating that the smoker or grill (<NUM>, <NUM>, <NUM>) is permitted to communicate with the cloud computing platform (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>),
if such communication is permitted by the user, the system is configured to establish communication between the smoker or grill (<NUM>, <NUM>, <NUM>) and an access point (<NUM>) that permits flow of control inputs between the grill or smoker (<NUM>, <NUM>, <NUM>) and the cloud computing platform (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>) and/or between the grill or smoker (<NUM>, <NUM>, <NUM>) and the smart phone (<NUM>), to enable the user to control the smoker or grill (<NUM>, <NUM>, <NUM>) from any location that has internet access, and
wherein the system is configured to disable an ignition functionality unless the smart phone (<NUM>) is within a specified distance of the smoker or grill (<NUM>, <NUM>, <NUM>).