lcd touch screen microwave free sample

2.Dual magnetron staggered arrangement and innovated waveguide coupled with precise calculate cavity volume which improves the microwave density and ensures reaction uniformity and effectiveness of 40 digestion vessels.

4.Individual float safety door is designed to release surge pressure inside the cavity and seal again to ensure the running safety. Self- checking program will identify the door status before start the microwave.

• Perform highly diversified duties to install and maintain electrical apparatus on production machines and any other facility equipment (Screen Print, Punch Press, Steel Rule Die, Automated Machines, Turret, Laser Cutting Machines, etc.).

A microwave oven can be a device that cooks food by using microwave energy generated from magnetron. Current microwave ovens have both manual cooking functions and automatic cooking functions. When the manual cooking function enables a user to adjust the output level and cooking time manually, the automatic cooking function cooks food automatically by selecting an item from menu without separately adjusting the cooking time. Automatic cooking functions in current microwave ovens are preset and static. In view of this, improvements may be made over conventional methods if, for example, a user were able to download recipes from a remote crowd-sourced database and/or modified said recipes. These recipes could then be automatically executed by the microwave oven. BRIEF SUMMARY OF THE INVENTION

FIG. 6 illustrates a process flow of control of personalization of a smart-microwave oven based on user preferences (e.g. recipes, region and/or country), according to some embodiments.

Disclosed are a system, method, and article of manufacture of a smart-microwave oven, according to some embodiments. The following description is presented to enable a person of ordinary skill in the art to make and use the various embodiments. Descriptions of specific devices, techniques, and applications are provided only as examples. Various modifications to the examples described herein may be readily apparent to those of ordinary skill in the art, and the general principles defined herein may be applied to other examples and applications without departing from the spirit and scope of the various embodiments.

FIG. 1 depicts a system 100 of smart-microwave oven, according to some embodiments. System 100 can include a smart-microwave oven 106 communicatively coupled with other computing devices (e.g. mobile devices, personal computers, servers, etc.) via a computer network such as the Internet 102 and/or local networking devices (e.g. WiFi modem 104). Smart-microwave oven 106 can be operated by an operating system (e.g. operated by an Android® or Linux®Operating system). Smart-microwave oven 106 can communicate directly with internet through Wi-Fi modem 104 as it involves an operating system which controls the oven and no special section is needed for receiving data and perform cooking O0rations. Smart-microwave oven 106 has no need of external device as well as no voltage level converters is required. Smart-microwave oven 106 can operate a user input system (e.g. a touch screen LCD panel). Said touchscreen panel can include a single section, as well as, various operation specific input buttons (and/or virtual buttons displayed as software application icons) such as, inter alia, cooking, selecting recipe, etc. Various software application icons can appears on said touch screen LCD panel. A user touch can perform various manual input actions on its touch screen with his/her fingers. Smart-microwave oven 106 can automatically synchronize all recipes from a webserver (e.g. see infra) to its memory whenever it connects to Internet 102. Accordingly, many recipes can be stored in a local datastore of the smart-microwave oven 106. Smart-microwave oven 106 can include voice recognition functionalities for user input means to control its operations. Smart-microwave oven 106 can include a proximity sensor (and/or other gesture-recognition input device such as, inter alia: depth-aware cameras, stereo cameras, 2D camera, wearable motion sensors, etc. and/or any combination thereof) for controlling its operations. Smart-microwave oven 106 can understand and/or learn user preferences and display various personalized recipes and/or cooking tips. Smart-microwave oven 106 can provide access to a server in a cloud-computing functionality that can access a datastore of crowd-sourced recipes (e.g. see infra). Smart-microwave oven 106 can include heating managers that manages the operation of any food-item heating systems (e.g. heating elements, microwaves, convection heaters, etc.). Smart-microwave oven 106 can include timing managers that manages the time period of cooking food items.

FIG. 2 depicts, in block diagram format, various sub-systems of a smart-microwave oven, according to some embodiments. For example, smart-microwave oven 106 can include various smart-oven systems 210 such as, inter alia: a convection relay, a microwave relay, a grill relay, microcontroller, a fan and/or a motor relay. Each subsystem can be individually connected to a microcontroller. The microcontroller can be connected to a microprocessor unit 202 (e.g. via connectivity interface(s) 212 utilizing USB, RS232, RS422, RS485, SPI or I2C protocol controls). System 200 can include clock system(s) 214 with real-time clock signals by a crystals means. A random access memory (RAM) 218 (e.g. Double Data Rate Synchronous Dynamic Random Access Memory) can be coupled with microprocessor 202 to facilitate dynamic data acquisition from the data storage. A non-volatile memory 216 (e.g. I2C Flash, SPI Flash, SD/MMC/MMC Plus, NAND Flash, etc.) can be coupled with microprocessor 202. A user interface system(s) can be coupled with microprocessor 202. Example user interfaces can include a touch screen along with LCD display with back light, proximity sensors, microphones, speakers, and the like. Local network connectivity can be provided with network connection(s) 220. For example, WIFI and Bluetooth connectivity can be provided to microprocessor 202 to connect with external devices and/or the Internet 102. Power supply unit 208 can provide microprocessor 202 with a battery backup. In one example, power supply unit 208 can include an SMPS unit which supplies a steady twelve volt (12v) supply regulated as five volts (5v) or three point three volts (3.3v) supply depends on type of microprocessor. Other subsystems can be included. For example, a door sensor can be used to monitor whether the door is closed or open to avoid any hazardous events due to microwave or heat. Smart-oven systems 210 can include modules 222 for controlling various functionalities. For example, a module can be included for optimizing cooking time (e.g. via crowd sourcing techniques combined with optimization and/or machine learning algorithms). For example, recipes in the recipe store can be continuously improved by gathering data from various users. The users can have the option to add or reduce cooking time by editing the downloaded the recipe. From these edits, over the time, the time and temperature for cooking a dish can be automatically optimized. An API module can be provided in some embodiments. Modules 222 can include an API module in the smart-oven system that enables the smart-oven system to connect to other computing devices. This is an implementation of internet of things concept and machine to machine communication. An application programming interface (API) can be provided for third-party developers to connect to smart-oven system and use information from it for various purposes. This API module can also be used to develop apps/devices to control the smart-oven system. The API module can also be used to send information about recipes over to other devices. The crowd sourcing module can also be available in the website of that provides information to various smart-oven systems 210 and/or supporting servers. The crowd sourcing can be done by the user entering the ingredients and steps in the text area provided in the website. The recipe can then be stored in a web server and made available to the users of smart-oven systems 210.

FIG. 5 illustrates an example set of processes 500 performed by microprocessor of a smart-microwave oven, according to some embodiments. Microprocessor can be microprocessor 202 of FIG. 2 supra. More specifically, FIG. 5 illustrates example processes how microprocessor 202 enables a touch console to process data internally. When internet connection is available, microprocessor 202 can synchronize with a recipe database and updates the local datastore 504 with new recipes via data from an external source 502. Virtually, unlimited number of recipes can be stored in this local storage and hence, it offers unlimited dishes for automatic cooking. In process 506, the LCD touchscreen can display cooking instructions (e.g. recipes that include instructions and/or ingredients for a specified set of dishes) and/or ingredients. In process 508, a speaker in the smart oven can output instructions and/or ingredients. In process 510, the smart-microwave oven triggering signals from microprocessor 202 can turn on microwave/grill and/or fans in specified modes (e.g. temperature control, etc.). In process 512, the user can input smart-microwave oven controls via voice commands received by microphones. In process 514, proximity sensor(s) detect nearby objects and alert microprocessor 202.

In one example of process 500, microprocessor 202 is connected to the LCD touch panel which displays ingredients list and each step of cooking. All the available recipes and their details are listed in this touch panel according to the categories. The touch panel also takes user input and sends it to the microprocessor. The microprocessor fetches the recipe according to the user"s choice only. A speaker can reads out the instructions step by step. This voice assisted cooking is easier and more efficient. A microphone can record a user"s voice in a computer-readable medium and pass that data to microprocessor 202 for processing. A proximity sensor can detect any objects in near a specified surface of microprocessor 202. Microprocessor 202 can take corresponding actions based on that input. In the event that a step in the recipe is an oven triggering signal (e.g. an instruction to switch on the microwave/grill/fan/convection for a given time period) then microprocessor 202 communicates this instruction to the oven relays to perform a specified action.

FIG. 6 illustrates a process flow 600 of control of personalization of a smart-microwave oven based on user preferences (e.g. recipes, region and/or country), according to some embodiments. In step 602 of process 600, it can be determined if the smart-microwave oven has been used at least once. If yes, then process 600 proceeds to step 604. In step 604, a display of the smart-microwave oven can display a menu as stored in a specified database. In step 606, various current information (such as, inter alia, time of use, recipe, calories, searched key words, selected recipes, quantity, region, country, etc.) can be recorded. If no, then process 600 proceeds to step 608. In step 608, it can be determined the smart-microwave oven has been used two or three times. If yes, process 600 proceeds to step 610. In step 610, the recipe list is reordered in a local database and previously selected recipes in top of list are displayed followed by recipes in similar category. In no, process 600 proceeds to step 612. In step 612, the recipe list in local database is reordered. Weightage to frequently repeated recipes can be provided and sorted based on previous smart-microwave oven use. Process 600 then proceeds to 614. In step 614, various current information (such as, inter alia, time of use, recipe, calories, searched key words, selected recipes, quantity, region, country, etc.) can be recorded. In step 616, the menu as stored in the local database is displayed. In step 618, a specified cooking process is implemented.

In one example of process flow 600, a smart-microwave oven can start for the first time. Smart-microwave oven can display recipes based on categories which is stored in local database. The user can then select the recipe of the user"s preference from list. During this process the smart-microwave oven can record time of use, type of recipe, search query, if any, selected recipes, calories of the recipe selected, quantity, region and/or country. During the next oven use, the recipes can be reordered and displayed in such a way that the previously selected recipes and the ones that are similar to it will be shown on top of list. From the third time usage of smart-microwave oven intelligently displays recipes by reordering the recipes based on comparing and giving weightage to pre-recorded data and sorting the list based on those preferences and its weightage. Each time the smart-microwave oven learns user preferences by recording time of use, type of recipe, selected recipes, calories of the recipe selected, quantity, region and country and continues to learn the user"s dietary habits and shows recipes, health tips and cooking tips based on this.

FIG. 7 illustrates a process flow 700 of crowd-sourcing recipes, according to some embodiments. Process flow 700 can include automatically verifications of recipes and/or their inclusion into a smart-microwave oven recipe database. Each crowd-sourced recipe will be checked if it has got at least one oven triggering signal. The recipe can have a minimum of three instructions including a smart-microwave oven trigger signal. The recipe can be checked if the oven temperature and cooking times are within a minimum and maximum range. Smart oven system can have access to these crowd sourced recipes. A smart-microwave oven users can rate each recipe after cooking and the rating will be synchronized to a central-recipe database server. Based on these ratings the recipes can be sorted (e.g. highest-rated recipes higher on the recipe list). The smart-microwave oven user can also include an option to edit the recipes and/or locally store recipes in the smart-microwave oven based on the user"s preference and taste.

In step 702, the user input a recipe. In step 704, the recipe is included in a crowd-sourced recipe database (e.g. in a remote server and/or in a cloud-computing platform). In step 706, it can be determined if the recipe has a minimum of three steps. If yes, process 700 proceeds to step 708. In step 708, it can be determined if at least one smart-microwave oven trigger is included in the recipe. If yes, process 700 proceeds to step 710. In step 710, it can be determined if the smart-microwave oven temperature for the recipe is fixed between a minimum and maximum temperature. If yes, process 700 proceeds to step 712. In step 712, it can be determined if the smart-microwave oven cooking time for the recipe is fixed between a minimum and maximum time range. If yes, process 700 proceeds to step 714. In step 714, the recipe can be included in a recipe database. In step 716, the recipe can be accessed by the smart-microwave oven and displayed on the smart-microwave oven"s display (and/or other user interface such as provided via a speaker phone, etc.).

FIG. 8 illustrates an example process 800 for decoding a recipe for a smart-microwave oven, according to some embodiments. In step 802, a recipe can be added to a recipe database (e.g. the recipe databases provided herein). For example, a text-entry field can be used by the user to enter recipe into the database. Each recipe step can be entered into a separate field. Each recipe step and/or ingredient can have a separate entry field. These recipe steps ca be stored in a file in Unicode format and/or the file name is associated to the recipe name and attributes in a database table. Each recipe can have attributes such as, inter alia: time, main ingredient, time of the day (e.g. breakfast, lunch, dinner). In step 804, a recipe can be accessed. For example, when a recipe is requested by name or attributes, it can be searched for and the corresponding file is send to the smart-microwave oven. In step 806, a recipe can be decoded. For example, the file is send to the smart-microwave oven when requested. Each recipe step can be obtained individually and analyzed by decoder algorithm. If a smart-microwave oven trigger action is detected, then the step can be converted into a command for the oven (e.g. heat in microwave for 20 minutes). This can be an action the smart-microwave oven uses natural language processing (NLP). This time can be for cooking one portion of the food in standard conditions. In some examples, smart-microwave oven use this time to calculate the cooking time right when it is being done. It calculates by considering the following factors, such as, inter alia: the time for cooking/heating is decided on the quantity of food in the microwave oven; the present temperature of the food is noted and the cooking/heating time is calculated according to that; the piece size is noted and cooking/heating time is calculated on it. Smart-microwave oven can include various sensors in place for calculating all these factors.

The smart-microwave oven can be a microwave oven that has smartness integrated to it. The smart-microwave oven can utilize an Android® or Linux® powered panel compared to ordinary user consoles. The smart-microwave oven can synchronize recipes from the Internet (and/or other remote database) and cook dishes automatically once the ingredients required are provided. Dishes can be cooked automatically. The user need not know any recipes or how to operate an oven. The smart-microwave oven can stream cookery videos from the Internet (and/or other remote database) so that the user can cook a dish while watching the video. The smart-microwave oven can include an ingredients search functionality. The ingredients search functionality can enable the user clicks on the name of an ingredient and the user is shown an image of the same. This can assist in identifying ingredients. The user also has the provision for entering his/her own recipes which will be stored in the smart-microwave oven and can be used for cooking later. The user can also share recipes through online social media websites. The smart-microwave oven can be controlled by user"s voice using voice recognition technology. Also user can give instructions to the smart-microwave oven using proximity sensor. The smart-microwave oven can connect to the Internet and updates its recipe database with the new recipes in a remote database. The smart-microwave oven can also retrieve relevant video files and stored in its database. Required videos can be downloaded from the Internet and played with a video player in the smart-microwave oven.

The Android® and/or Linux® operating systems can provide a GUI for the smart-microwave oven (and/or other type of smart oven). The operating system can receives the input from the user and processes it and passes the corresponding actions to a microcontroller. The operating system can work as the embedded operating system for the smart-microwave oven. The operating system can process voice of the user (e.g. with voice recognition algorithms) and/or user"s input on a proximity sensor (and/or other type of user gesture input system) and perform corresponding instructions. Instructions can also be received from a touch screen system. For example, a user selects a corresponding food-item dish from a main menu in touch screen LCD display and device checks whether dish is available or not in the local storage. In case dish is not available in data of device, the device downloads the recipe list as well as cooking methods from the internet from a common recipe portal website and shows the user how to cook along with voice assist. The user performs the corresponding actions prescribed by the smart-oven system and closes the door then the oven self-adjust the temperature and time for cooking that dish. The Android® or Linux® operating systems can manage a GUI for the smart-oven system. It receives the input from the user and processes it and passes the corresponding actions to a microcontroller. The microprocessor also obtain input from a microphone. The microcontroller can turns on/off the grill, microwave, convection, fan, motor relays, etc. The smart-microwave oven can be controlled over a phone via Bluetooth®.

There are some significant differences in the two models, however. The original model had two cameras, one over your range and one front-facing for chats. The Next Gen Kitchen Hub adds a third inside the microwave.

In addition to the microwave and its built-in camera, GE Appliances is making this version of the Kitchen Hub Z-Wave compatible, so it can act as a hub for your smart home"s Z-Wave devices. That"s not something I"d deem essential for a kitchen appliance, but it"s a nice option for folks hanging onto the idea of a

The Next Gen Kitchen Hub will be available in late 2020, but we don"t have any details on pricing just yet. AI-powered computer vision cooking technology, accessible for all GE appliances with cameras, will also be available in late 2020. Stay tuned as we find out more about the tablet-wearing microwave that could be your kitchen"s command central.

If the display or screen is frozen, not responding, not scrolling, or the status is not updating, check the following, or perform the following troubleshooting.

UWave-2000 Multifunctional Microwave Chemistry Reaction Workstation is the upgrade of Sineo’s best seller UWave-1000, with Sineo"s 20 years of microwave chemical experience andscientific achievements of many scientists. It integrates the atmospheric pressure and pressurized reactions, microwave heating, ultrasonic wave and ultraviolet irradiation and other functions, and provides the workstation with flexibility and reliability for the microwave chemical research. UWave-2000 hasa intelligent operating system, and 7-inch touch screen control is simple and friendly; It realizes the multi-energy and multifunctional free combination and collocation with the modular design, giving inspiration to your experiment; Itcan conduct the 2000ml open vessel reaction and 500ml pressurized reactionmaximally, thus can help researchers conduct the mass production experiment.Regardless of organic extraction, pharmaceutical research, protein chemistry,novel material science, research of the graphene, polymer synthesis and manyother fields, UWave-2000 will provides various imaginations and feasibility ofthe microwave chemical research.

Good Innovation:Integrate the atmospheric pressure and pressurized reaction, microwave, ultrasonic wave and ultraviolet irradiation and other functions, giving full flexiblility;

High reproducibility:Microwave automatic frequency conversion control, dual temperature control technology, and piezoelectric crystal pressure can ensure the accurate record and representation of each reaction;

Three energy sources - microwave, ultrasonic and ultraviolet irradiation can be free combined and work together,and software control them timing on and off, achieving the synergistic effectby multi energies. UWave-2000 adopts immersion ultrasonic launcher, with an adjustable scope of ultrasound power: 0 - 800W, frequency of 28KHZ, and automatic frequency sweeping and frequency locking; With two sets of ultravioletsource (standard UV lamp power is 300W, dominant wavelength is 365nm, while optional UV lamp power is 100W, and dominant wavelength is 254nm), it can conduct selective photochemical research. UWave-2000 is equipped with multiple reaction vessels, 50-2000ml glass flasks can meet the routine use, and optional multi-standards quartz reaction flasks can meet photochemical reaction under the ultraviolet radiation.

High-precision dual-channel infrared temperature sensor and platinum resistor temperature sensor can switch automatically, with infrared temperature measurement range of 0 - 900°C (standard configuration of 300°C), platinum resistor temperature measurement range of 0 - 250°C and precision of±1°C. The pressurized reaction is equipped with the patentedpiezo-electric crystal (pressure control range of 0 - 5MPa, precision of±0.01MPa), realizing the pressure monitoring of reaction process and ensuring the safe and comfortable experiment. The same system can conduct themicrowave atmospheric pressure and pressurized reaction and the software canjudge the type of the reaction vessel automatically for preventing the wrong operation.

UWave-2000 is equipped with intelligent control software. It can transmit the reaction parameters and curves byconnecting with the computer, and can record each reaction process and curve unlimitedly; It can conduct real-time control or change the reaction parametersof the host through the computer, realizing user"s programmed on or off ofthree energy sources - microwave, ultrasonic and UV radiation. 7-inch color LCDtouch screen can make accurate setting and real-time display of various reaction parameters and curves, and conduct the real-time display of reactioncolor image. The chamber is equipped with color recording system, which canrealize real-time display of reaction image through the color LCD screen, andcan output the image signal for facilitating user"s recording or external connection.