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Home Energy Monitor Design: Usability Goals and Interface Principles Guide Case Study By Native Assignment Help.
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Different kinds of household items can detect electricity usage but the home energy monitor is one of them. The device will evaluate the terms usability and experience. Here, the of the software is a home energy monitor. The software is made by the just in mind software. In the software, different types of editing tools have been used. The software is edited by the different kinds of tools and buttons in the just-in-mind software. There are mainly two parts to this assignment. Activity 1, There will discuss the five usability and experience goals and also define energy usage in terms of spending and setting up the initial program in the assignment. Then, there will discuss two usabilities and the user experience also in the assignment. In activity 2, the visibility, feedback, constraints, consistency, and affordance topic will be discussed in the assignment.
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Order AI-FREE ContentAt the start of the designing of the application, it is totally clear that usability and experience are necessary for the designing of an application, the user is involved in the process of designing the software and the case study is about smart home energy monitors, the software will be made on that topic.
The essentiality of the users is carried out by the environment, the interaction contributes to the user experience, and that contributes to the designing of the application. The usability of the software is flexible (Coulton and Lindley, 2019). The software will be on the smart home energy monitor. It interacts with the other system.
The usability of the device determines the system of the device and the interfaces and it is also easy to access on mobile. The usability goals determine the quality side of the device and the home energy monitor (Peruzzini et al. 2019). The smart home energy monitor works as an automated system, it is also called a tracking system. It can even provide real-time feedback for adjusting and reducing energy consumption. The home energy monitor shows how much electrical energy is used by us and it helps to make smart decisions for saving energy. The home energy monitors enable the Wi-Fi services which are installed in the electrical panel.
The most important usability goal should be safe as the traditional smart home energy monitors can even predict the energy consumption for the coast (Buckingham Shum et al. 2019). The application can even predict energy consumption for a better environment by saving fuel and money. It should be better for the environment to save natural behaviors. The natural energy consumption should be tested for a few months.
TEfficiencyis one of the most important usability goals for the home energy monitor, it can be the few steps of energy consumption (Ye et al. 2019). The home energy monitor has different kinds of challenges and it can even carry out a few steps for putting the effort into the application. It helps to find out the information on the usability goals of the home energy monitor. The user has to find the efficiency of the energy consumption. The usability must be measured by completing the given task.
The home energy monitor software has been included in the effectiveness to accomplish the tasks ( Chen et al. 2019). It helps to find the household electricity use in real-time and it helps to find out the information on the energy use of the various types of electronic devices in the house. The application indicates the energy use of the following device.
The user would also support these types of applications. This energy monitor can also present the data graphically. Most people in India use the lowest standard interfaces for reading skills which can even lead to home energy monitors (Li et al. 2019). There are different types of skills and that home energy monitor leads to frustration and irritation. This is also a time-consuming process. It can be measured by using this kind of software that should be used in the application. To get the user experience, the application must be featured to ensure the software or application is again. The following software and its features ensure the interaction of the following application.
To get a good user experience, the fishers are motivated by the application and its features to interact with the application once again (Lutzhoft et al. 2019). Home energy and its features should not be neglected by using the app again and the application gives a great user experience. This application helps to find out how much gas, water, and electricity are used by us in a home and by checking the meter how much money will be paid by us can detect this machine and this machine is helpful for us.
At home, energy monitor people can even check how much they have to pay for their current bills (Mangaroska et al. 2021). It is an unnecessary consumption for the devices and also for heavy users. The home energy monitor can manage the home appliances remotely. It comes from the devices. It is the main appliance for generating the automation process. The problem with the smart home device is that it can only generate automation, but it is not enough. There are different kinds of data for the estimated bills and the energy usage also, it has the reduction tips of such devices. There are also no different types of data for the system bills and reduction tips in such devices. The home energy monitor connects with the circuit breaker and it also helps to track energy consumption. The home energy monitor has a different kind of device feature in the application. The feature of the weather forecast can even interact with the standard interfaces and this operation can even implement this thing, the home energy monitor helps to do the observation test. The weather forecast is for the process of the smartphones by the basic operation. It has been based on the following knowledge. To operate this thing, the implementation of the design can reduce the chance of dissatisfaction and it can be the heuristic evaluation of the following application.
Additionally to learnability, it is essential as the users can even spend their time interacting with the following application (Korn, 2019). By interacting with the application, the application is such a good thing that it can even help to identify the usage of the devices. The memorability of the device is also an important thing, the application helps to remember the electricity usage of the different kinds of data. The condition of the application is also changing rapidly and it leads the good work for the home energy monitor. The home energy monitor application is useful as it can help to detect the energy consumption of electricity and also it can reduce electricity usage. The home energy monitor can do perfect monitoring of the electricity, this device is used for middle-class standard people. In general, the device is costly and it can detect the energy of gas, water, and electricity it has a few requirements too for this environment and this is the main reason for the evaluation and the technology can even impact the behaviors and consent in the evaluation. The main menu of the application helps to research the measurement of the total electricity and the user can pay less money for the electric office by reducing the usage of gas, water, and electricity. The rate of the device is not so high.
The smart home device can even control home appliances. This machine or device helps to reduce power usage ( Li et al. 2019). This device is favorable for home appliances but it is not even enough to control and generate automation. There are also no tips on monthly spending and data usage in such devices. Specifically, the energy monitor connects with the circuit breaker. It helps to track energy consumption with good detail. and it can even also cut the energy consumption of the home.
The goal of the assignment is to monitor the system that can even enable the tracking of energy usage and can even control the routines and home appliances (Sangiorgi et al. 2019). The user has an insight into the gas bills, electricity, water, etc. The home energy monitor can save energy from electricity and it is called energy consumption. The device also can even gain power consumption, this is the objective of the following assignment. This device can control home appliances like electronic gadgets from anywhere (Skarlatidou et al. 2019). The energy consumption allows us to watch the electricity consumption increase the cost for the users. The energy consumption allows the users to see the energy consumption and the cost of it can even increase or decrease. The user can control the budget and its expenses of it. Energy efficiency can even increase or decrease this.
There are mainly six design principles that can even lead to good design the design principles can implement the interface and can help to fulfill the task of the interface and it has the thinking of the design itself.
Visibility is one of them the six design principles. The visibility makes the components for the functions of software products and the visibility is possible here. The functions and components should be designed obviously and this is the primary procedure (Shi et al. 2021). It is a frustrating thing for automated devices as the sensor can even handle hygienic reasons. The user can even react for hygienic reasons. It is troubling to interact with the project and the object can't give clear indications.
The feedback implements into the system that can activate some kind of action. They will be informed that they have activated and accomplished the activity, and the feedback is shown in different kinds of ways and it can look like an animation. It is highlighted for the main combination (Wang et al. 2019). This helps to provide good visibility for the users and it is a combination of all things and it gives good visibility for the users.
The user makes too many mistakes, to decrease the error chance and it helps to choose the correct options and prevent them from choosing the incorrect options (Ali et al. 2019). This should be achieved for example as another option that should proceed and the buttons indicate that it should be deactivated and it can be another option that proceeds and the attention focuses on the needed task (Vieira, 2019). The physical objects are designed by different types of constraints. The key is inserted from the keyhole and they should prevent ambiguity.
Consistency is related to similar operations and it helps to fulfill similar tasks it helps to fulfill the element tasks (Rahman et al. 2021). The users are familiar with the different kinds of components. It means the knowledge and the implementation of the system will help to know the re-learn an interface. The type of device that will be used here can even bring many errors. It helps to return to the previous pages of the screen and it helps to know the consistency of the operations this is known as a complex interface and it is also difficult to maintain consistency for the different kinds of operations. The of the prototype is a Home energy monitor (Webber et al. 2020). The software is made in just in mind software. For getting the more complex interface, the external consistency refers to the operation and the interfaces will also work for multiple devices.
Specifically, affordance gives a hint about the attribute and it can interact with an object. There are mainly two types of affordance in the assignment and it helps to perceive the real affordance (Cooke et al. 2022). The of the affordance is perceived affordance and real affordance. The perceived affordance is mainly virtual and screen-based. Virtual affordance is not straightforward. It cannot be used every day and the scroll bars help to move up and down.
Real affordance helps to interact physically with an object and it is known as obvious in terms.
The prototypes are an important aspect of designing as it is an important way of communication. The of the prototype is a home energy monitor. The software is made in the just-in-mind software (Mathis et al. 2021). It also helps to explore the idea of the design. The low-fidelity prototype has to show the final result of the design. The prototype is cheap and simple and it should be used for exploration because it is used for the exploration.
Figure 1: Screen 1 Home energy monitor front page
This is the first step to making software and this page is called the front page. The of the device is a Home energy monitor and there is a button to start the front page and the of the button is Let’s get started (French et al. 2020). This button helps to go to the other page of the device.
Figure 2: Screen 2 Home energy monitor login page
This is the second page of the device and this device is called a Screen 2 home energy monitor login page (Lawal and Bano, 2019). This prototype is made just in mind. This is the login page of the home energy monitor device.
Figure 3: Screen 3 Home energy monitor registration page
This is the third screen of the following device and the device is called the home energy monitor registration page (Ouafiq et al. 2021). This page is made with just-in-mind software. This page has different kinds of options like phone, email id, password, etc. For returning to the main menu, there are submit and back buttons too.
Figure 4: Screen 4 Home energy monitor verification page
In screen 4, there are also home energy monitor verification pages in the assignment. The software page is made with just in mind (Peruzzini et al. 2020). Here is an option for the verification email, no, phone, OTP, etc and the verify button should be clicked.
Figure 5: Screen 5 Home energy monitor page
At the above, there is an option for the screen 5 energy monitor page. There are also various types of buttons like home energy monitor page, Gas, electricity, water, washing machine, micro oven, etc (Perebner et al. 2019). The prototype is made just in mind. There is also a back page on the prototype screen.
Figure 6: Screen 6 Home energy monitor, 1 page
There is a search button on the middle page. The submit and the location input are also there on screen 6. The location input button is also there (Wang et al. 2020). Then, the submit button has to be clicked.
Figure 7: Screen 7 Home energy Monitor, 1 page
This is the home page of the prototype, here the home energy monitor digit will come on the screen and there is also a back option to go back to the main menu.
Figure 8: Screen 8 Home energy monitor 1 page
There is a payment option too and people can even buy the home appliances in the prototype. The appliances can be added to the cart (Roy, 2019). There is a back option too for going to the main menu.
Figure 9: Screen 9 Home energy monitor 2 page
The home energy monitor prototype has the ready-to-buy option for buying home appliances (Oliveira et al. 2019). By clicking the ready to buy option, the user can go to the next option.
Figure 10: Screen 10 Home energy monitor payment option page
On this page of the prototype, the user can even pay for the home appliances through UPI, Net banking, credit card, etc.
Figure 11: Screen 11 Home energy monitor pay detail page
On this page, there is an option for Net banking, Debit card, cash on delivery, and different kinds of options.
Figure 12: Screen 12 Home energy remote device is controlling other machines' page
This is the opiate of the confirmation (Ye et al. 2019). If the confirmation is true, then they will show the right option.
Figure 13: Screen 13 Home energy remote device is controlling the software page
This is the home energy monitor setting page. This device helps to control the software. For going back to the main menu, there is an option of “Back”.
Reference list
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