There are many challenges in fault diagnostics and pre-diagnostics techniques, such as:(1) Although the application of deep learning and machine learning models in fault diagnosis and pre-diagnosis technology can be developed, this technology still needs to be improved to increase the model accuracy and applicability. (2) For the identification of fault types, especially how to diagnose operational faults in advance, the standard of selecting the method has not yet been established. (3) There is a lack of visualization tools to assist in optimizing the output of fault diagnosis information and providing decision-making. Therefore, this thesis applies web page structure to realize the visual output and decision-making display of fault diagnosis information and combines multiple machine learning and deep learning models with query-based learning in order to identify fault types, which can help improve the model accuracy. The author participated in the development of the "Motor Monitoring System" of InSynerger Technology Corporation in 2019. In order to make the fault diagnosis and pre-diagnosis technology more refined, and to help people quickly identify the multiple fault types of complex motor systems, this thesis utilizes main characteristics in query-based machine learning and deep learning, which are self-learning, self-adaptation, and processing of complex patterns to assist in judging faults type and status. Moreover, this technique helps achieve the goal of saving maintenance costs. At the beginning of the experiment, samples were taken from the real data, and then the sampled data were classified according to the common fault types of the motors to form a fault diagnosis data set. In terms of fault pre-diagnosis, the bathtub curve and sampling data are used to form a fault pre-diagnosis data set, and then each data set is regarded as a sensing signal and input to an improved artificial intelligence algorithm in order to present the real situation. Experimental results show that under the combination of one-dimensional multi-feature motor spectrum signals and query-based supervised machine learning and deep learning algorithms, Motor Fault Diagnosis System can identify motor fault types more quickly and accurately. This system can make up for the shortcomings that humans are hard to detect subtle changes in signals, humans have slower response times than computers', and humans are unable to monitor and diagnose faults 24/7. In addition, the experimental results also show that query-based learning can improve the anti-noise ability of most supervised machine learning and deep learning algorithms. This feature is especially helpful since the sensor data often collects noise, errors, and redundant signals. In other words, even if the data is mixed with error signals due to human or mechanical factors, query-based learning can still use the data to make more reliable decisions and identifications. The experimental results also show that query-based learning has the ability to improve the classification effect of the deep learning neural network model without changing the network model. The experimental results also achieve the purpose of explainable artificial intelligence through the functions of mapping model parameter changes, visualizing the contents of the data set, and artificial intelligence detection reports. It is also hoped that the fault diagnosis and pre-diagnosis technology developed in this thesis can be used as a reference standard for scholars to choose methods in the future.