Google Professional-Machine-Learning-Engineer Exam With Confidence Using Practice Dumps

The training time of a machine learning model depends on several factors, such as the complexity of the model, the size of the data, the hardware resources, and the hyperparameters. To minimize the training time without significantly compromising the accuracy of the model, one should optimize these factors as much as possible.

One of the factors that can have a significant impact on the training time is the scale-tier parameter, which specifies the type and number of machines to use for the training job on AI Platform.  The scale-tier parameter can be one of th e predefined values, such as BASIC, STANDARD_1, PREMIUM_1, or BASIC_GPU, or a custom value that allows you to configure the machine type, the number of workers, and the number of parameter servers 1

To speed up the training of an LSTM-based model on AI Platform, one should modify the scale-tier parameter to use a higher tier or a custom configuration that provides more computational resources, such as more CPUs, GPUs, or TPUs. This can reduce the training time by increasing the paral lelism and throughput of the model training.  However, one should also consid er the trade-off between the training time and the cost, as higher tiers or custom configurations may incur higher charges 2

The other options are not as effective or may have adverse effects on the model accuracy. Modifying the epochs parameter, which specifies the number of times the model sees the entire dataset, may reduce the training time, but also affect the model’s convergence and performance. Modifying the batch size parameter, which specifies the number of examples per batch, may affect the model’s stability and generalization ability, as well as the memory usage and the gradient update frequency.  Modifying the learning rate parame ter, which specifies the step size of the gradient descent optimization, may affect the model’s convergence and performance, as well as the risk of overshooting or getting stuck in local minima 3

Option A is incorrect because creating a collaborative filtering system that recommends articles to a user based on the user’s past behavior is not the best approach to suggest articles that are similar to the articles they are currently reading.  Collaborative filtering is a method of recommendation that uses the ratings or prefe rences of other users to predict the preferences of a target user 1 . However, this method does not consider the content or features of the articles, and may not be able to find articles that are similar in terms of topic, style, or sentiment.

Option B is correct because encoding all articles into vectors using word2vec, and building a model that returns articles based on vector similarity is a suitable approach to suggest articles that are similar to the articles they are currently reading.  Word2vec is a technique that learns low-dimensional and dense representations of words from a large corpus o f text, such that words that are semantically similar have similar vectors 2 . By applying word2vec to the articles, we can obtain vector representations of the articles that capture their meaning and usage.  Then, we can use a similarity measure, such as cosine similarity, to find articles that have similar vectors to the current article 3 .

Option C is incorrect because building a logistic regression model for each user that predicts whether an article should be recommended to a user is not a feasible approach to suggest articles that are similar to the articles they are currently reading.  Logistic regression is a supervised learning method that models the probability of a binary outcome (such as recommend or not) based on some input features (such as user prof ile or article content) 4 . However, this method requires a large amount of labeled data for each user, which may not be available or scalable. Moreover, this method does not directly measure the similarity between articles, but rather the likelihood of a user’s preference.

Option D is incorrect because manually labeling a few hundred articles, and then training an SVM classifier based on the manually classified articles that categorizes additional articles into their respective categories is not an effective approach to suggest articles that are similar to the articles they are currently reading.  SVM (support vector machine) is a supervised learning method that finds a hyperplane that separates the data into different classes (such as news categories) with the maximum margin 5 . However, this method also requires a large amount of labeled data, which may be costly and time-consuming to obtain. Moreover, this method does not account for the fine-grained similarity between articles within the same category, or the cross-category similarity between articles from different categories.

 Transfer learning is a technique that leverages the knowledge and weights of a pre-trained model and adapts them to a new task or domain 1 .  Transfer learning can save time and resources by avoiding training a model from scratch, and can also improve the performance and generalization of the model by using a larger and more diverse dataset 2 .  AI Platform provides several established text classification models that can be used for transfer learning, such as BERT, ALBERT, or XLNet 3 .  These models are based on state-of-the-art natural language p rocessing techniques and can handle various text classification tasks, such as sentiment analysis, topic classification, or spam detection 4 . By using one of these models on AI Platform, you can customize the model’s code, serving, and deployment, and use Kubeflow pipelines for the ML platform. Therefore, using an established text classification model on AI Platform to perform transfer learning is the best option for this use case.