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Google Cloud Data Engineer Practice Exam | WarOfCloud




Google Cloud Professional Data EngineerProfessional Course


All Job Seekers


Online and Classroom Sessions


Week Days and Week Ends

Duration :

30 to 45 days

Google Cloud Professional Data Engineer Objectives

•Best practices for Google Cloud Professional Data Engineer
•How to implement Google Cloud Professional Data Engineer on different Platforms.
•Learn how to integrate and customize Google Cloud Professional Data Engineer code.
•learn How to use Test driven Development in Google Cloud Professional Data Engineer .
•Learn Google Cloud Professional Data Engineer in the most efficient and easy way
•Learn Google Cloud Professional Data Engineer ) quickly, easily and effectively by using this course
•Learn Basic and Advanced Google Cloud Professional Data Engineer Programming and become a Google Cloud Professional Data Engineer Developer
•you will be confident in your skills as a Developer / designer
•Google Cloud Professional Data Engineer -Learn how to use one component inside an other i.e complex components.

Google Cloud Data Engineer Practice Exam | WarOfCloud Training Highlights

•Free Aptitude classes & Mock interviews
•Exercises and handouts after every session
•Doubt clarification in class and after class
•We enage Experienced trainers for Quality Training
•Indutry oriented training with corporate casestudies
•Hands On Experience – will be provided during the course to practice
•Affordable fee structure to help as many students strive career in IT industry
• Our dedicated HR department will help you search jobs as per your module & skill set, thus, drastically reducing the job search time

Who are eligible for Google Cloud Professional Data Engineer

•C, c# c c++, Java Developer, Php Developer, dot net c#
•Digital Marketing, General Manager, Business Development, Product Manager, Big Data, Business Analyst, Frontend Developer, Human Resources, data
•java, php, .net, 3dmodelling, unitydeveloper, androiddeveloper, gamedeveloper, Software Developer, Php, Java, Photoshop
•PHP, OpenCart Developer, Magento Developer, Html, Javascript, Jquery, Css, Photoshop, html, css, bootstrap, javascript, jquery, Business Development
•Software Engineer, Software Developer, Business Analyst, manager, Delivery Manager, Team Lead, .Net Framework, Java Framework, Mobile Application Development


These exams are up to date with the current version as of September 2019 The Data Engineer practice exam will familiarize you with types of questions you may encounter on the certification exam and help you determine your readiness or if you need more preparation and/or experience. Successful completion of the practice exam does guarantee you will pass the certification exam as the actual exam is longer and covers a wider range of topics. For a full list of the topics you could be tested on, see the exam guide. There is no limit to the number of times you can take this practice exam. You can save your progress. There is 120 minutes time limit for the practice exam, but we recommend completion in 60 minutes or less. This practice exam is available in English Certification exam guide 1. Designing data processing systems 1.1 Selecting the appropriate storage technologies. Considerations include: Mapping storage systems to business requirements Data modeling Tradeoffs involving latency, throughput, transactions Distributed systems Schema design 1.2 Designing data pipelines. Considerations include: Data publishing and visualization (e.g., BigQuery) Batch and streaming data (e.g., Cloud Dataflow, Cloud Dataproc, Apache Beam, Apache Spark and Hadoop ecosystem, Cloud Pub/Sub, Apache Kafka) Online (interactive) vs. batch predictions Job automation and orchestration (e.g., Cloud Composer) 1.3 Designing a data processing solution. Considerations include: Choice of infrastructure System availability and fault tolerance Use of distributed systems Capacity planning Hybrid cloud and edge computing Architecture options (e.g., message brokers, message queues, middleware, service-oriented architecture, serverless functions) At least once, in-order, and exactly once, etc., event processing 1.4 Migrating data warehousing and data processing. Considerations include: Awareness of current state and how to migrate a design to a future state Migrating from on-premises to cloud (Data Transfer Service, Transfer Appliance, Cloud Networking) Validating a migration 2. Building and operationalizing data processing systems 2.1 Building and operationalizing storage systems. Considerations include: Effective use of managed services (Cloud Bigtable, Cloud Spanner, Cloud SQL, BigQuery, Cloud Storage, Cloud Datastore, Cloud Memorystore) Storage costs and performance Lifecycle management of data 2.2 Building and operationalizing pipelines. Considerations include: Data cleansing Batch and streaming Transformation Data acquisition and import Integrating with new data sources 2.3 Building and operationalizing processing infrastructure. Considerations include: Provisioning resources Monitoring pipelines Adjusting pipelines Testing and quality control 3. Operationalizing machine learning models 3.1 Leveraging pre-built ML models as a service. Considerations include: ML APIs (e.g., Vision API, Speech API) Customizing ML APIs (e.g., AutoML Vision, Auto ML text) Conversational experiences (e.g., Dialogflow) 3.2 Deploying an ML pipeline. Considerations include: Ingesting appropriate data Retraining of machine learning models (Cloud Machine Learning Engine, BigQuery ML, Kubeflow, Spark ML) Continuous evaluation 3.3 Choosing the appropriate training and serving infrastructure. Considerations include: Distributed vs. single machine Use of edge compute Hardware accelerators (e.g., GPU, TPU) 3.4 Measuring, monitoring, and troubleshooting machine learning models. Considerations include: Machine learning terminology (e.g., features, labels, models, regression, classification, recommendation, supervised and unsupervised learning, evaluation metrics) Impact of dependencies of machine learning models Common sources of error (e.g., assumptions about data) 4. Ensuring solution quality 4.1 Designing for security and compliance. Considerations include: Identity and access management (e.g., Cloud IAM) Data security (encryption, key management) Ensuring privacy (e.g., Data Loss Prevention API) Legal compliance (e.g., Health Insurance Portability and Accountability Act (HIPAA), Children’s Online Privacy Protection Act (COPPA), FedRAMP, General Data Protection Regulation (GDPR)) 4.2 Ensuring scalability and efficiency. Considerations include: Building and running test suites Pipeline monitoring (e.g., Stackdriver) Assessing, troubleshooting, and improving data representations and data processing infrastructure Resizing and autoscaling resources 4.3 Ensuring reliability and fidelity. Considerations include: Performing data preparation and quality control (e.g., Cloud Dataprep) Verification and monitoring Planning, executing, and stress testing data recovery (fault tolerance, rerunning failed jobs, performing retrospective re-analysis) Choosing between ACID, idempotent, eventually consistent requirements 4.4 Ensuring flexibility and portability. Considerations include: Mapping to current and future business requirements Designing for data and application portability (e.g., multi-cloud, data residency requirements) Data staging, cataloging, and discovery

Eligiblity for Certification :

Google Cloud Certified – Professional Data Engineer Practice Exams have been designed for students as a final preparation step before appearing for the exams. We recommend taking the course atleast 15 days before the exam and make sure you pass all of them with more then 80%