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| </tr> | | </tr> |
− | <tr><td colspan="2" class="logo">[[KubernetesIMG.png|200px]]</td></tr> | + | <tr><td colspan="2" class="logo">[[File:Technology_Trends_-_Datalakes_logo.png|200px]]</td></tr> |
| <tr> | | <tr> |
| <th>Status</th> | | <th>Status</th> |
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| <tr> | | <tr> |
| <th>Initial release</th> | | <th>Initial release</th> |
− | <td>May 5, 2019</td> | + | <td>July 12, 2019</td> |
| </tr> | | </tr> |
| <tr> | | <tr> |
| <th>Latest version</th> | | <th>Latest version</th> |
− | <td>July 18, 2019</td> | + | <td>February 17, 2020</td> |
| </tr> | | </tr> |
| <tr> | | <tr> |
| <th>Official publication</th> | | <th>Official publication</th> |
− | <td>[[Media:EN_-_Kubernetes_v0.1_EN.pdf|Kubernetes.pdf]]</td> | + | <td>[[Media:EN_-_Technology_Trends_-_Datalakes.pdf|Datalakes.pdf]]</td> |
| </tr> | | </tr> |
| <tr><td colspan="2" class="disclaimer"><table><tr> | | <tr><td colspan="2" class="disclaimer"><table><tr> |
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| <h2>Business Brief</h2> | | <h2>Business Brief</h2> |
| <p>In an ever-increasing hyperconnected world, corporations and businesses are struggling to deal with the responsibilities of storage, management and quick availability of raw data. To break these data challenges down further:</p> | | <p>In an ever-increasing hyperconnected world, corporations and businesses are struggling to deal with the responsibilities of storage, management and quick availability of raw data. To break these data challenges down further:</p> |
− | <ul class="expand mw-collapsible-content"> | + | <ul> |
| <li>Data comes in many different structures. | | <li>Data comes in many different structures. |
| <ul> | | <ul> |
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| </ul> | | </ul> |
| | | |
− | <p></p> | + | <p>In an effort to resolve these data challenges, a new way of managing data was created which drove data oriented companies to invent a new data storage mechanism called a Data Lake.</p> |
| + | <p class="expand mw-collapsible-content">Data Lakes are characterized as: </p> |
| + | <ul class="expand mw-collapsible-content"> |
| + | <li>Collect Everything<ul> |
| + | <li>A Data Lake contains all data; raw sources over extended periods of time as well as any processed data.</li> |
| + | </ul></li> |
| + | <li>Dive in anywhere<ul> |
| + | <li>A Data Lake enables users across multiple business units to refine, explore and enrich data on their terms.</li> |
| + | </ul></li> |
| + | <li>Flexible Access<ul> |
| + | <li>o A Data Lake enables multiple data access patterns across a shared infrastructure: batch, interactive, online, search, in-memory and other processing engines.</li> |
| + | </ul></li> |
| + | </ul> |
| | | |
| + | <p>Data Lakes are essentially a technology platform for holding data. Their value to the business is only realized when applying data science skills to the lake. </p> |
| | | |
| + | <p>To summarize, usecases for Data Lakes are still being discovered. Cloud providers are making it easier to procure Data Lakes and today Data Lakes are primarily used by Research Institutions, Financial Services, Telecom, Media, Retail, Manufacturing, Healthcare, Pharma, Oi l& Gas and Governments. |
| + | </p> |
| | | |
| <h2>Technology Brief</h2> | | <h2>Technology Brief</h2> |
− | <p>The Kubernetes cluster or deployment can be broken down into several components. The Kubernetes “master” is the machine in charge of managing other “node” machines. The “node is the machine in charge of actually running tasks fed to it via the user or the “master”. The master and nodes can be either a physical or virtual machines. In each Kubernetes cluster, there is one master and multiple nodes machines. The main goal of Kubernetes is to achieve “Desired State Management”. The “master” is fed a specific configuration through its RESTful API which it exposes to the user, and the “master” is then responsible for running this configuration across its set of “node”. The nodes can be thought of as host of containers. They communicate with the “master” through the agent in each node --“Kubelet” process. To establish a specific configuration in Kubernetes, the “master is fed a deployment file with the “.yaml” extension. This file contains a variety of configuration information. Within this information are “Pods” and “replicas”. There is a concept of Pod in Kubernetes and it can be described as a logic collection of containers which are managed as a single application. Resources can be shared within a Pod, these resources include shared storage (Volumes), a unique cluster of IP addresses, and information about how to run each container. A Pod can be thought of as the basic unit of the Kubernetes object model, it represents the deployment of a single instance of an application in Kubernetes <ref>Kubernetes.io. (2018). Kubernetes Basics - Kubernetes. [online] Available at: <i>[https://kubernetes.io/docs/tutorials/kubernetes-basics/] </i></ref>. A Pod can encapsulate one or more application containers. Two models exist for how Pods are deployed within a cluster. The “one-Pod-per-container” means a single pod will be associated with a single container. There can also be multiple containers that run within a single Pod, where these containers may need to communicate with one another as they share resources. In either model, the Pod can be thought of as a wrapper around the application containers. Kubernetes manages the Pod instances rather than managing the containers directly. The Pods are run on the Node machines to perform tasks. Replicas are simply instances of the Pods. Within the “.yaml” deployment file, specifications are instructing the “master” machine how many instances/replicas of each Pod to run, which is handled by a replication controller <ref>Kubernetes.io. (2018). Kubernetes Basics - Kubernetes. [online] Available at: <i>[https://kubernetes.io/docs/tutorials/kubernetes-basics/] </i></ref>. When a node dies or a running Pod experiences an unexpected termination, the replication controller will take note take care of this by creating the appropriate number of Pods <ref>Kubernetes.io. (2018). Kubernetes Basics - Kubernetes. [online] Available at: <i>[https://kubernetes.io/docs/tutorials/kubernetes-basics/] </i></ref>.</p> | + | <p class="expand mw-collapsible-content">The most popular implementation of a Data Lake is through the open source platform called Apache Hadoop. Apache Hadoop is a collection of open-source software utilities that facilitates using a network of many computers to solve problems involving massive amounts of data and computation. Hadoop was originally created by researchers at Google as a storage method to handle the indexing of websites on the Internet; At that time it was called the Google File System. </p> |
| + | <p>A Data Lake is a centralized repository that allows you to store all your structured and unstructured data at any scale. You can store your data as-is, without having to first structure the data, and run different types of analytics—from dashboards and visualizations to big data processing, real-time analytics, and machine learning to guide better decisions.”</p> |
| + | <p class="expand mw-collapsible-content">Data can flow into the Data Lake by either batch processing or real-time processing of streaming data. Additionally, data itself is no longer restrained by initial schema decisions and can be exploited more freely by the enterprise. Rising above this repository is a set of capabilities that allow IT to provide Data and Analytics as a Service (DAaaS), in a supply-demand model. IT takes the role of the data provider (supplier), while business users (data scientists, business analysts) are consumers.</p> |
| + | <p>The DAaaS model enables users to self-serve their data and analytic needs. Users browse the lake’s data catalog (a Datapedia) to find and select the available data and fill a metaphorical “shopping cart” (effectively an analytics sandbox) with data to work with. Once access is provisioned, users can use the analytics tools of their choice to develop models and gain insights. Subsequently, users can publish analytical models or push refined or transformed data back into the Data Lake to share with the larger community.</p> |
| + | <p class="expand mw-collapsible-content">Although provisioning an analytic sandbox is a primary use, the Data Lake also has other applications. For example, the Data Lake can also be used to ingest raw data, curate the data, and apply Export-Transform-Load (ETL). This data can then be loaded to an Enterprise Data Warehouse. To take advantage of the flexibility provided by the Data Lake, organizations need to customize and configure the Data Lake to their specific requirements and domains.</p> |
| <h2>Industry Usage</h2> | | <h2>Industry Usage</h2> |
− | <p class="inline">Kubernetes is an open source system and many companies have begun to adopt it into their existing architecture as well as adapt it to their specific needs. It was originally developed by Google and was made an open source project in 2014. The Cloud Native Computing Foundation is a project of the Linux Foundation providing a community for different companies who are seeking to develop Kubernetes and other container orchestration projects. Several major cloud providers and platforms including Google Cloud Compute, HP Helion Cloud, RedHat Openshift, VMware Cloud, and Windows Azure all support the use of Kubernetes<ref>CENGN. (2018). CENGN and CloudOps Collaborate to Train Industry on Docker and Kubernetes.<i>[Available at: https://www.cengn.ca/docker-kubernetes-training-jan18/ ]</i></ref>. A survey, performed by iDatalabs in 2017, found 2,867 companies are currently using Kubernetes. These companies are generally located in the United States and are also most the computer software industry. Companies on the list hire between 50 and 200 employees, and accumulate 1M-100M in revenue per year. Some of the major companies on this list include GoDaddy inc, Pivotal Software inc, Globant SA, and Splunk inc</p><p class="expand inline mw-collapsible-content">. Kubernetes own approximately 8.6% of the market share within the virtualization management software category <ref>Idatalabs.com. (2018). Kubernetes commands 8.62% market share in Virtualization Management Software<i>[https://idatalabs.com/tech/products/kubernetes] </i></ref>. </p> | + | <p>There are a variety of ways Data Lakes are being used in the industry:</p> |
| + | <ul> |
| + | <li><p><b>Ingestion of semi-structured and unstructured data sources (aka big data)</b>such as equipment readings, telemetry data, logs, streaming data, and so forth. A Data Lake is a great solution for storing IoT (Internet of Things) type of data which has traditionally been more difficult to store, and can support near real-time analysis. Optionally, you can also add structured data (i.e., extracted from a relational data source) to a Data Lake if your objective is a single repository of all data to be available via the lake.</p></li> |
| + | <li><p><b>Experimental analysis </b>of data before its value or purpose has been fully defined. Agility is important for every business these days, so a Data Lake can play an important role in "proof of value" type of situations because of the "ELT" approach discussed above.</p></li> |
| + | <li><p><b>Advanced analytics support. </b>A Data Lake is useful for data scientists and analysts to provision and experiment with data.</p></li> |
| + | <li><p><b>Archival and historical data storage. </b>Sometimes data is used infrequently, but does need to be available for analysis. A Data Lake strategy can be very valuable to support an active archive strategy.</p></li> |
| + | <li><p><b>Distributed processing </b>capabilities associated with a logical data warehouse.</p></li> |
| + | </ul> |
| + | <p class="expand mw-collapsible-content"><b>[https://www.datanami.com/2017/10/03/td-bank-made-data-lake-usable How TD Bank Made Its Data Lake More Usa]</b></p> |
| + | <p class="expand mw-collapsible-content">Toronto-Dominion Bank (TD Bank) is one of the largest banks in North America, with 85,000 employees, more than 2,400 locations between Canada and the United States, and assets nearing $1 trillion. In 2014, the company decided to standardize how it warehouses data for various business intelligence and regulatory reporting functions. The company purchased a Hadoop distribution and set off to build a large cluster that could function as a centralized lake to store data originating from a variety of departments.</p> |
| + | |
| <h2>Canadian Government Use</h2> | | <h2>Canadian Government Use</h2> |
− | <p>There is a lack of documented Government of Canada (GC) initiatives and programs promoting the current and future use of Kubernetes technology. As a GC strategic IT item, Kubernetes is absent from both the GC’s Digital Operations Strategic Plan: 2018-2022 and the GC Strategic Plan for Information Management and Information Technology 2017 to 2021. This may be due to the fact that the GC is currently grappling with the implementation of Cloud Services, and the majority of resources and efforts are occupied with implementation challenges, as well as security concerns related to the protection of the information of Canadians.</p> | + | <p>In 2019, the Treasury Board of Canada Secretariat (TBS), partnered with Shared Services Canada and other departments, to identify a business lead to develop a Data Lake (a repository of raw data) service strategy so that the GC can take advantage of big data and market innovation to foster better analytics and promote horizontal data-sharing.<ref>Treasury Board of Canada Secretariat. (March 29th, 2019). Digital Operations Strategic Plan: 2018-2022. Government of Canada. Treasury Board of Canada Secretariat. Retrieved 26-May-2019 from: <i>[https://www.canada.ca/en/government/system/digital-government/digital-operations-strategic-plan-2018-2022.html] </i></ref> </p> |
− | <p class="expand mw-collapsible-content">However, the inception of containers into the market has shown that large-scale organizations, who are involved in cloud-native application development as well as networking, can benefit greatly from the use of containers <ref>CENGN. (2018). CENGN and CloudOps Collaborate to Train Industry on Docker and Kubernetes<i>[Available at: https://www.cengn.ca/docker-kubernetes-training-jan18/]</i></ref>. Although the infrastructure applications providing cloud services can be based solely on Virtual Machines (VMs), the maintenance costs associated with running different operating systems on individual VMs outweighs the benefit <ref>Heron, P. (2018). Experimenting with containerised infrastructure for GOV.UK - Inside GOV.UK. [online] Insidegovuk.blog.gov.uk<i>[https://insidegovuk.blog.gov.uk/2017/09/15/experimenting-with-containerised-infrastructure-for-gov-uk/ ]</i></ref>. Containers and Containerization is a replacement and/or complimentary architecture for VMs. As the GC moves toward cloud services and development of cloud-native applications, the use of containers and orchestrating them with Kubernetes can become an integral part the GC IT architecture. </p> | + | <p class="expand mw-collapsible-content">Big data is the technology that stores and processes data and information in datasets that are so large or complex that traditional data processing applications can’t analyze them. Big data can make available almost limitless amounts of information, improving data-driven decision-making and expanding open data initiatives. Business intelligence involves creating, aggregating, analyzing and visualizing data to inform and facilitate business management and strategy. TBS, working with departments, will lead the development of requirements for an enterprise analytics platform.<ref>Ibid.<i></i></ref></p> |
− | | + | <p>Data Lake development in the GC is a more recent initiative. This is mainly due to the GC focussing resources on the implementation of cloud initiatives. However, there are some GC departments engaged in developing Data Lake environments in tandem to cloud initiatives.</p> |
| + | <p class="expand mw-collapsible-content">Notably, the Employment and Social Development Canada (ESDC) is preparing the installment of multiple Data Lakes in order to enable a Data Lake Ecosystem and Data Analytics and Machine Learning toolset. This will enable ESDC to share information horizontally both effectively and safely, while enabling a wide variety of data analytics capabilities. ESDC aims to maintain current data and analytics capabilities up-to-date while exploring new ones to mitigate gaps and continuously evolve our services to meet client’s needs.<ref>Brisson, Yannick, and Craig, Sheila. (November, 2018). ESDC Data Lake – Implementation Strategy and Roadmap Update. Government of Canada. Employment and Social Development Canada – Data and Analytics Services. Presentation. Last Modified on 2019-04-26 15:45. Retrieved 07-May-2019 from GCDocs<i>[https://gcdocs.gc.ca/ssc-spc/llisapi.dll?func=ll&objaction=overview&objid=36624914 ]</i></ref> </p> |
| <h2>Implications for Government Agencies</h2> | | <h2>Implications for Government Agencies</h2> |
| <h3>Shared Services Canada (SSC)</h3> | | <h3>Shared Services Canada (SSC)</h3> |
| <h4>Value Proposition</h4> | | <h4>Value Proposition</h4> |
− | <p>The primary business value impact of Kubernetes is the technology’s portability, and mobility independent of the environment. Its ability to manage, and orchestrate an organization’s application containers is a marked benefit. Kubernetes secondary business value is that it enables enterprise high-velocity, meaning that every product team can safely ship updates many times a day, deploy instantly, observe results in real time, and use this feedback to roll containers forward or back with the goal to improve the customer experience as fast as possible<ref>Jayanandana, Nilesh. (May 2nd, 2018). Benefits of Kubernetes. Medium Newspaper. Retrieved 16-May-2019 from: <i>[https://medium.com/platformer-blog/benefits-of-kubernetes-e6d5de39bc48]</i></ref>. </p> | + | <p class="expand mw-collapsible-content">There are three common value propositions for pursuing Data Lakes. 1) It can provide an easy and accessible way to obtain data faster; 2) It can create a singular inflow point of data to help connect and merge information silos in an organization; and 3) It can provide an experimental environment for experienced data scientists to enable new analytical insights.</p> |
− | <p>In the age of modern web services, users expect their applications to be available 24/7, and developers expect the ability to deploy new versions of those applications several times a day with minimal downtime. Containers have become one of the main ways in which to manage applications across enterprise IT infrastructure and also one of the most difficult areas to manage effectively.</p> | + | <p class="inline-spacer"> </p> |
− | <p>Kubernetes, as an open source system, is a technology that can administer and manage a large number of containerized applications spread across clusters of servers while providing basic mechanisms for deployment, maintenance, and scaling of applications<ref>GitHub. (2019). Production-Grade Container Scheduling and Management. GitHub. 2019. Retrieved 16-May-2019 from: <i>[https://github.com/kubernetes/kubernetes ]</i></ref>. An application container is a standard unit of software that packages code and all its dependencies so the application runs quickly and reliably from one computing environment to another<ref>Docker. (2019). What is a Container? A Standardized Unit of Software. Docker Inc. 2019.Retrieved 16-May-2019 from: <i>[https://www.docker.com/resources/what-container ]</i></ref>. Kubernetes automates the distribution and scheduling of application containers across a cluster in a more efficient way<ref>Kubernetes. (2019). Using Minikube to Create a Cluster. Kubernetes. 2019. ICP license: 京ICP备17074266号-3. Retrieved 16-May-2019 from: <i>[https://kubernetes.io/docs/tutorials/kubernetes-basics/create-cluster/cluster-intro/ ]</i></ref>. </p>
| + | <p class="inline">Data Lakes can provide data to consumers more quickly by offering data in a more raw and easily accessible form. Data is stored in its native form with little to no processing, it is optimized to store vast amounts of data in their native formats. By allowing the data to remain in its native format, a much timelier stream of data is available for unlimited queries and analysis. A Data Lake can help data consumers bypass strict data retrieval and data structured applications such as a data warehouse and/or data mart. This has the effect of improving a business’ data flexibility.</p><p class="expand inline mw-collapsible-content">Some companies have in fact used Data Lakes to replace existing warehousing environments where implementing a new data warehouse is more cost prohibitive. A Data Lake can contain unrefined data, this is helpful when either a business data structure is unknown, or when a data consumer requires access to the data quickly. </p> |
− | <p>Containers offer a logical packaging mechanism in which applications can be abstracted from the environment in which they actually run. This decoupling allows container-based applications to be deployed easily and consistently, regardless of whether the target environment is a private data center, the public cloud, or even a developer’s personal laptop<ref><i>[https://cloud.google.com/containers/ ]</i></ref>. An additional benefit to containerization is that the Operating System (OS) is not running as hard. </p>
| + | <p class="inline-spacer"> </p> |
− | <p class="inline">Since Kubernetes is open source, it allows the enterprise freedom to take advantage of on-premises, hybrid, or public cloud infrastructure, and the ability to effortlessly move workloads<ref>Kubernetes. (2019). Production-Grade Container Orchestration. Kubernetes. 2019. ICP license: 京ICP备17074266号-3. Retrieved 16-May-2019 from: <i>[https://kubernetes.io/ ]</i></ref>. Containerized applications are more flexible and available than in past deployment models, where applications were installed directly onto specific machines as packages deeply integrated into the host. Kubernetes groups containers that make up an application into logical units for easy management and discovery. </p><p class="expand inline mw-collapsible-content">The abstractions in Kubernetes allows deployment of containerized applications to a cluster without tying them specifically to individual machines (i.e. Virtual Machines). Applications can be co-located on the same machines without impacting each other. This means that tasks from multiple users can be packed onto fewer machines. This provides greater efficiency and reduces the cost on hardware as less machines are used. </p>
| + | <p class="inline">A Data Lake is not a single source of truth. A Data Lake is a central location in which data converges from all data sources and is stored, regardless of the data formatting. </p><p class="expand inline mw-collapsible-content">As a singular point for the inflow of data, sections of a business can pool their information together in the Data Lake and increase the sharing of information with other parts of the organization. In this way everyone in the organization has access to the data. A Data Lake can increase the horizontal data sharing within an organization by creating this singular data inflow point. Using a variety of storage and processing tools analysts can extract data value quickly in order to inform key business decisions.</p> |
− | <p>Kubernetes contains tools for orchestration, secrets management, service discovery, scaling and load balancing and includes automatic bin packing to place containers with the optimal resources, and it applies configurations via configuration management features<ref>Rouse, Margaret, et al. (August 2017). Kubernetes. TechTarget Inc. 2019. Retrieved 16-May-2019 from: <i>[https://searchitoperations.techtarget.com/definition/Google-Kubernetes ]</i></ref>. It protects container workloads by rolling out or rolling back changes and offers availability and quality checks for containers -- replacing or restarting failed containers. As requirements change, a user can move container workloads in Kubernetes from one cloud provider or hosting infrastructure to another without changing the code<ref>Rouse, Margaret, et al. (August 2017). Kubernetes. TechTarget Inc. 2019. Retrieved 16-May-2019 from: <i>[https://searchitoperations.techtarget.com/definition/Google-Kubernetes]</i></ref>. This is a great value to developers as their work is protected and an audit trail of changes is available.</p>
| + | <p class="inline-spacer"> </p> |
− | <p class="expand mw-collapsible-content">The core concepts of Kubernetes which enables high velocity are immutability, declarative configuration and self-healing systems<ref>Jayanandana, Nilesh. (May 2nd, 2018). Benefits of Kubernetes. Medium Newspaper. Retrieved 16-May-2019 from: <i>[https://medium.com/platformer-blog/benefits-of-kubernetes-e6d5de39bc48]</i></ref>. </p> | + | <p class="expand inline mw-collapsible-content">A Data Lake is optimized for exploration and provides an experimental environment for experienced data scientists to uncover new insights from data. Analysts can overlay context on the data to extract value. All organizations want to increase analytics and operational agility.</p><p class="inline">The Data Lake architectural approach can store large volumes of data, this can be a way in which cross-cutting teams can pool their data in a central location and by complementing their systems of record with systems of insight. </p><p class="expand inline mw-collapsible-content">Data Lakes present the most potential benefits for experienced and competant data scientists. </p><p class="inline">Having structured, unstructured and semistructured data, usually in the same data set, can contain business, predictive, and prescriptive insights previously not possible from a structured platform as observed in data warehouses and data marts.</p> |
− | <p>Containers and Kubernetes encourage developers to build distributed systems that adhere to the principles of immutable infrastructure. In immutable infrastructure an artifact created, will not be changed upon user modifications. To update applications in an immutable infrastructure, a new container image is built with a new tag, and is deployed, terminating the old container with the old image version. In this way, the enterprise always has an artifact record of what was done and if there was an error in the new image. If an error is detected the container is rolled back to the previous image<ref>Jayanandana, Nilesh. (May 2nd, 2018). Benefits of Kubernetes. Medium Newspaper. Retrieved 16-May-2019 from: <i>[https://medium.com/platformer-blog/benefits-of-kubernetes-e6d5de39bc48]</i></ref>. Anything that goes into a container has a text file. Text files can be treated like application source code and provisions immutability.</p>
| + | |
− | <p class="expand mw-collapsible-content">Declarative configuration enables the user to describe exactly what state the system should be in. Traditional tools of development such as source control, unit tests etc. can be used with declarative configurations in ways that are impossible with imperative configurations. Imperative systems describe how to get from point A to B, but rarely include reverse instructions to get back. Kubernetes declarative configuration makes rollbacks fairly easy which is impossible with imperative configurations<ref>Jayanandana, Nilesh. (May 2nd, 2018). Benefits of Kubernetes. Medium Newspaper. Retrieved 16-May-2019 from: <i>[https://medium.com/platformer-blog/benefits-of-kubernetes-e6d5de39bc48]</i></ref>. </p>
| |
− | <p class="expand mw-collapsible-content">Lastly, Kubernetes has a means of self-healing. When Kubernetes receives a desired state configuration, it does not simply take actions to make the current state match the desired state at a single time, but it will continuously take actions to ensure it stays that way as time passes by<ref>Jayanandana, Nilesh. (May 2nd, 2018). Benefits of Kubernetes. Medium Newspaper. Retrieved 16-May-2019 from: <i>[https://medium.com/platformer-blog/benefits-of-kubernetes-e6d5de39bc48]</i></ref>. </p>
| |
| <h4>Challenges</h4> | | <h4>Challenges</h4> |
− | <p>The greatest challenge in regards to Kubernetes is its complexity. However, security, storage and networking, maturity, and competing enterprise transformation priorities are also challenges facing the Kubernetes technology.</p><br><b>Kubernetes Complexity and Analyst Experience</b> | + | <p>Although Data Lake technology has many benefits for organizations dealing with big data it has its own challenges. For example:</p> |
− | <p>There is the challenge of a lack of organizational and analyst experience with container management and in using Kubernetes. Managing, updating, and changing a Kubernetes cluster can be operationally complex, more so if the analysts have a lack of experience. The system itself does provide a solid base of infrastructure for a Platform as a Service (PaaS) framework, which can reduce the complexity for developers. However, testing within a Kubernetes environment is still a complex task. Although its use cases in testing are well noted, testing several moving parts of an infrastructure to determine proper application functionality is still a more difficult endeavour <ref>Clayton, T. and Watson, R. (2018). Using Kubernetes to Orchestrate Container-Based Cloud and Microservices Applications. [online] Gartner.com. Available at: <i>[https://www.gartner.com/doc/3873073/using-kubernetes-orchestrate-containerbased-cloud]</i></ref>. This means a lot of new learning will be needed for operations teams developing and managing Kubernetes infrastructure. The larger the company, the more likely the Kubernetes user is to face container challenges<ref>Williams, Alex, et al. Kubernetes Deployment & Security Patterns. The New Stack. 2019. 20180622. thenewstack.io. Retrieved 15-May-2019 from: <i>[https://thenewstack.io/ebooks/kubernetes/kubernetes-deployment-and-security-patterns/]</i></ref>. </p><br><b>Security</b> | + | <p><b><u>Data Governance and Semantic Issues</u></b></p> |
− | <p>In a distributed, highly scalable environment, traditional and typical security patterns will not cover all threats. Security will have to be aligned for containers and in the context of Kubernetes. It is critical for operations teams to understand Kubernetes security in terms of containers, deployment, and network security. Security perimeters are porous, containers must be secured at the node level, but also through the image and registry. Security practices in the context of various deployment models will be a persistent challenge<ref>Williams, Alex, et al. Kubernetes Deployment & Security Patterns. The New Stack. 2019. 20180622. thenewstack.io. Retrieved 15-May-2019 from: <i>[https://thenewstack.io/ebooks/kubernetes/kubernetes-deployment-and-security-patterns/]</i></ref>. </p><br><b>Storage & Networking</b> | + | <p class="expand inline mw-collapsible-content">The biggest challenge for Data Lakes is to resolve assorted data governance requirements in a single centralized data platform. Data Lakes fail mostly when they lack governance, self-disciplined users, and a rational data flow.</p><p class="inline">Often, Data Lake implementations are focused on storing data instead of managing the data. Data Lakes are not optimized for semantic enforcement or consistency. They are made for semantic flexibility, to allow anyone to provide context to data if they have the skills to do so. </p> |
− | <p>Storage and networking technologies are pillars of data center infrastructure, but were designed originally for client/server and virtualized environments. Container technologies are leading companies to rethink how storage and networking technologies function and operate<ref>Williams, Alex, et al. Kubernetes Deployment & Security Patterns. The New Stack. 2019. 20180622. thenewstack.io. Retrieved 15-May-2019 from: <i>[https://thenewstack.io/ebooks/kubernetes/kubernetes-deployment-and-security-patterns/]</i></ref>. Architectures are becoming more application-oriented and storage does not necessarily live on the same machine as the application or its services. Larger companies tend to run more containers, and to do so in scaled-out production environments requires new approaches to infrastructure<ref>Williams, Alex, et al. Kubernetes Deployment & Security Patterns. The New Stack. 2019. 20180622. thenewstack.io. Retrieved 15-May-2019 from: <i>[https://thenewstack.io/ebooks/kubernetes/kubernetes-deployment-and-security-patterns/]</i></ref>. </p> | + | <p>Putting data in the same place does not remove it’s ambiguity or meaning. Data Lakes provide unconstrained, “no compromises” storage model environment without the data governance assurances common to data warehouses or data marts. Proper meta data is essential for a Data Lake, without appropriate meta data the Data Lake will not work as intended. It is beneficial to think of meta data as the fish finder in the Data Lake.</p> |
− | <p>Some legacy systems can run containers and only sometimes can VMs can be replaced by containers. There may be significant engineering consequences to existing legacy systems if containerization and Kubernetes is implemented in a legacy system not designed to handle that change. Some Legacy systems may require refactoring and making it more suitable for containerization. Some pieces of a system may be able to be broken off and containerized. In general, anything facing the internet should be run in containers.</p><br><b>Maturity</b> | + | <p><b class="expand mw-collapsible-content"><u>Lack of Quality and Trust in Data</u></b></p> |
− | <p>Kubernetes maturity as a technology is still being tested by organizations. For now, Kubernetes is the market leader and the standardized means of orchestrating containers and deploying distributed applications. Google is the primary commercial organization behind Kubernetes; however they do not support Kubernetes as a software product. It offers a commercial managed Kubernetes service known as GKE but not as a software. This can be viewed as both a strength and a weakness. Without commercialization, the user is granted more flexibility with how Kubernetes can be implemented in their infrastructure; However, without a concrete set of standards of the services that Kubernetes can offer, there is a risk that Google’s continuous support cannot be guaranteed. Its donation of Kubernetes code and intellectual property to the Cloud Native Computing Foundation does minimize this risk since there is still an organization enforcing the proper standards and verifying services Kubernetes can offer moving forward <ref>Clayton, T. and Watson, R. (2018). Using Kubernetes to Orchestrate Container-Based Cloud and Microservices Applications. [online] Gartner.com. Available at: <i>[https://www.gartner.com/doc/3873073/using-kubernetes-orchestrate-containerbased-cloud]</i></ref>. It is also important to note that the organizational challenges that Kubernetes users face have been more dependent on the size of the organization using it.</p> | + | <p class="expand mw-collapsible-content">Data quality and trust in the data is a perennial issue for many organizations. Although data discovery tools can apply Machine Learning across related datasets from multiple data sources to identify anomalies (incorrect values, missing values, duplicates and outdated data), quality and trustworthiness of data continue to be an issue for Data Lakes who can easily become data dumping grounds. Some data is more accurate than others. This can present a real problem for anyone using multiple data sets and making decisions based upon analysis conducted with data of varying degrees of quality.</p> |
− | <p>Kubernetes faces competition from other scheduler and orchestrator technologies, such as Docker Swarm and Mesosphere DC/OS. While Kubernetes is sometimes used to manage Docker containers, it also competes with the native clustering capabilities of Docker Swarm<ref>Rouse, Margaret, et al. (August 2017). Kubernetes. TechTarget Inc. 2019. Retrieved 16-May-2019 from: <i>[https://searchitoperations.techtarget.com/definition/Google-Kubernetes]</i></ref>. However, Kubernetes can be run on a public cloud service or on-premises, is highly modular, open source, and has a vibrant community. Companies of all sizes are investing into it, and many cloud providers offer Kubernetes as a service<ref>Tsang, Daisy. (February 12th, 2018). Kubernetes vs. Docker: What Does It Really Mean? Sumo Logic. 2019. Retrieved 16-May-2019 from: <i>[https://www.sumologic.com/blog/kubernetes-vs-docker/ ]</i></ref>. </p><br><b class="expand mw-collapsible-content">Competing Enterprise Transformation Priorities</b> | + | <p><b><u>Data Swamps, Performance, and Flexibility Challenges</u></b></p> |
− | <p class="expand mw-collapsible-content">The last challenge facing Kubernetes initiative development and implementation is its place in an organization’s IT transformation priority list. Often there are many higher priority initiatives that can take president over Kubernetes projects.</p>
| + | <p class="expand inline mw-collapsible-content">Data stored in Data Lakes can sometimes become muddy when good data is mixed with bad data. Data Lake infrastructure is meant to store and process large amounts of data, usually in massive data files. </p><p class="inline">A Data Lake is not optimized for a high number of users or diverse and simultaneous workloads due to intensive query tasks. This can result in performance degradation and failures are common when running extractions, transformations, and loading tasks all at the same time. On-premises Data Lakes face other performance challenges in that they have a static configuration. </p> |
− | | + | <p><b class="expand mw-collapsible-content"><u>Data Hoarding and Storage Capacity</u></b></p> |
− | | + | <p class="expand mw-collapsible-content">Data stored in Data Lakes may actually never be used in production and stay unused indefinitely in the Data Lake. By storing massive amounts of historical data, the infinite Data Lake may skew analysis with data that is no longer relevant to the priorities of the business. In keeping the historical data the metadata describing it must be understood as well. This decreases the performance of the Data Lake by increasing the overall workload of employees to clean the datasets no longer in use for analysis.</p> |
| + | <p class="expand mw-collapsible-content">Storing increasingly massive amounts of data for an unlimited time will also lead to scalability and cost challenges. Scalability challenges are less of a risk in public cloud environments, but cost remains a factor. On-premises Data Lakes are more susceptible to cost challenges. This is because their cluster nodes require all three dimensions of computing (storage, memory and processing). Organizations of all kinds generate massive amounts of data (including meta data) and it is increasing exponentially.</p> |
| + | <p>The storage capacity of all this data (and future data) will be an ongoing challenge and one that will require constant management. While Data Lakes can and will be stored on the cloud, SSC as cloud broker for the GC will need to provide the appropriate infrastructure and scalability to clients.</p> |
| + | <p><b class="expand mw-collapsible-content"><u>Advanced Users Required</u></b></p> |
| + | <p class="expand mw-collapsible-content">Data Lakes are not a platform to be explored by everyone. Data Lakes present an unrefined view of data that usually only the most highly skilled analysts are able to explore and engage in data refinement independent of any other formal system-of-record such as a data warehouse. </p> |
| + | <p class="expand mw-collapsible-content">Not just anyone in an organization is data-literate enough to derive value from large amounts of raw or uncurated data. The reality is only a handful of staff are skilled enough to navigate a Data Lake. Since Data Lakes store raw data their business value is entirely determined by the skills of Data Lake users. These skills are often lacking in an organization.</p> |
| + | <p><b><u>Data Security</u></b></p> |
| + | <p class="inline"></p>Data in a Data Lake lacks standard security protection with a relational database management system or an enterprise database. In practice, this means that the data is unencrypted and lacks access control.<p class="expand inline mw-collapsible-content">. Security is not just a binary solution. We have varying degrees of security (unclassified, secret, top secret, etc.) and all of which require different approaches. This will inevitably present challenges with the successful use of data from Data Lakes.To combat this, organizations will have to embrace a new security framework to be compatable with Data Lakes and Data Scientists.</p> |
| <h4>Considerations</h4> | | <h4>Considerations</h4> |
− | <b>Strategic Resourcing and Network Planning</b> | + | <p class="expand mw-collapsible-content">Shared Services Canada (SSC) has an excellent opportunity to capitalize on its mandate of providing data storage service to GC’s other departments. SSC, as the GC’s Service Provider, could potentially a centralized GC Data Lake and allow GC Data Scientists access to this central data using a single unified Data Lake interface. However, this is a project which should be implemented after cloud has been adopted and enterprise data centers have been migrated to in order to provide adequate infrastructure and scaling.</p> |
− | <p>A strategic approach to Kubernetes investments will need to be developed to ensure opportunities are properly leveraged. The GC invests a significant portion of its annual budget on IT and supporting infrastructure. Without strategic Kubernetes direction the fragmented approaches to IT investments, coupled with rapid developing technology and disjointed business practices, can undermine effective and efficient delivery of GC programs and services<ref>Treasury Board of Canada Secretariat. December 3, 2018. Directive on Management of Information Technology. Treasury Board of Canada Secretariat. Government of Canada. Retrieved 27-Dec-2018 from: <i>[https://www.tbs-sct.gc.ca/pol/doc-eng.aspx?id=15249 ]</i></ref>. A clear vision and mandate for how Kubernetes will transform services, and what the end-state Kubernetes initiative is supposed to look like, is a prominent consideration. </p> | + | <p class="inline">Data Lakes should not be confused for conventional databases although they both store information. A Data Lake will always underperform when tasked with the jobs of a conventional database. </p><p class="expand inline mw-collapsible-content">To combat this, SSC must create data architectures that define the proper application of Data Lakes. Too often, Data Lakes suffer from lack of foresight on what they're supposed to achieve. </p><p class="inline">Creating a Data Lake becomes the goal rather than achieving a strategic objective. </p><p class="expand inline mw-collapsible-content"></p> |
− | <p>SSC should consider defining a network strategy for Kubernetes adoption. Multiple factors should be taken into account, including the amount of resources, funding, and expertise that will be required for the development and experimentation with Kubernetes technologies. Calculation of resource requirements including CPU, memory, storage, etc. at the start of Kubernetes projects is imperative. Considerations include whether or not an in-house Kubernetes solution is required or if a solution can be procured. Other strategy considerations include analyzing different orchestration approaches for different application use cases.</p> | + | <p class="expand mw-collapsible-content">Shared Services Canada (SSC) should consider designing Data Lake infrastructure around Service-Level Agreements (SLA) to keep Data Lake efforts on track. This includes ensuring that SSC has established clear goals for Data Lakes prior to deployment. </p> |
− | <b>Complexity and Skills Gap</b> | + | <p class="expand mw-collapsible-content">SSC should also consider building an expert special group focussed on advanced analytics and experimental data trend discovery in Data Lakes. While the fundamental assumption behind the Data Lake concept is that everyone accessing a Data Lake is moderately to highly skilled at data manipulation and analysis, the reality is most are not. SSC should consider significant investment in training employees necessary skills, such as Data Science, Artificial Intelligence, Machine Learning, or Data Engineering.</p> |
− | <p>Kubernetes is a good technology and the de facto standard for orchestrating containers, and containers are the future of modern software delivery. But it is notoriously complex to manage for enterprise workloads, where Service Level Agreements (SLAs) are critical. The operational pain of managing production-grade Kubernetes is further complicated by the industry-wide talent scarcity and skills gap. Most organizations today struggle to hire Kubernetes experts, and even these “experts” lack advanced Kubernetes experience to ensure smooth operations at scale. SSC will need to be cautious in implementing Kubernetes and having the right staff experienced and comfortable in its use.</p> | + | <p>SSC should be cognisant that there are significant overinflated expectations revolving around Data Lakes. Inflated expectations lead to vague and ambiguous use cases and increased chances of catastrophic failures. As a Service Provider, SSC must be strict in establishing clear goals for Data Lake provision efforts before deployment. SSC, should be wary of attempts to replace strategy development with infrastructure. A Data Lake can be a technology component that supports a data and analytics strategy, but it cannot replace that strategy.</p> |
− | <b>Customization and Integration Still Required</b> | + | <p class="expand mw-collapsible-content">SSC should be concerned with the provision and running of the infrastructure, the departments themselves are responsible for the data they put in the Data Lake. However, as a Service Provider, SSC should monitor the Data Lake with regards to data governance, data lifecycle for data hygiene, and what is happening in the Data Lake overall. Depending on technology, SSC will need to be very clear on how to monitor activities in the Data Lakes it provides to the GC. </p> |
− | <p>Kubernetes technology and ecosystem are evolving rapidly, because of its relatively new state, it is hard to find packaged solutions with complete out-of-the-box support for complex, large-scale enterprise scenarios. As a large and sophisticated enterprise organization, SSC will need to devote significant resources on customization and training. Enterprise Architecture pros will need to focus on the whole architecture of cloud-native applications as well as keep a close watch on technology evolution and industry. </p> | + | <p class="expand mw-collapsible-content">SSC should consider a Data Lake implementation project as a way to introduce or reinvigorate a data management program by positioning data management capabilities as a prerequisite for a |
− | <p>Implementation usually takes longer than expected, however the consensus in the New Stack’s Kubernetes User Experience Survey is that Kubernetes reduces code deployment times, and increases the frequency of those deployments<ref>Williams, Alex, et al. The State of the Kubernetes Ecosystem. The New Stack. thenewstack.io. Retrieved 15-May-2019 from: <i>[https://thenewstack.io/ebooks/kubernetes/state-of-kubernetes-ecosystem/ ]</i></ref>. However, in the short run, the implementation phase does consume more human resources. Additionally, implementation takes longer than expected. The consensus is that Kubernetes reduces code deployment times, and increases the frequency of those deployments. However, in the short run, the implementation phase does consume more human resources.</p> | + | successful Data Lake. Data will need to be qualified before it hits the data lake, this can and should be done in a system of record first. In this way the data can be organizedto fit into the Data Lake implementation. |
− | <b>Pilot Small and Scale Success</b> | + | </p> |
− | <p>SSC may wish to consider evaluating the current Service Catalogue in order to determine where Kubernetes can be leveraged first to improve efficiencies, reduce costs, and reduce administrative burdens of existing services as well as how a new Kubernetes service could be delivered on a consistent basis. Any new procurements of devices or platforms should have high market value and can be on-boarded easily onto the GC network. SSC should avoid applying in-house Kubernetes for production mission-critical apps. Failure of in-house deployments is high and thus should be avoided. SSC should pilot and establish a Kubernetes test cluster. With all new cloud-based technologies, piloting is preferred. Focus should first be on a narrow set of objectives and a single application scenario to stand up a test cluster.</p> | + | <p class="expand mw-collapsible-content">SSC should create policies on how data is managed and cleaned in the Data Lake. Automated data governance technologies should be added to support advanced analytics. Standardizing on a specific type of governance tool is an issue which must be resolved. Additionally, planning for effective metadata management, considering metadata discovery, cataloguing and enterprise metadata management applied to Data Lake implementation is vital. Rigorous application of data discipline and data hygiene is needed. To combat this, SSC should use data management tools and create policies on how data is managed and cleaned in the Data Lake. The majority of Data Lake analysts will prefer to work with clean, enriched, and trusted data. However, data quality is relative to the task at hand. Lowquality data may be acceptable for low-impact analysis or distant forecasting, but unacceptable for tactical or high-impact analysis. SSC assessments should take this into account.</p> |
− | <b>Implement Robust Monitoring, Logging, and Audit Practices and Tools</b>
| + | <p>Design Data Lakes with the elements necessary to deliver reliable analytical results to a variety of data consumers. The goal is to increase cross-business usage in order to deliver advanced analytical insights. Build Data Lakes for specific business units or analytics applications, rather than try to implement some vague notion of a single enterprise Data Lake. However, alternative architectures, like data hubs, are often better fits for sharing data within an organization.</p> |
− | <p>Monitoring provides visibility and detailed metrics of Kubernetes infrastructure. This includes granular metrics on usage and performance across all cloud providers or private data centers, regions, servers, networks, storage, and individual VMs or containers. Improving data center efficiency and utilization on both on-premises and public cloud resources is the goal. Additionally, logging is a complementary function and required capability for effective monitoring is also a goal. Logging ensures that logs at every layer of the architecture are all captured for analysis, troubleshooting and diagnosis. Centralized, distributed, log management and visualization is a key capability<ref>Chemitiganti, Vamsi, and Fray, Peter. (February 20th, 2019). 7 Key Considerations for Kubernetes in Production. The New Stack. 2019. Retrieved 16-May-2019 from: <i>[https://thenewstack.io/7-key-considerations-for-kubernetes-in-production/]</i></ref>. Lastly, routine auditing, no matter the checks and balances put in place, will cover topics that normal monitoring will not cover. Traditionally, auditing is as a manual process, but the automated tooling in the Kubernetes space is quickly improving.</p> | + | <h2>References</h2> |
− | <b>Security</b> | + | <div style="display: none"> |
− | <p>Security is a critical part of cloud native applications and Kubernetes is no exception. Security is a constant throughout the container lifecycle and it is required throughout the design, development, DevOps, and infrastructure choices for container-based applications. A range of technology choices are available to cover various areas such as application-level security and the security of the container and infrastructure itself. Different tools that provide certification and security for what goes inside the container itself (such as image registry, image signing, packaging), Common Vulnerability Exposures/Enumeration (CVE) scans, and more<ref>Chemitiganti, Vamsi, and Fray, Peter. (February 20th, 2019). 7 Key Considerations for Kubernetes in Production. The New Stack. 2019. Retrieved 16-May-2019 from: <i>[https://thenewstack.io/7-key-considerations-for-kubernetes-in-production/]</i></ref>.. SSC will need to ensure appropriate security measures are used with any new Kubernetes initiatives, including the contents of the containers being orchestrated.</p>
| + | <ref>Dennis, A. L. (2018, October 15). Data Lakes 101: An Overview. Retrieved from <i>[https://www.dataversity.net/data-lakes-101-overview/#]</i></ref> |
− | | + | <ref>Marvin, R., Marvin, R., & Marvin, R. (2016, August 22). Data Lakes, Explained. Retrieved from <i>[ https://www.pcmag.com/article/347020/data-lakes-explained]</i></ref> |
− | <h2>References</h2>
| + | <ref>The Data Lake journey. (2014, March 15). Retrieved from <i>[https://hortonworks.com/blog/enterprise-hadoop-journey-data-lake/]</i></ref> |
| + | <ref>Google File System. (2019, July 14). Retrieved from <i>[https://en.wikipedia.org/wiki/Google_File_System]</i></ref> |
| + | <ref>Coates, M. (2016, October 02). Data Lake Use Cases and Planning Considerations. Retrieved from <i>[https://www.sqlchick.com/entries/2016/7/31/data-lake-use-cases-and-planning]</i></ref> |
| + | <ref>Bhalchandra, V. (2018, July 23). Six reasons to think twice about your data lake strategy. Retrieved from <i>[https://dataconomy.com/2018/07/six-reasons-to-think-twice-about-your-data-lake-strategy/]</i></ref> |
| + | <ref>Data Lake Expectations: Why Data Lakes Fail. (2018, September 20). Retrieved from <i>[https://www.arcadiadata.com/blog/the-top-six-reasons-data-lakes-have-failed-to-live-up-to-expectations/]</i></ref> |
| + | <ref>Data Lake: AWS Solutions. (n.d.). Retrieved from <i>[https://aws.amazon.com/solutions/data-lake-solution/]</i></ref> |
| + | </div> |
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July 12, 2019 |
Latest version |
February 17, 2020 |
Official publication |
Datalakes.pdf |
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This page is a work in progress. We welcome your feedback. Please use the discussion page for suggestions and comments. When the page is approved and finalized, we will send it for translation. |
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Datalakes is a central system or repository of data that is stored in its natural/raw format. A datalake acts as a single store for all enterprise data. Data is transformed using machine learning, advanced,analytics, and visualization. Several forms of data can be hosed in a datalake. These include structured data from relational databases, unstructured data, semi-structured data, and binary data.
Business Brief
In an ever-increasing hyperconnected world, corporations and businesses are struggling to deal with the responsibilities of storage, management and quick availability of raw data. To break these data challenges down further:
- Data comes in many different structures.
- Unstructured
- Semi-Sturctured
- Structured
- Data comes from many disparate sources.
- Enterprise Applications
- Raw Files
- Operation and Security Logs
- Financial Transactions
- Internet of Things (IoT) Devices and Network Sensors
- Websites
- Scientific Research
- Data sources are often geographically distributed to multiple locations
- Datacenters
- Remote Offices
- Mobile Devices
In an effort to resolve these data challenges, a new way of managing data was created which drove data oriented companies to invent a new data storage mechanism called a Data Lake.
Data Lakes are characterized as:
- Collect Everything
- A Data Lake contains all data; raw sources over extended periods of time as well as any processed data.
- Dive in anywhere
- A Data Lake enables users across multiple business units to refine, explore and enrich data on their terms.
- Flexible Access
- o A Data Lake enables multiple data access patterns across a shared infrastructure: batch, interactive, online, search, in-memory and other processing engines.
Data Lakes are essentially a technology platform for holding data. Their value to the business is only realized when applying data science skills to the lake.
To summarize, usecases for Data Lakes are still being discovered. Cloud providers are making it easier to procure Data Lakes and today Data Lakes are primarily used by Research Institutions, Financial Services, Telecom, Media, Retail, Manufacturing, Healthcare, Pharma, Oi l& Gas and Governments.
Technology Brief
The most popular implementation of a Data Lake is through the open source platform called Apache Hadoop. Apache Hadoop is a collection of open-source software utilities that facilitates using a network of many computers to solve problems involving massive amounts of data and computation. Hadoop was originally created by researchers at Google as a storage method to handle the indexing of websites on the Internet; At that time it was called the Google File System.
A Data Lake is a centralized repository that allows you to store all your structured and unstructured data at any scale. You can store your data as-is, without having to first structure the data, and run different types of analytics—from dashboards and visualizations to big data processing, real-time analytics, and machine learning to guide better decisions.”
Data can flow into the Data Lake by either batch processing or real-time processing of streaming data. Additionally, data itself is no longer restrained by initial schema decisions and can be exploited more freely by the enterprise. Rising above this repository is a set of capabilities that allow IT to provide Data and Analytics as a Service (DAaaS), in a supply-demand model. IT takes the role of the data provider (supplier), while business users (data scientists, business analysts) are consumers.
The DAaaS model enables users to self-serve their data and analytic needs. Users browse the lake’s data catalog (a Datapedia) to find and select the available data and fill a metaphorical “shopping cart” (effectively an analytics sandbox) with data to work with. Once access is provisioned, users can use the analytics tools of their choice to develop models and gain insights. Subsequently, users can publish analytical models or push refined or transformed data back into the Data Lake to share with the larger community.
Although provisioning an analytic sandbox is a primary use, the Data Lake also has other applications. For example, the Data Lake can also be used to ingest raw data, curate the data, and apply Export-Transform-Load (ETL). This data can then be loaded to an Enterprise Data Warehouse. To take advantage of the flexibility provided by the Data Lake, organizations need to customize and configure the Data Lake to their specific requirements and domains.
Industry Usage
There are a variety of ways Data Lakes are being used in the industry:
Ingestion of semi-structured and unstructured data sources (aka big data)such as equipment readings, telemetry data, logs, streaming data, and so forth. A Data Lake is a great solution for storing IoT (Internet of Things) type of data which has traditionally been more difficult to store, and can support near real-time analysis. Optionally, you can also add structured data (i.e., extracted from a relational data source) to a Data Lake if your objective is a single repository of all data to be available via the lake.
Experimental analysis of data before its value or purpose has been fully defined. Agility is important for every business these days, so a Data Lake can play an important role in "proof of value" type of situations because of the "ELT" approach discussed above.
Advanced analytics support. A Data Lake is useful for data scientists and analysts to provision and experiment with data.
Archival and historical data storage. Sometimes data is used infrequently, but does need to be available for analysis. A Data Lake strategy can be very valuable to support an active archive strategy.
Distributed processing capabilities associated with a logical data warehouse.
How TD Bank Made Its Data Lake More Usa
Toronto-Dominion Bank (TD Bank) is one of the largest banks in North America, with 85,000 employees, more than 2,400 locations between Canada and the United States, and assets nearing $1 trillion. In 2014, the company decided to standardize how it warehouses data for various business intelligence and regulatory reporting functions. The company purchased a Hadoop distribution and set off to build a large cluster that could function as a centralized lake to store data originating from a variety of departments.
Canadian Government Use
In 2019, the Treasury Board of Canada Secretariat (TBS), partnered with Shared Services Canada and other departments, to identify a business lead to develop a Data Lake (a repository of raw data) service strategy so that the GC can take advantage of big data and market innovation to foster better analytics and promote horizontal data-sharing.[1]
Big data is the technology that stores and processes data and information in datasets that are so large or complex that traditional data processing applications can’t analyze them. Big data can make available almost limitless amounts of information, improving data-driven decision-making and expanding open data initiatives. Business intelligence involves creating, aggregating, analyzing and visualizing data to inform and facilitate business management and strategy. TBS, working with departments, will lead the development of requirements for an enterprise analytics platform.[2]
Data Lake development in the GC is a more recent initiative. This is mainly due to the GC focussing resources on the implementation of cloud initiatives. However, there are some GC departments engaged in developing Data Lake environments in tandem to cloud initiatives.
Notably, the Employment and Social Development Canada (ESDC) is preparing the installment of multiple Data Lakes in order to enable a Data Lake Ecosystem and Data Analytics and Machine Learning toolset. This will enable ESDC to share information horizontally both effectively and safely, while enabling a wide variety of data analytics capabilities. ESDC aims to maintain current data and analytics capabilities up-to-date while exploring new ones to mitigate gaps and continuously evolve our services to meet client’s needs.[3]
Implications for Government Agencies
Shared Services Canada (SSC)
Value Proposition
There are three common value propositions for pursuing Data Lakes. 1) It can provide an easy and accessible way to obtain data faster; 2) It can create a singular inflow point of data to help connect and merge information silos in an organization; and 3) It can provide an experimental environment for experienced data scientists to enable new analytical insights.
Data Lakes can provide data to consumers more quickly by offering data in a more raw and easily accessible form. Data is stored in its native form with little to no processing, it is optimized to store vast amounts of data in their native formats. By allowing the data to remain in its native format, a much timelier stream of data is available for unlimited queries and analysis. A Data Lake can help data consumers bypass strict data retrieval and data structured applications such as a data warehouse and/or data mart. This has the effect of improving a business’ data flexibility.
Some companies have in fact used Data Lakes to replace existing warehousing environments where implementing a new data warehouse is more cost prohibitive. A Data Lake can contain unrefined data, this is helpful when either a business data structure is unknown, or when a data consumer requires access to the data quickly.
A Data Lake is not a single source of truth. A Data Lake is a central location in which data converges from all data sources and is stored, regardless of the data formatting.
As a singular point for the inflow of data, sections of a business can pool their information together in the Data Lake and increase the sharing of information with other parts of the organization. In this way everyone in the organization has access to the data. A Data Lake can increase the horizontal data sharing within an organization by creating this singular data inflow point. Using a variety of storage and processing tools analysts can extract data value quickly in order to inform key business decisions.
A Data Lake is optimized for exploration and provides an experimental environment for experienced data scientists to uncover new insights from data. Analysts can overlay context on the data to extract value. All organizations want to increase analytics and operational agility.
The Data Lake architectural approach can store large volumes of data, this can be a way in which cross-cutting teams can pool their data in a central location and by complementing their systems of record with systems of insight.
Data Lakes present the most potential benefits for experienced and competant data scientists.
Having structured, unstructured and semistructured data, usually in the same data set, can contain business, predictive, and prescriptive insights previously not possible from a structured platform as observed in data warehouses and data marts.
Challenges
Although Data Lake technology has many benefits for organizations dealing with big data it has its own challenges. For example:
Data Governance and Semantic Issues
The biggest challenge for Data Lakes is to resolve assorted data governance requirements in a single centralized data platform. Data Lakes fail mostly when they lack governance, self-disciplined users, and a rational data flow.
Often, Data Lake implementations are focused on storing data instead of managing the data. Data Lakes are not optimized for semantic enforcement or consistency. They are made for semantic flexibility, to allow anyone to provide context to data if they have the skills to do so.
Putting data in the same place does not remove it’s ambiguity or meaning. Data Lakes provide unconstrained, “no compromises” storage model environment without the data governance assurances common to data warehouses or data marts. Proper meta data is essential for a Data Lake, without appropriate meta data the Data Lake will not work as intended. It is beneficial to think of meta data as the fish finder in the Data Lake.
Lack of Quality and Trust in Data
Data quality and trust in the data is a perennial issue for many organizations. Although data discovery tools can apply Machine Learning across related datasets from multiple data sources to identify anomalies (incorrect values, missing values, duplicates and outdated data), quality and trustworthiness of data continue to be an issue for Data Lakes who can easily become data dumping grounds. Some data is more accurate than others. This can present a real problem for anyone using multiple data sets and making decisions based upon analysis conducted with data of varying degrees of quality.
Data Swamps, Performance, and Flexibility Challenges
Data stored in Data Lakes can sometimes become muddy when good data is mixed with bad data. Data Lake infrastructure is meant to store and process large amounts of data, usually in massive data files.
A Data Lake is not optimized for a high number of users or diverse and simultaneous workloads due to intensive query tasks. This can result in performance degradation and failures are common when running extractions, transformations, and loading tasks all at the same time. On-premises Data Lakes face other performance challenges in that they have a static configuration.
Data Hoarding and Storage Capacity
Data stored in Data Lakes may actually never be used in production and stay unused indefinitely in the Data Lake. By storing massive amounts of historical data, the infinite Data Lake may skew analysis with data that is no longer relevant to the priorities of the business. In keeping the historical data the metadata describing it must be understood as well. This decreases the performance of the Data Lake by increasing the overall workload of employees to clean the datasets no longer in use for analysis.
Storing increasingly massive amounts of data for an unlimited time will also lead to scalability and cost challenges. Scalability challenges are less of a risk in public cloud environments, but cost remains a factor. On-premises Data Lakes are more susceptible to cost challenges. This is because their cluster nodes require all three dimensions of computing (storage, memory and processing). Organizations of all kinds generate massive amounts of data (including meta data) and it is increasing exponentially.
The storage capacity of all this data (and future data) will be an ongoing challenge and one that will require constant management. While Data Lakes can and will be stored on the cloud, SSC as cloud broker for the GC will need to provide the appropriate infrastructure and scalability to clients.
Advanced Users Required
Data Lakes are not a platform to be explored by everyone. Data Lakes present an unrefined view of data that usually only the most highly skilled analysts are able to explore and engage in data refinement independent of any other formal system-of-record such as a data warehouse.
Not just anyone in an organization is data-literate enough to derive value from large amounts of raw or uncurated data. The reality is only a handful of staff are skilled enough to navigate a Data Lake. Since Data Lakes store raw data their business value is entirely determined by the skills of Data Lake users. These skills are often lacking in an organization.
Data Security
Data in a Data Lake lacks standard security protection with a relational database management system or an enterprise database. In practice, this means that the data is unencrypted and lacks access control.
. Security is not just a binary solution. We have varying degrees of security (unclassified, secret, top secret, etc.) and all of which require different approaches. This will inevitably present challenges with the successful use of data from Data Lakes.To combat this, organizations will have to embrace a new security framework to be compatable with Data Lakes and Data Scientists.
Considerations
Shared Services Canada (SSC) has an excellent opportunity to capitalize on its mandate of providing data storage service to GC’s other departments. SSC, as the GC’s Service Provider, could potentially a centralized GC Data Lake and allow GC Data Scientists access to this central data using a single unified Data Lake interface. However, this is a project which should be implemented after cloud has been adopted and enterprise data centers have been migrated to in order to provide adequate infrastructure and scaling.
Data Lakes should not be confused for conventional databases although they both store information. A Data Lake will always underperform when tasked with the jobs of a conventional database.
To combat this, SSC must create data architectures that define the proper application of Data Lakes. Too often, Data Lakes suffer from lack of foresight on what they're supposed to achieve.
Creating a Data Lake becomes the goal rather than achieving a strategic objective.
Shared Services Canada (SSC) should consider designing Data Lake infrastructure around Service-Level Agreements (SLA) to keep Data Lake efforts on track. This includes ensuring that SSC has established clear goals for Data Lakes prior to deployment.
SSC should also consider building an expert special group focussed on advanced analytics and experimental data trend discovery in Data Lakes. While the fundamental assumption behind the Data Lake concept is that everyone accessing a Data Lake is moderately to highly skilled at data manipulation and analysis, the reality is most are not. SSC should consider significant investment in training employees necessary skills, such as Data Science, Artificial Intelligence, Machine Learning, or Data Engineering.
SSC should be cognisant that there are significant overinflated expectations revolving around Data Lakes. Inflated expectations lead to vague and ambiguous use cases and increased chances of catastrophic failures. As a Service Provider, SSC must be strict in establishing clear goals for Data Lake provision efforts before deployment. SSC, should be wary of attempts to replace strategy development with infrastructure. A Data Lake can be a technology component that supports a data and analytics strategy, but it cannot replace that strategy.
SSC should be concerned with the provision and running of the infrastructure, the departments themselves are responsible for the data they put in the Data Lake. However, as a Service Provider, SSC should monitor the Data Lake with regards to data governance, data lifecycle for data hygiene, and what is happening in the Data Lake overall. Depending on technology, SSC will need to be very clear on how to monitor activities in the Data Lakes it provides to the GC.
SSC should consider a Data Lake implementation project as a way to introduce or reinvigorate a data management program by positioning data management capabilities as a prerequisite for a
successful Data Lake. Data will need to be qualified before it hits the data lake, this can and should be done in a system of record first. In this way the data can be organizedto fit into the Data Lake implementation.
SSC should create policies on how data is managed and cleaned in the Data Lake. Automated data governance technologies should be added to support advanced analytics. Standardizing on a specific type of governance tool is an issue which must be resolved. Additionally, planning for effective metadata management, considering metadata discovery, cataloguing and enterprise metadata management applied to Data Lake implementation is vital. Rigorous application of data discipline and data hygiene is needed. To combat this, SSC should use data management tools and create policies on how data is managed and cleaned in the Data Lake. The majority of Data Lake analysts will prefer to work with clean, enriched, and trusted data. However, data quality is relative to the task at hand. Lowquality data may be acceptable for low-impact analysis or distant forecasting, but unacceptable for tactical or high-impact analysis. SSC assessments should take this into account.
Design Data Lakes with the elements necessary to deliver reliable analytical results to a variety of data consumers. The goal is to increase cross-business usage in order to deliver advanced analytical insights. Build Data Lakes for specific business units or analytics applications, rather than try to implement some vague notion of a single enterprise Data Lake. However, alternative architectures, like data hubs, are often better fits for sharing data within an organization.
References
- ↑ Treasury Board of Canada Secretariat. (March 29th, 2019). Digital Operations Strategic Plan: 2018-2022. Government of Canada. Treasury Board of Canada Secretariat. Retrieved 26-May-2019 from: [1]
- ↑ Ibid.
- ↑ Brisson, Yannick, and Craig, Sheila. (November, 2018). ESDC Data Lake – Implementation Strategy and Roadmap Update. Government of Canada. Employment and Social Development Canada – Data and Analytics Services. Presentation. Last Modified on 2019-04-26 15:45. Retrieved 07-May-2019 from GCDocs[2]
- ↑ Dennis, A. L. (2018, October 15). Data Lakes 101: An Overview. Retrieved from [3]
- ↑ Marvin, R., Marvin, R., & Marvin, R. (2016, August 22). Data Lakes, Explained. Retrieved from [ https://www.pcmag.com/article/347020/data-lakes-explained]
- ↑ The Data Lake journey. (2014, March 15). Retrieved from [4]
- ↑ Google File System. (2019, July 14). Retrieved from [5]
- ↑ Coates, M. (2016, October 02). Data Lake Use Cases and Planning Considerations. Retrieved from [6]
- ↑ Bhalchandra, V. (2018, July 23). Six reasons to think twice about your data lake strategy. Retrieved from [7]
- ↑ Data Lake Expectations: Why Data Lakes Fail. (2018, September 20). Retrieved from [8]
- ↑ Data Lake: AWS Solutions. (n.d.). Retrieved from [9]