For LLM applications, we often use embedding models like ada-002 or davinci models. While using these models, we need to often estimate the number of tokens that would required for our application.
For the English language, a good thumb rule is that 3 to 4 chars make up a token.
A nifty online tool that can help you estimate the number of tokens is: https://www.quizrise.com/token-counter
If you are looking for a web-based database manager that is open-source and commercial friendly, then please have a look at DBGate: https://github.com/dbgate/dbgate
Since it is web-based, you can see a good demo here: https://demo.dbgate.org/
Complex build processes have dominated the web development world for years. JavaScript module bundling, transpiling, and management have become critical tasks for tools such as Webpack. However, what if there was an easier method?
It is time for us to "un-learn" old tricks and rid ourselves of the baggage of old knowledge! Modern browsers support HTTP/2 and "import maps" for javascript modules and this is an absolute game changer!
In the past, web browsers had trouble comprehending contemporary JavaScript features and had trouble loading many small files quickly. Webpack and other build tools addressed these problems by:
An excellent article that states why we need to actually use a CDN for serve popular JS libraries: https://blog.wesleyac.com/posts/why-not-javascript-cdn
Excerpt from the article:
"This means that one of these CDNs going down, or an attacker hacking one of them would have a huge impact all over society — we already see this category of problem with large swaths of the internet going down every time cloudflare or AWS has an outage."
Have you ever clicked on a webpage only to spend a long time staring at a blank screen? Yes, it is frustrating. That's bad for the website (since you could just click away) and bad for you (because you're waiting).
This is where Core Web Vials are useful -- they are a set of metrics defined by Google to measure a website’s loading speed, interactivity and visual stability. In essence, there are three things that websites must do well in order to ensure that users have a positive experience.
Unless you have been living under a rock, you must have heard about Gaia-X. The whole premise of Gaia-X was to build a fair and open data ecosystem for Europe, where everyone can share information securely and control who gets to use it. It's like a big marketplace for data, but with European values of privacy and control at its heart.
The core techical concepts that we need to understand around Gaia-X are "Data Spaces" and "Connectors".
Data Spaces refer to secure and trusted environments where businesses, individuals, and public institutions can share and use data in a controlled and fair manner. They're like marketplaces for data, but with strict rules to ensure privacy, security, and data sovereignty (meaning individuals and companies retain control over their data).
A connector plays a crucial role in facilitating secure and controlled data exchange between different participants within the ecosystem. Think of it as a translator and bridge builder, helping diverse systems and providers communicate and share data seamlessly and safely. The Eclipse foundation has taken a lead on this and created the Eclipse Dataspace Component (EDC) initiative wherein many opensource projects have been created to build Gaia-X compliant connectors.
These core concepts of Dataspaces and Connectors can also be used to build a modern data architecture in a federated decentralized manner. An excellent article on this approach is available on AWS here - https://aws.amazon.com/blogs/publicsector/enabling-data-sharing-through-data-spaces-aws/
An offshoot of Gaia-X is another initiative called Catena-X that aims to create a data ecosystem for the automotive industry. It aims to create a standardized way for car manufacturers, suppliers, dealers, software providers, etc. – to share information securely and efficiently through usage of standard data formats and procotols. The Eclipse Tractus-X™ project is the official open-source project in the Catena-X ecosystem under the umbrella of the Eclipse Foundation and has reference implementations of connectors to securely exchange data.
At the heart lies the data usage contract, a legally binding agreement between data providers and consumers within the Catena-X ecosystem. This contract specifies the exact terms of data usage, including:
Contracts establish a basic link between the policies and the data to be transferred; a transfer cannot occur without a contract.
Because of the legal binding nature of this design, all users of data are required to abide by the usage policies just like they would with a handwritten contract.
More details around data governance can be found in the official white paper --https://catena-x.net/fileadmin/_online_media_/231006_Whitepaper_DataSpaceGovernance.pdf
Besides contracts, every data access and usage event is logged on a distributed ledger, providing a transparent audit trail for accountability and dispute resolution. The connectors also enforce proper authentication/authorization through the Identity Provider and validate other policy rules.
Thus Gaia-X/Catena-X enforce data usage policies through a combination of legal contracts, automated technical tools, independent verification, and a strong legal framework. This multi-layered approach ensures trust, transparency, and accountability within the data ecosystem, empowering data providers with control over their valuable information.
Faker is an excellent tool for generating mock data for your application. But any complex application would have tens of tables with complex relationships between them. How can we use Faker to populate all of these tables?
We can follow two approaches here:
Option 1: Create the primary table first and then the dependent tables. Then when populating the dependent tables, you can refer to a random primary key from the first table. A good article summarizing this is here -- https://khofifah.medium.com/how-to-generate-fake-relational-data-in-python-and-getting-insight-using-sql-in-bigquery-985c5adc87d3
Large language models (LLMs) have revolutionized the field of natural language processing (NLP), enabling state-of-the-art performance on a wide range of tasks, including text classification, translation, summarization, and generation.
When it comes to usecases around leveraing LLMs for extracting insights from our own knowledge repositories, we have broadly two design approaches:
Debezium is a distributed open source platform for change data capture (CDC). It collects real-time changes to database tables and transmits them to other applications. Debezium is developed on top of Apache Kafka, which provides a dependable and scalable streaming data infrastructure.
Debezium operates by connecting to a database and watching for table updates. When a change is identified, Debezium creates a Kafka event with the change's information. Other applications, such as data pipelines, microservices, and analytics systems, can then ingest these events.
There are several benefits of utilising Debezium CDC, including:
Mocking APIs and synthetic mock data generation are invaluable techniques to speed up development. We recently used the Mockaroo platform and found it quite handy to generate dummy data and mock APIs.
IBM has also kindly released ~25M records of synthetic financial transacation data that can be used during application development or ML training.
https://github.com/IBM/TabFormer
Other examples of mock data generation tools are:
There are many techniques for building Fraud Detection systems. It can be:
To prevent abusive prompts and prompt hacking, we need to leverage certain techniques such as Filtering, Post-Prompting, random enclosures, content moderation, etc.
A good explanation of these techniques is given here -- https://learnprompting.org/docs/category/-defensive-measures
Clickjacking is a sort of cyberattack in which people are tricked into clicking on something they did not plan to click on. This can be accomplished by superimposing a malicious frame on top of a legal website or injecting a malicious link within an apparently innocent piece of content.
When a user clicks on what appears to be a legitimate website or link, they are in fact clicking on a malicious frame or link. This can then redirect users to a bogus website or run malicious programmes on their PC.
Clickjacking attacks are sometimes difficult to detect because they frequently depend on social engineering tactics to deceive users. For example, the attacker may develop a phoney website that appears to be the actual one, or they could give the victim a link that appears to be from a valid source.
To protect yourself against clickjacking, make use of a pop-up blocker (default in Chrome and many modern browsers). Any website that asks you to enable Flash or JavaScript should be avoided. Hover your cursor over a link before clicking on it if you are unsure whether it is authentic. If the URL of the link changes, it is most likely malicious.
If you are a developer, please check out the following links to what can be done in your code to reduce the risk of clickjacking.
https://cheatsheetseries.owasp.org/cheatsheets/Clickjacking_Defense_Cheat_Sheet.html
Shadow testing is a software testing technique that involves sending production traffic to a duplicate or shadow environment. This allows testers to compare the behavior of the new feature in the shadow environment to the behavior of the old feature in the production environment. This can help to identify any potential problems with the new feature before it is released to all users.
The following diagram from the Microsoft GitHub site illustrates this concept.
Differential privacy (DP) is a mathematical paradigm for protecting individuals' privacy in datasets. By allowing data to be analysed without disclosing sensitive information about any individual in the dataset, it can protects the privacy of individuals. Thus, it is a method of protecting the privacy of people in a dataset while maintaining the dataset's overall usefulness.
To protect privacy, the most easy option is anonymization, which removes identifying information. A person's name, for example, may be erased from a medical record. Unfortunately, anonymization is rarely enough to provide privacy because the remaining information might be uniquely identifiable. For example, given a person's gender, postal code, age, ethnicity, and height, it may be able to identify them uniquely even in a massive database.
The concept behind differential privacy is to introduce noise into the data in such a manner that it is hard to verify whether any specific individual's data was included in the dataset. This is accomplished by assigning a random value to each data point, which is chosen in such a manner that it has no effect on the overall statistics of the dataset but makes identifying individual data points more difficult.
The following paper by Apple gives a very good overview of how Apple uses Differential Privacy to gain insight into what many Apple users are doing, while helping to preserve the privacy of individual users - https://www.apple.com/privacy/docs/Differential_Privacy_Overview.pdf
Epsilon (ε) is a parameter in differential privacy that affects the amount of noise introduced to the data. A greater epsilon number adds more noise, which gives more privacy but affects the accuracy of the findings.
Here are some examples of epsilon values that might be used in different applications:
nip.io is a free, open-source service that allows you to use wildcard DNS for any IP address. This implies you may build a hostname that resolves to any IP address, no matter where it is. This may be beneficial for a number of things, including:
It is more critical than ever in today's complex and dispersed IT settings to have a complete grasp of how your systems are performing. This is where the concept of observability comes into play. The capacity to comprehend the condition of a system by gathering and analysing data from various sources is referred to as observability.
Observabilty has three critical pillars:
Distributed Logging: Logs keep track of events that happen in a system. They may be used to discover problems, performance bottlenecks, and the flow of traffic through a system. In a modern scalable distributed architecture, we need logging frameworks that support collection and ingestion of logs across the complete tech stack. Platforms such as Splunk and ELK (Elastic, Logstash, Kibana) support this and are popular frameworks for distributed logging.
Metrics (performance instrumentation in code): Metrics are numerical measures of a system's status. They may be used to monitor CPU use, memory consumption, and request latency, among other things. Some of the most popular frameworks for metrics are Micrometer , Prometheus and DropWizard Metrics.
Tracing (E2E visibility across the tech stack): Traces are a record of a request's route through a system. They may be utilised to determine the core cause of performance issues and to comprehend how various system components interact with one another. A unique Trace-ID is used to corelate the request across all the components of the tech stack.
Platforms such as Dynatrace, AppDynamics and DataDog provide comprehensive features to implement all aspects of Observability.
The three observability pillars operate together to offer a complete picture of a system's behaviour. By collecting and analysing data from all three sources, you can acquire a thorough picture of how your systems operate and discover possible issues before they affect your consumers.
There are a number of benefits to implementing the three pillars of observability. These benefits include:
If you want to increase the observability of your systems, I recommend that you study more about the three pillars of observability and the many techniques to apply them. You can take your IT operations to the next level if you have a thorough grasp of observability.
There has been a lot of buzz in recent years about the potential of large language models (LLMs) to develop new text forms, translate languages, compose various types of creative material, and answer your queries in an instructive manner. However, one of the drawbacks of LLMs is that they may be quite unexpected. Even little changes to the prompt might provide drastically different outcomes. This is where quick engineering comes into play.
The technique of creating prompts that are clear, explicit, and instructive is known as prompt engineering. You may maximise your chances of receiving the desired outcome from your LLM by properly writing your questions.
Given below are some of the techniques you can use to create better prompts:
If you have an OpenAPI specs file (YAML or JSON), then you can quickly create a mock server using one of the following tools.
Today Kubernetes has become the defacto standard to deploy applications. To understand what happens behind the scenes when you fire "kubectl" commands, please have a look at this excellent tutorial series by VMWare - https://kube.academy/courses/the-kubernetes-machine
Some key components of the K8 ecosystem. The control plane consists of the API server, Scheduler, etcd and Controller Manager.
The following two articles by Rebecca Bevans are an excellent introduction to the concept of Hypothesis testing and the types of statistical tests available:
Snippet from the article on the process of hypothesis testing:
Step 1: State your null and alternate hypothesis
Step 2: Collect data
Step 3: Perform a statistical test
Step 4: Decide whether to reject or "fail to reject" your null hypothesis
Step 5: Present your findings
The following site has an excellent collection of 20 free courses that I would highly recommend for folks who want to learn the basics of finance and fundamentals of maths/stats in finance.
https://corporatefinanceinstitute.com/collections/?cost=free&card=117884
I really liked the following courses and helped me consolidate my understanding:
- Stats basics: https://learn.corporatefinanceinstitute.com/courses/take/statistics-fundamentals
- Accounting basics: https://learn.corporatefinanceinstitute.com/courses/take/learn-accounting-fundamentals-corporate-finance
- How to read financial statements: https://learn.corporatefinanceinstitute.com/courses/take/learn-to-read-financial-statements-free-course/
- Data Science fundamentals - https://learn.corporatefinanceinstitute.com/courses/take/data-science-and-machine-learning/
The following websites gives an excellent overview for beginners of the 3 different types of variables that we encounter in feature engineering (or even in basic stats):
https://study.com/academy/lesson/continuous-discrete-variables-definition-examples.html
https://www.scribbr.com/methodology/types-of-variables/
Snippets from the articles:
A discrete variable only allows a particular set of values, and in-between values are not included. If we are counting a number of things, that is a discrete value. A dice roll has a certain number of outcomes, and nothing else (we can roll a 4 or a 5, but not a 4.6). A continuous variable can be any value in a range. Usually, things that we are measuring are continuous variables, because it can be any value. The length of a car ride might be 2 hours, 2.5 hours, 2.555, and so on.
Categorical variables are descriptive and not numerical. So any way to describe something is a categorical variable. Hair color, gum flavor, dog breed, and cloud type are all categorical variables.
There are 2 types of categorical variables: Nominal categorical variables are not ordered. The order doesn't matter. Eye color is nominal, because there is no higher or lower eye color. There isn't a reason one is first or last.
Ordinal categorical variables do have an order. Education level is an ordinal variable, because they can be put in order. Note that there is not some exact difference between the levels of education, just that they can be put in order.
The TM Forum (TMF) is an organisation of over 850 telecom firms working together to drive digital innovation. They created a standard known as TMF Open APIs, which provides a standard interface for the interchange of various telco data.
TM Forum’s Open APIs are JSON-based and follow the REST paradigm. They also share a common data model for Telecom.
Any CSP (Communications service provider) can accelerate their API journey by leveraging the TMForum API contracts. The link below gives some of the examples of the API standards available:
https://projects.tmforum.org/wiki/display/API/Open+API+Table
Currently, there are around 60+ APIs defined in the Open API table of TMForum.
Few examples of the APIs are as follows:
The GitHub repository of TMForum is a great place to get acquainted with the APIs - https://github.com/tmforum-apis
Since the TMForum defines the data model in JSON format, any noSQL datastore that stores data as JSON documents becomes an easy option to quickly implement an API strategy. For example, TMF data model of the API can be persisted 1:1 in Mongo database without the need for additional mappings as shown here - https://www.mongodb.com/blog/post/why-telcos-implement-tm-forum-open-apis-mongodb
mAP (mean Average Precision) is a common metric used for evaluating the accuracy of object detection models. The mAP computes a score by comparing the ground-truth bounding box to the detected box. The higher the score, the more precise the model's detections.
The following articles give a good overview of the concepts of precision, recall, mAP, etc.
https://jonathan-hui.medium.com/map-mean-average-precision-for-object-detection-45c121a31173
https://blog.paperspace.com/mean-average-precision/
https://blog.paperspace.com/deep-learning-metrics-precision-recall-accuracy/
https://www.narendranaidu.com/2022/01/confusion-matrix-for-classification.html
Some snippets from the above article:
"When a model has high recall but low precision, then the model classifies most of the positive samples correctly but it has many false positives (i.e. classifies many Negative samples as Positive). When a model has high precision but low recall, then the model is accurate when it classifies a sample as Positive but it may classify only some of the positive sample.
Higher the precision, the more confident the model is when it classifies a sample as Positive. The higher the recall, the more positive samples the model correctly classified as Positive.
As the recall increases, the precision decreases. The reason is that when the number of positive samples increases (high recall), the accuracy of classifying each sample correctly decreases (low precision). This is expected, as the model is more likely to fail when there are many samples.
The precision-recall curve makes it easy to decide the point where both the precision and recall are high. The f1 metric measures the balance between precision and recall. When the value of f1 is high, this means both the precision and recall are high. A lower f1 score means a greater imbalance between precision and recall.
The average precision (AP) is a way to summarize the precision-recall curve into a single value representing the average of all precisions. The AP is the weighted sum of precisions at each threshold where the weight is the increase in recall.
The IoU is calculated by dividing the area of intersection between the 2 boxes by the area of their union. The higher the IoU, the better the prediction.
The mAP is calculated by finding Average Precision(AP) for each class and then average over a number of classes."
I was trying to help my kids understand the importance of deeply understanding a concept, instead of just remembering facts.
I found the knowledge pyramid of Bloom an excellent illustration to help my kids understand how to build skills and knowledge. The following article on Vanderbilt University site is a good read to understand the concepts - https://cft.vanderbilt.edu/guides-sub-pages/blooms-taxonomy/
In a distributed microservices environment, we do not have complex 2-phase commit transaction managers.
We need a simpler approach and we have design patterns to address this issue. A good article explaining this strategy is available here - https://docs.microsoft.com/en-us/azure/architecture/reference-architectures/saga/saga
The crux of the idea is to issue compensating transactions whenever there is a failure in one step of the flow. A good sample usecase for a banking scenario (with source code) is available here - https://github.com/Azure-Samples/saga-orchestration-serverless
I have always been a great fan of the 'Contract-First' API design paradigm. The Swagger (OpenAPI) toolset makes it very simple to design new API contracts and object schemas.
There is a Swagger Pet Store demo available here, wherein we can design API contracts using a simple YAML file: https://editor.swagger.io/
After the API contract has been designed and reviewed, we can quickly generate stubs and client code in 20 languages using Swagger Codegen.
In my previous blog posts, we had discussed about Data Lakes and Snowflake architecture.
Since Snowflake combines the abilities of a traditional data warehouse and a Data Lake, they also market themselves as a Data Lakehouse.
Another competing opensource alternative that is headed by the company databricks is called Delta Lake. Delta Lake provides ACID transactions, scalable metadata handling, and unifies streaming and batch data processing on top of existing data lakes.
A good comparison between Snowflake and databricks Delta Lake is available here: https://www.firebolt.io/blog/snowflake-vs-databricks-vs-firebolt
Enterprises who are embarking on their data platform modernization strategy can ask the following questions to arrive at a best fit choice:
One of the fundamental challenges in migrating SAP ECC to S/4 HANA is the lack of knowledge on the plethora of customizations done on legacy SAP ECC.
To address this challenge, there are two leading products in the market - ServiceNow Gekkobrain and Celonis.
Gekkobrain helps teams in getting a deeper understanding of custom code that was developed to extend the functionality of SAP. It analyses the custom code base and identifies relevant HANA issues and also try to fix the issue.
Gekkobrain flows is a component that uses ML to understand and visualize the business process. It can understand main flows, sub flows and deviations and help in identifying automation opportunities. This capability of Gekkobrain flows is also branded as a Process Mining Tool.
ServiceNow acquired Gekkobrain to integrate it with the NOW platform and leverage its workflow engine to automate workflows for customized SAP code (during HANA migrations).
Another popular tool that is used for during SAP modernization is the popular process mining tool called as Celonis. Celonis is used for retrieving, visualizing and analyzing business processes from transactional data stored by the SAP ERP systems.
