Avi Networks

Autonomous Vehicle Infrastructure (AVI) Networks is an application delivery and load balancing platform provider that delivers software-defined services across on‑premises and cloud environments.

• Software-defined Application Delivery Controller (ADC) platform (application delivery / load balancing)
• Load balancing, SSL/TLS termination, and traffic management for enterprise applications (networking / security)
• Web Application Firewall (WAF) and application security capabilities (application security)
• Analytics and observability for application traffic and performance (observability / APM-adjacent)
• Multi-cloud and container-native deployment support across data centers and public clouds (cloud networking)

More About Avi Networks

AVI Networks provides an application delivery platform that enterprises use to deliver and secure applications across data centers and cloud environments. The platform replaces or complements hardware-based load balancers with a software-defined architecture that runs on commodity infrastructure, virtual machines, containers, and public cloud services. It is used by infrastructure and operations teams, application owners, and platform engineering groups that manage HTTP/S, Transmission Control Protocol (TCP), and User Datagram Protocol (UDP) application traffic, including web applications, APIs, and microservices.

The AVI Networks architecture is commonly described as separating a centralized control plane from distributed data-plane components. A central controller (control plane) manages configuration, policy, and analytics, while distributed service engines (data plane) handle actual packet processing, load balancing, SSL/TLS termination, and security enforcement. This model aligns with Software Defined Networking (SDN) concepts and supports elastic scaling of load balancing capacity by instantiating additional service engines as traffic grows or changes.

AVI Networks focuses on Layer 4–7 services, including application load balancing, global server load balancing, content switching, and health monitoring. The platform supports TLS/SSL offload and inspection, HTTP/2, and integration with Domain Name System (DNS) and IP Address Management (IPAM) services. Enterprises use it to publish applications with virtual Intrusion Prevention System (IPS), balance traffic across pools of servers, apply persistence and connection policies, and automate blue‑green or canary deployments. The system is accessible through a web-based UI, RESTful APIs, and integrations with Infrastructure-as-Code (IaC) tools, which supports DevOps workflows and Continuous Integration and Continuous Deployment (CI/CD) pipelines.

The platform includes WAF capabilities (application security) that protect HTTP-based applications from common vulnerabilities such as injection and Cross-Site Scripting (XSS), using rule sets and policy-based controls. It also provides Distributed Denial of Service (DDoS) mitigation features and supports integration with identity and access management and certificate management systems. These security functions allow enterprises to consolidate application delivery and security policies at the edge of their applications.

A core element of AVI Networks is analytics and observability for application traffic. The platform collects telemetry from every transaction handled by its service engines and aggregates this into time-series dashboards and reports. Metrics can include latency, throughput, error rates, Secure Socket Layer (SSL) handshake characteristics, and client geography. This data can be used for capacity planning, troubleshooting, and automated decisions such as scaling service engines or redirecting traffic. Integrations with logging and monitoring systems support centralized operations across hybrid and multi-cloud environments.

From a marketplace taxonomy perspective, AVI Networks belongs in categories such as application delivery controllers (networking), load balancing (networking), WAF (application security), and observability for application traffic (observability). It is also relevant to multi-cloud networking and Kubernetes ingress and service mesh integrations, where its software-based approach can provide ingress control and traffic management for containerized and microservices-based applications.