Secure Extranet with Equinix Fabric and F5 Distributed Cloud
Why: The Challenge of Building a Secure Extranet Establishing a secure extranet that spans multiple clouds, partners, and enterprise locations is inherently complex. Organizations face several persistent challenges: Technology Fragmentation: Different clouds, vendors, and networking stacks introduce inconsistency and integration friction. Endpoint Proliferation: Each new partner or cloud region adds more endpoints to secure and manage. Configuration Drift: Manual or siloed configurations across environments increase the risk of misalignment and security gaps. Security Exposure: Without centralized control, enforcing consistent policies across environments is difficult, increasing the attack surface. Operational Overhead: Managing disparate systems and connections strains NetOps, DevOps, and SecOps teams. These challenges make it difficult to scale securely and efficiently, especially when onboarding new partners or deploying applications globally. What: A Unified, Secure, and Scalable Extranet Solution The joint solution from F5 and Equinix addresses these challenges by combining: F5® Distributed Cloud Customer Edge (CE): A virtualized network and security node deployed via Equinix Network Edge. Equinix Fabric®: A software-defined interconnection platform that provides private, high-performance connectivity between clouds, partners, and enterprise locations. Together, they create a strategic point of control at the edge of your enterprise network. This enables secure, scalable, and policy-driven connectivity across hybrid and multi-cloud environments. This solution: Simplifies deployment by eliminating physical infrastructure dependencies. Centralizes policy enforcement across all connected environments. Accelerates partner onboarding with pre-integrated, software-defined connectors. Reduces risk by isolating traffic and enforcing consistent security policies. How: Architectural Overview At the heart of the architecture is the F5 Distributed Cloud CE, deployed as a virtual network function (VNF) on Equinix Network Edge. This CE: Acts as a gateway node for each location (cloud, data center, or partner site). Connects to other CEs via F5’s global private backbone, forming a secure service mesh. Integrates with F5 Distributed Cloud Console for centralized orchestration, visibility, and policy management. The CE node(s) are interconnected to partners, vendors, etc. using Equinix Fabric, which provides: Private, low-latency interconnects to major cloud providers (AWS, Azure, GCP, OCI). Software-defined routing via Fabric Cloud Router. Tier-1 internet access for hybrid workloads. This architecture enables a hub-and-spoke or full-mesh extranet topology, depending on business needs. Key Tenets of the Solution Strategic Point of Control The CE becomes the enforcement point for traffic inspection, segmentation, and policy enforcement—across all clouds and partners. Unified Management F5 Distributed Cloud Console provides a single pane of glass for managing networking, security, and application delivery policies. Zero-Trust Connectivity Built-in support for mutual TLS, IPsec, and SSL tunnels ensures encrypted, authenticated communication between nodes. Rapid Partner Onboarding Equinix’s Fabric and F5 CE connectors allow new partners to be onboarded in minutes, not weeks. Operational Efficiency Automation hooks (GitOps, Terraform, APIs) reduce manual effort and configuration drift. Private interconnects and regional CE deployments help meet regulatory requirements. Additional Links F5 and Equinix Partnership The Business Partner Exchange - An F5 Distributed Cloud Services Demonstration Equinix Fabric Overview Additional Equinix and F5 partner informationGlobal Live Webinar (02/19) Driving AI Integration with Hybrid Multicloud Strategies
Driving Al Integration with Hybrid Multicloud Strategies This webinar event is open to all regardless of geographic location. Date: Wednesday, February 19, 2025 Time: 10:00am PT | 1:00pm ET Speakers: Bart Salaets, EMEA Field CTO, F5 | Aubrey King, Community Evangelist, F5 What's the webinar about? Driving AI Integration with Hybrid Multicloud We're excited to share the pivotal advantages of embracing a hybrid, multicloud strategy and how integrating advanced AI technologies can drive innovation and efficiency within your organization. Discover the multifaceted benefits of hybrid, multicloud deployments: Reduce overall cloud expenditure Enhance system resilience Streamline AI application deployment Join our experts as they share valuable insights and actionable strategies to help you navigate the complexities of the modern IT landscape and harness the full potential of a multicloud environment powered by AI. Key Takeaways: Understand the driving forces behind the shift towards a multicloud strategy and what makes it compelling for organizations today. Learn how AI applications are influencing and shaping multicloud strategies. Explore how our solutions can help you overcome the inherent challenges of multicloud environments. Learn more, register todaySite-to-Site Connectivity in F5 Distributed Cloud Network Connect – Reference Architecture
Purpose This guide describes the reference architecture for deploying F5 Distributed Cloud’s (XC) Multicloud Network Connect service to interconnect their workload across private connectivity or the internet. It enumerates the options available to an F5 Distributed Cloud user to configure site-to-site connectivity using F5 XC Customer Edges (CEs) and explains them in detail to help the user make informed decisions to choose the correct topology for their use case. Audience This guide is for technical readers, including network admins and architects who want to understand how the Multicloud Network Connect service works and what network topology they must use to interconnect their workloads across data centers, branches, and public clouds. This guide assumes the reader is familiar with networking concepts like routing, default gateway configurations, IPSec and SSL encryption, and private connectivity solutions provided by public clouds like AWS Direct Connect and Azure Express Route. Introduction Ensuring workload reachability across data centers, branches, and/or public cloud can be challenging and operationally complex if done in the traditional way. The network teams must design, configure, and maintain multiple networking and security equipment and need expertise across many vendor solutions that provide functionality like NAT, SD-WAN, VPN, firewalls, access control lists (ACLs), etc. This gets even more nuanced while connecting two networks that have overlapping IP address CIDRs which is often in the case of hybrid cloud deployments and during mergers and acquisitions. F5 XC Multicloud Network Connect provides a simple way to configure these interconnections and manage access and security policies across multiple heterogeneous environments, from a single console. It abstracts the complexities by taking the user intent and automating the underlying networking and security while providing the flexibility to choose to connect over a private network or the public internet. Customer Edge as a Gateway To provide site-to-site reachability and ensure enforcement of the security policies, traffic must flow through the CE site. For this, the CE’s Site Local Inside (SLI) IP address must be used as the default gateway or as the next hop to reach the networks on other sites. Figure: Using CE as the gateway Physical vs. Logical Connectivity Two or more CE sites can be physically connected in multiple ways. But this does not automatically allow networks on different sites to be L3 routable to each other by default. For this, the user must associate networks with segments. The physical connection dictates the path the packets will take while going from one site to the other, and the logical connection connects the VLANs (on-prem) and the VPCs/VNETs (in the public cloud) using network overlay and provides segmentation. Note: Multicloud Network Connect provides Layer 3 connectivity between networks. Configuring L3 connectivity is not required to have app-to-app connectivity across the sites. This is done using the distributed load balancer feature under App Connect. Physical Transit Options Over F5 Global Network Backbone A CE site is always connected to the two nearest Regional Edges (REs) for redundancy, using IPSec or SSL tunnels. The REs across different regions are connected via a global, private F5 backbone network. F5’s global network backbone provides high-speed, private transit across regions where Regional Edges are located. Users can use the CE-RE tunnels over the internet to securely connect to this backbone locally and leverage the private connectivity to connect across regions. Figure: Default CE-CE connectivity over REs and F5 network backbone Pros: No need to manage underlay networking if using CE-RE tunnels over the internet. High-speed private transit between geographically distant regions, at no extra cost. End-to-end encryption of traffic between sites. Option to have end-to-end private connectivity Cons: Throughput is limited to the bandwidth of the two tunnels per site. When To Use: The easiest way to connect when private connectivity is not available between data centers or to the cloud VPCs in the case of hybrid cloud. IPSec/SSL tunnels over the internet are acceptable, but you do not want to manage multiple VPN tunnels or SD-WAN devices. Connecting geographically distant sites and you need better end-to-end latency and reliability than going over the internet. Direct Site-to-Site Over Internet If security regulations prevent the use of F5’s private backbone network, users can connect the CE sites directly to each other using IPSec tunnels (SSL encryption is not supported in this case). This is done using the Site Mesh Group (SMG) feature. Note: Even when the CEs are a part of Site Mesh Group, they will still connect to the REs using encrypted tunnels as this is required for control plane connectivity. When the sites are in an SMG, the data path traffic flows through the CE-CE tunnels as the preferred path. If this link fails, as a backup, the traffic gets routed to the REs and over the F5 network backbone to the other site. The number of tunnels on each link between two CE sites depends on the number of control nodes they have. Two single-node sites are connected using only one tunnel. If any one of these sites has three control nodes, it forms three tunnels to the other site. Figure: Number of tunnels between sites in a SMG Pros: Sites are directly connected, so the data path is not dependent on RE. Easy connectivity over the internet Traffic is always encrypted in transit Eliminates the need to manually configure cross-site VPNs or SD-WAN. Cons: Encryption and decryption require more CPU resources on CE nodes as performance requirements increase. Note: L3 Mode Enhanced Performance can be enabled on the sites to get more performance from available CPU and memory resources, but this must be enabled when the site is used only for L3 connectivity as it reduces the resources available for L7 features. Direct Site-to-Site Over Customer’s Network Backbone The CE-CE tunnels can also be configured to be connected over a private network if end-to-end private connectivity is required. Customer can leverage their existing private connectivity between data centers provisioned using private NaaS providers like Equinix. The sites can either be connected directly using SMG where the connections are encrypted or using the DC Cluster Group (DCG) feature, which connects the sites using IP-in-IP tunnels (no encryption). The number of tunnels on each link between two CE sites depends on the number of control nodes they have. Two single-node sites are connected using only one tunnel. If any one of these sites has three control nodes, it forms three tunnels to the other site. A DCG will give better performance, while an SMG is more secure. Unlike SMG, DCG does not fall back to sending RE-CE tunnels if private connectivity fails. Pros: Data path confined within the customer’s private perimeter. Sites are directly connected, so the data path is not dependent on RE. Option to choose encrypted or unencrypted transit. Simplifies the ACLs on the physical network and allows users to manage segmentation using the F5 XC console. Cons: Customer needs to manage the private connectivity across data centers or from the data center to the public cloud. Direct Site-to-Site Connectivity Topologies For direct site-to-site connectivity, sites can be grouped into Site Mesh Group (SMG) or DC Cluster Group (DCG). These allow sites to connect either in Full Mesh or Hub-Spoke topologies as described below: Full Mesh Site Mesh Group All sites that are part of a full-mesh SMG are connected to every other site using IPSec tunnels, forming a full-mesh topology. Figure: Sites in full mesh Site Mesh Group When To Use: In Hybrid cloud use cases. When all sites have equal functionality (e.g. connecting workloads across data centers). High fault tolerance is required for site-to-site connectivity (not dependent on any one site for transit). Hub-Spoke Site Mesh Group This mode allows the sites to be grouped into a hub SMG and a spoke SMG. The sites within the hub SMG are connected using full mesh topology. The sites within the spoke SMG are connected to the sites in hub SMG only and not to other sites in the spoke SMG. Figure: Sites in Hub-Spoke Site Mesh Group Some characteristics of Hub-Spoke SMG: The hub can have multiple sites for redundancy, but it usually has one site in most customer use cases. A hub site can be a spoke site for a different Hub-Spoke SMG. A CE site can be a spoke for multiple hubs. When To Use: For data center/cloud to edge/branch connectivity use cases. Full Mesh DC Cluster Group DC Cluster Group only supports full mesh topology. Every site in a DCG is connected to every other site using IP-in-IP tunnels. Traffic is not encrypted in transit, but DCG is only supported when sites can be connected over a private network. Figure: Sites in DC Cluster Group When To Use: Connecting VLANs on a data center to VLANs on other data centers or to public cloud VPCs/VNETs, when there is private connectivity between them. When the security regulations allow unencrypted traffic over the private transit. Offline Survivability CE Sites require control plane connectivity to the REs and Global Controller (GC) to exchange routes, renew certificates, and decrypt blindfolded secrets. To enable business continuity during an upstream outage, the Offline Survivability feature can be enabled on all sites in a Full Mesh SMG or DCG. The feature is not supported for Hub-Spoke SMG. With this feature enabled the sites can continue normal operations for 7 days without connecting to the REs and the GC. With the offline survivability feature enabled on a CE site, the local control plane becomes the certificate authority in case of connectivity loss. The decrypted secrets and certificates are cached locally on the CE. So, this feature is not turned on by default to allow the user to decide if enabling it aligns with the security regulations of the company. Logical Connectivity Once the physical transit is configured and the connection topology is chosen the workloads on the networks across the sites can be connected using segments or the applications on one site can be delivered to any other site by configuring a distributed load balancer. Connect Networks - Segmentation Users can create segments and add data center VLANs or public cloud VPCs/VNETs to them. All such networks added to a segment become part of a common routing domain and all workloads on these networks can reach each other using the CE sites as gateways. Users must ensure the networks added to a segment do not overlap. Segments are isolated layer 3 domains. So, workloads on one segment cannot access workloads from other segments by default. However, users can configure Segment Connectors to allow traffic from one segment to another. Figure: Segmentation Connect Applications - Distributed Load Balancing Instead of allowing the workloads to route directly to one another, the user can configure a distributed load balancer to publish a service from one site to other sites. This is done by adding the service endpoints to an origin pool of a load balancer object and advertising it using a custom VIP to another site or multiple sites. This allows the client to connect to the service as a local resource. Using Distributed Load Balancing, an LB admin can configure policies to expose the required API of the application only to the required sites. This reduces the attack surface and increases app security. Figure: Distributed Load Balancing E.g. in the figure above, the on-prem database is advertised to client apps on AWS and Azure which can access the DB using their local VIP, and the on-prem application is advertised to the client on Azure only. Decision Flow to Choose Physical Connectivity Options Once you understand the various physical and logical connectivity options, the below chart can help you to make an informed decision based on the connectivity requirements, infrastructure/platform available, and security restrictions. Once the connectivity is decided, you can choose to connect the network or only publish apps to sites where required based on the application requirements. Related Articles F5XC Site Site Mesh Group DC Cluster Group Segmentation Distributed Load Balancer
