If you've been following my blog for a while, you know that one of the many mysteries/points of discussion that come up repeatedly is: what is happening in the space under La Sirena's bridge? There's a door leading there from the mess hall and we see Picard walk through it in S01E06, "The Impossible Box", but we never find out what that space is being used as.
(At least, we don't know what its in-universe use is. We know from set plans that in the studio, the space apparently held the playback setup.)
We got a glimpse of a cross-section of the ship in the Blu-ray set tour, which has some impossible geometry happening under the bridge...
(That is not a proper floor and something is definitely clipping through it!)
... and if you remember my post from a while back, I speculated that the most likely explanation is that the model has an extendable ladder there, that would allow people to board/leave the ship by a means other than the loading ramp. This would fit with the early idea of the season 1 writers to have Picard board La Sirena in a space port, rather than beam him on board while she's in orbit.
Well, a couple of weeks ago, we got confirmation that this is indeed what the production team originally intended.
Dave Blass, the production designer for PIC Seasons 2 and 3, tweetet some images showcasing a cross-section of the Sirena set/model:
As you can imagine, this gave me enormous joy (and a not too small amount of glee)! I have long insisted that the panorama windows, i.e. the exit the Motley Crew use to get off the ship once she crash-lands on Coppelius, don't really work as a proper access point to the ship. There is a three foot drop right inside the window the crew needs to bridge, no proper hatch, no ladders, etc. The only reason it makes for such a convenient exit is that Sirena is buried in a few metres of dirt, bringing the window level with the ground.
And indeed, La Sirena has, or at least was originally intended to have, a proper access to the front of the ship, one with a ladder and hatch and everything! And it's located in the mysterious space under the bridge!
But, me being me, this schematic also immediately raised a question: Isn't that ladder a bit too short?
If you remember this post, it seems like one of the changes made during Sirena's design process was that the wings were dropped quite a significant amount. Where the early concept art has the ship sitting fairly low to the ground, she is raised much higher when she reaches her final form.
Essentially, we went from a configuration that might have looked something like the version on the top to the actual model on the bottom:
This change increased the ship's clearance significantly.
For the non-imperial-measuring among us, the height of the ladder given in the schematic shared by Blass, 14' 10 1/2", translates to about 4.8m. However, when you line up the orthogonal view of the ship with the cross section, the length of the ladder is not really enough to reach the ground once the ship has landed.
(The green line indicates the bottom of the stairs.)
There is some speculation that maybe Sirena can fold up her nacelles for landing, and that might be true. There are rooms extending into the wings that would end up at an odd angle, but I suppose with artificial gravity, anything is possible -- if somewhat unlikely.
Still, if we presume Sirena's wings are rigid in general, the distance from the tarmac to the belly of the ship (here: the stage floor in the schematic) is a bit larger than 4.8m.
I wanted to adapt the ladder accordingly, but getting good measurements by converting between feet, pixels, and metres is a bit of a hassle. So instead, I simply used the measurements already on the schematic and extended the ladder so that the ship's clearance would be 5.5m or around 18ft.
This brings the total length of the ladder to about 21ft or 6.5m, and overlaid on the orthogonal ship view, it looks like this:
(The green line once again indicates the bottom of the stairs.)
As you can see, this length requires for the outer engines to fold up a little bit and would have the lowest point of the nacelles basically sitting on the ground. I personally think that would make a lot of sense, and in season 2 we did see that the outer engine pods are on hinges and can definitely fold down.
(It's subtle, but they do move back into their resting position towards the end of the gif.)
It was never confirmed that the engings can fold farther up as well, but looking at how they're attached, I think it makes sense that they could.
Now, in the adjusted S1 concept art of Sirena at the space port, the outer engines are in their normal positions and the wings are actually fully off the ground, with the ship resting on extended landing gear:
So, my extended ladder is the absolute minimum length needed to account for the dropped wings. In all likelihood the ladder would have to be even longer than that, because the clearance would be over 5.5m.
One thing that playing around with all of these views and measurements made me realize, though, is that La Sirena is quite a bit larger than I usually picture her. I have this realization about once every two or three months, so to make it easier to internalize, I asked the wonderful @regionalpancake to assist me.
Google helpfully suggests that 5.5m / 18ft is about half the size of a telephone pole or of three Michael Jordan's standing on each other's shoulders. It is also the size of...
... one average adult giraffe. (This is more or less helpful, depending on when you last went to the zoo, but I really enjoyed that as a visual aide.)
And because Regionalpancake is a good sport (and extremely proficient at adding animals to La Sirena), she also gave me this second edit:
(She also helpfully removed the spacedock workers who were a little to tall in comparison to Sirena. Hopefully, the friendly Averagely-Sized Adult Giraffe will make the ship's real dimensions slightly easier to gauge.)
So, now we have an idea of what might lurk beneath La Sirena's bridge!
I imagine in-universe, there is more stuff stashed under there than just the stairs, though. Perhaps the space gives easier access to the phaser banks in the nose of the ship, or to some other flight control or power distribution machinery. And there's still the question of why Picard, after a very emotionally draining conversation, chooses to head into this space rather than going straight upstairs to his cabin or to his study on the holodeck.
(Yes, I know the Doylist answer is because it was the more dramatically satisfying blocking/staging choice, but on this blog, we like to dig for Watsonian explanations, too!)
My personal guess is still that there's some communal washroom down there, because those have to be somewhere on the ship, and that space would actually make sense, being in such close proximity to the bridge and mess hall.
But, since we never saw any of it on screen (and won't ever see La Sirena on screen again), I guess the space under the bridge will always remain a canonical mystery -- and thus available for any interpretation your writing /mapping/ headcanon might require ;)
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The Ubiquiti U7-Pro-XGS: A New Benchmark for WiFi 7 Access Points
As enterprise networks scale to accommodate more devices, higher bandwidth demands, and mission-critical wireless applications, the need for robust, high-capacity access points has never been greater. Ubiquiti's U7-Pro-XGS answers that call as a ceiling-mounted, 8-stream WiFi 7 access point engineered for serious UniFi deployments.
Built for Density and Speed
The Ubiquiti U7-Pro-XGS delivers high-performance wireless connectivity through tri-band WiFi 7 technology, supporting simultaneous operation across the 2.4GHz, 5GHz, and 6GHz bands. This tri-band architecture allows the access point to intelligently distribute client devices across less congested spectrum, which is especially valuable in environments like offices, schools, or hospitality venues where hundreds of devices may compete for airtime. With support for 500+ clients and coverage spanning roughly 160 square meters, the device is clearly designed with density in mind rather than just raw speed.
Speaking of speed, the numbers are substantial. The access point can push data rates up to 8.6 Gbps on the 5GHz band and 5.8 Gbps on 6GHz, figures that reflect just how far WiFi 7 has pushed wireless throughput compared to previous generations.
A Standout Feature: Dedicated Spectral Scanning
What sets the U7-Pro-XGS apart from many competing access points is its dedicated spectral-scanning radio, which helps analyse RF conditions while the main radios continue serving client devices. Rather than pausing service to check for interference, the AP can monitor the radio environment in real time, giving network administrators clearer visibility into signal quality, rogue devices, and channel congestion without sacrificing performance.
Wired Backbone to Match Wireless Ambition
A powerful WiFi radio is only as good as the wired connection feeding it. The U7-Pro-XGS includes a 10/5/2.5/1 GbE RJ45 Ethernet port and is powered via PoE++, delivering both power and data over a single cable. This flexible uplink ensures the access point won't become a bottleneck even as multi-gigabit client speeds become more common, while PoE++ simplifies installation by eliminating the need for a separate power source.
Built to Last
Ubiquiti hasn't skimped on durability either. The unit features a UV-stabilized polycarbonate and aluminium alloy enclosure, paired with stainless steel and galvanised steel mounting hardware for long-term reliability, making it well-suited to demanding indoor commercial installations that must hold up over years of continuous operation.
Seamless UniFi Integration
Perhaps the biggest advantage for existing Ubiquiti customers is how effortlessly the U7-Pro-XGS slots into the ecosystem. Fully managed through UniFi Network, it integrates seamlessly into existing UniFi environments, making it well-suited for enterprise, education, hospitality, and other professional wireless deployments. For organizations already running UniFi switches and gateways, adding this access point means centralized management, consistent firmware updates, and a unified dashboard rather than juggling separate vendor tools.
The Ubiquiti U7-Pro-XGS represents a compelling option for organizations ready to make the leap to WiFi 7. Its combination of high client capacity, multi-gigabit wired uplink, dedicated spectral analysis, and rugged construction makes it a strong fit for demanding, high-density environments where reliability and future-proofing matter as much as raw speed.
Smart homes rely heavily on stable internet connections. A mesh WiFi router ensures that all IoT devices stay connected without interruptions.
With multiple nodes distributing the signal evenly, mesh WiFi routers handle smart lights, cameras, thermostats, and voice assistants efficiently.
The system prioritizes traffic and reduces interference, ensuring reliable operation. Centralized control allows users to manage all connected devices easily.
For smart homes, a mesh WiFi router provides the reliability and performance required for automation and control.
Mesh WiFi for Mine Digital Transformation and Industry 4.0
Mesh WiFi for mine digital transformation supports the adoption of Industry 4.0 technologies in mining operations. As mines embrace automation, AI, and data analytics, reliable wireless connectivity becomes essential. Mesh WiFi provides the performance and scalability needed to support these advanced systems.
Automated machinery, remote-controlled vehicles, and AI-driven monitoring tools depend on low-latency and high-availability networks. Mesh WiFi ensures seamless connectivity across all operational zones. Centralized management allows IT teams to optimize network performance and maintain security.
By enabling digital workflows and real-time insights, mesh WiFi for mine digital transformation helps improve productivity, reduce costs, and enhance safety.
High Performance Wireless Mesh WiFi Network Built for Speed, Stability, and Scale
A high performance wireless mesh WiFi network is engineered to deliver fast, stable, and uninterrupted wireless connectivity across large or complex environments. Instead of depending on a single router, this network architecture uses multiple intelligent mesh nodes that cooperate to form one unified system. Each node acts as both an access point and a traffic relay, ensuring continuous coverage and optimized data flow.
What sets a high performance mesh network apart is its advanced radio design. Multi-radio and multi-channel architectures reduce interference and prevent congestion, allowing data to move efficiently between nodes. Dedicated wireless backhaul ensures that inter-node communication does not interfere with client device traffic, preserving high speeds even as the network expands.
Performance consistency is a key advantage. Intelligent routing algorithms continuously evaluate link quality and automatically select the best path for data transmission. This results in low latency, reduced packet loss, and stable throughput—critical for applications such as video conferencing, cloud computing, online gaming, and industrial automation.
Scalability is another defining feature. As coverage requirements grow, additional mesh nodes can be deployed without reconfiguring the entire network. The system self-optimizes to balance traffic and maintain performance across all nodes. This makes the network ideal for homes, enterprises, campuses, warehouses, and outdoor deployments.
Reliability is enhanced through self-healing capabilities. If a node fails or encounters interference, traffic is instantly rerouted through alternate nodes, minimizing downtime. Centralized management tools provide real-time visibility into network health, device usage, and performance metrics, enabling proactive optimization and maintenance.
Overall, a high performance wireless mesh WiFi network delivers the flexibility, resilience, and speed required for today’s always-connected environments, making it a future-proof solution for demanding wireless applications.
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WiFi 6 vs WiFi 6E: Which Delivers the Fastest Mesh WiFi?
WiFi 6 and WiFi 6E are both designed for high-performance networks, but they differ in how they deliver the fastest mesh WiFi experience. Understanding these differences helps users choose the right system for their needs.
WiFi 6 improves efficiency on existing bands by introducing OFDMA, MU-MIMO, and better power management. It is ideal for homes with many connected devices, delivering faster speeds and reduced congestion compared to older standards.
WiFi 6E extends these benefits into the 6 GHz band, which is less crowded and offers wider channels. This results in higher throughput and lower latency, making WiFi 6E mesh systems some of the fastest available today.
The fastest mesh WiFi systems often combine WiFi 6E with tri-band or quad-band designs. This allows devices and backhaul traffic to operate on separate, interference-free channels.
For future-proofing, WiFi 6E provides a significant advantage, especially in dense urban environments. However, WiFi 6 remains a strong option for users seeking speed and reliability at a lower cost.
Both standards deliver excellent performance, but WiFi 6E currently represents the peak of fastest mesh WiFi technology.
Mesh WiFi Router Explained: How It Works and Why You Need One
A mesh WiFi router works by creating a network of interconnected nodes that act as a single, powerful wireless system. Unlike traditional routers that broadcast signals from one location, a mesh WiFi router spreads coverage evenly by allowing nodes to communicate with each other and share data efficiently.
Each node in a mesh WiFi router system functions as both a receiver and transmitter. This design ensures that data can travel through multiple paths, maintaining strong connections even if one node experiences interference. The result is improved reliability and consistent speeds across the network.
This technology is especially useful for modern homes filled with smart devices. A mesh WiFi router can manage multiple simultaneous connections without slowing down performance. Intelligent load balancing ensures fair bandwidth distribution, keeping all devices running smoothly.
Installation is simple and user-friendly. Most mesh WiFi router systems offer app-based setup and management, allowing users to customize settings, monitor usage, and enhance security with minimal effort.
If you want stable coverage, fast speeds, and a network that adapts to your needs, a mesh WiFi router is an essential upgrade for any connected environment.