Mountain climbing. Increases social skills, teamwork and trust.

Building a house. Increases spatial visualization and planning skills.

Electronics. Increases mathematical and problem solving skills.

Chemistry. Increases precision and analytical reasoning skills.

Psychedelic drugs. Increases imagination, inspiration and abstraction skills.

Note that the example tags for rants includes Xcode... There is a reason.

In 1984 Apple introduced Macintosh and we got a computer that could barely handle multiple windows on the screen. But by 1986 multiple windows all over the place.

In 1985 Microsoft introduced Window 1.0 Yes boys and girls, no "s" because it hand only one Window. 7 years later in 1992 Microsoft got their head out of their ass and produced "MDI" or Multiple Document Interface and woohoo, had multiple windows on the screen... big boy pants 8 years after Mac.

Today we have Xcode from Apple. The old Window 1.0 engineers are apparently alive and well as Xcode is a One Window Trick Pony and if you fight with it, it starts randomly jamming your separate Windows into tabs into one window, completely fucking up your spatial organization of your working source code.

It is like the bastards going into a blind man's house and re-arranging his furniture for fun.

Xcode - it's only free if your time is worth absolutely nothing.

Im listening to 8D music (sound vibrations in 8 dimensions) and it is weird as fuck

Feels like i am in a giant and small room in the same time, at place A while being at place B in the same time because the vibrations cycle around you to create an illusion of offset spatial divergence

Just finished a little proof of concept of a reprojected multisample antialiasing technique and daaaaamn it's looking good. First time ever a rendering technique I invented isn't complete shit so that's an improvement

It still has some (pretty big) issues with both spatial and temporal ghosting but I have some ideas in the pipeline

I wish I could show you guys comparison images but as it turns out most anti aliasing techniques look pretty good on still frames but only the good ones stand up under motion and I don't know of a good way right now to capture pixel perfect clips like that

More from my big black book of ai and neuroscience:

I think if trace theory is true to any degree it would go some distance in explaining phenomenal consciousness, assuming I haven't misunderstood anything.

In fuzzy trace theory (FTT) it is posited that people form two types of mental representations about a past event:

*verbatim traces: detailed representations of a past event.

*gist traces: fuzzy representations of a past event.

People can reason with verbatim *and* gist traces but prefer gists.

*vision was suggested to work similarly in 1999. With human vision, two processes could be used: one that aggregates local receptive fields and one that parses the local receptive spatial field. It was suggested that people used prior experience, gists, to decide which dominates a perceptual decision.

Gist processes form representations of events, semantic details, where verbatim reinstates the context found in the surface details of an event.

__notes__

Parallel storage: asserts encoding/storage of verbatim/gist traces operate in *parallel*, not in serial.

I like to think of verbatim traces as databases, and gists as queries constructed by recognition.

Several studies have found that the meaning (gist) of an item is encoded even *before* the surface details (verbatim).

This might be important as a survival mechanism but should not be taken to mean strictly that gists are formed wholly *without* details or important and recognizable features of the item in question. It may well be for high level el processing and classification efficiency this may be an important reprocessing step, in the same way that many functions of the brain are duplicated throughout.

Design in Motion: Real-Time Rendering's Impact on Architecture

Architecture, a discipline that once relied heavily on blueprints, models, and lengthy render times, has undergone a revolutionary transformation in recent years. The advent of real-time rendering technology has fundamentally altered the way architects visualize, present, and interact with their designs. This paradigm shift has not only enhanced the creative process but has also empowered architects to make more informed decisions and create immersive experiences for clients and stakeholders.

Real-time rendering, a technological marvel that harnesses the power of high-performance graphics hardware and advanced software algorithms, allows architects to generate photorealistic visualizations of their designs in a matter of milliseconds. Gone are the days of waiting hours or even days for a single rendering to complete. This acceleration in rendering time has not only expedited the design process but has also encouraged architects to explore multiple design iterations rapidly.

One of the most significant impacts of real-time rendering on architecture is the ability to visualize a design in various lighting conditions and environmental settings. Architects can now instantly switch between daytime and nighttime lighting scenarios, experiment with different materials, and observe how their designs respond to different seasons or weather conditions. This level of dynamic visualization offers insights into how a building's appearance and functionality evolve throughout the day, contributing to more holistic and thoughtful design solutions.

Moreover, real-time rendering has transformed client presentations. Architectural concepts can now be communicated with unprecedented clarity and realism. Clients can virtually walk through spaces, observing intricate details, exploring different angles, and even experiencing the play of light and shadow in real-time. This immersive experience fosters a deeper understanding of the design intent, enabling clients to provide more targeted feedback and make informed decisions.

The impact of real-time rendering on collaboration within architectural teams cannot be overstated. Traditionally, architects and designers would need to wait for a rendering to complete before discussing design changes or improvements. With real-time rendering, team members can make adjustments on the fly, observing the immediate effects of their decisions. This seamless collaboration not only enhances efficiency but also encourages interdisciplinary collaboration as architects, engineers, and other stakeholders can work together in real-time to refine designs.

The integration of virtual reality (VR) and augmented reality (AR) into the architectural workflow is another transformative aspect of real-time rendering. Architects can now create VR environments that allow clients to step inside their designs and explore every nook and cranny. This not only enhances client engagement but also enables architects to identify potential design flaws or spatial issues that might not be apparent in 2D drawings. AR, on the other hand, overlays digital information onto the physical world, facilitating on-site decision-making and construction supervision.

Real-time rendering's impact extends beyond the design phase. It has proven to be a valuable tool for public engagement and community involvement in architectural projects. By creating virtual walkthroughs of proposed structures, architects can offer the public an opportunity to experience the design before construction begins. This transparency fosters a sense of ownership and allows for constructive feedback, contributing to the development of designs that resonate with the community's needs and aspirations.

The environmental implications of real-time rendering are also noteworthy. The ability to visualize designs in various environmental contexts contributes to more sustainable architecture. Architects can assess how natural light interacts with interior spaces, optimizing energy efficiency and reducing the need for artificial lighting during the day.

In conclusion, real-time rendering has ushered in a new era of architectural design, propelling the industry into a realm of dynamic visualization, immersive experiences, and enhanced collaboration. The ability to witness designs in motion, explore different lighting conditions, and interact with virtual environments has redefined how architects approach their craft. From facilitating client presentations to fostering sustainable design solutions, real-time rendering's impact on architecture is profound and multifaceted. As the technology continues to evolve, architects have an unprecedented opportunity to push the boundaries of creativity, efficiency, and sustainability in the built environment.

When i took CS operating system class few years ago there was discussion on layout of memory and how to retrieve things faster. There was a point where we were asked question on locality and i was first to shoot my hand and prof looked at me : i was eager to answer locality of refrences, i knew temporal locality but i forgot the other one. That is when he told me to remeber Einstein and his space time principal. Instantly i remembered spatial locality. Till this date after so many years i remeber the concept! Woohoo to all the awesome teachers!!

Math Doctor: The Best Math Tutoring Services Near You in Toronto

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As urban infrastructure projects venture deeper beneath city streets, the need for reliable compact power solutions becomes vital. An Industrial concealed socket system provides robust, low profile outlets integrated directly into tunnel walls, ensuring uninterrupted power for lighting rigs, ventilation units and monitoring equipment. In rapidly expanding underground networks—from subway expansions to utility corridors—the capacity to deliver stable power while minimizing spatial footprint drives both safety and efficiency efforts.

Tunnels demand equipment that withstands high humidity, dust and occasional splashes without compromising performance. A recessed socket module sealed with durable gaskets offers IP rated protection, keeping internal contacts free of debris and corrosion. By embedding these modules flush with concrete or prefabricated panels, installers eliminate protruding covers that might snag maintenance cables or equipment trolleys. The result is a sleek interface that blends seamlessly into the hardened environment, reducing trip hazards and simplifying cleaning routines in confined spaces.

In smart city initiatives, underground spaces host sophisticated sensor networks that track air quality, structural movement and lighting intensity. Each sensor node relies on local power access, making strategically placed concealed sockets indispensable. Modular socket clusters enable technicians to add or relocate outlets alongside fiber optic junctions and network switches, supporting rapid deployment of IoT devices without extensive wiring overhauls. This flexibility accelerates modernization efforts, letting urban planners upgrade systems in existing tunnels with minimal disruption to transit services.

Safety protocols in subterranean environments prioritize rapid isolation of faulty circuits. Concealed socket panels can house miniature protective devices that trip at the first sign of overload or short. Clear labeling and color coded terminals inside the enclosure guide service crews during inspections, while lockable covers prevent unauthorized access. These features ensure that power faults do not escalate into equipment failures or fire risks, maintaining safe operational conditions even amid high traffic subway platforms and service galleries.

Maintenance efficiency also benefits from quick release mounting systems. Technicians working under tight schedules appreciate panels that slide out of their housings on guide rails, granting direct access to wiring without chiseling out concrete or dismantling support frames. A captive fastener design keeps screws linked to the cover, preventing lost hardware in hard to reach areas. Such user friendly details reduce downtime for lighting lamp replacements or duct sensor recalibrations, keeping tunnel inspections on schedule.

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As cities push for resilient underground networks to meet rising transit and utility demands, the right power distribution approach becomes a cornerstone of project success. By choosing sleek, durable modules designed for harsh subterranean conditions, engineers deliver a safer, more adaptable environment for both equipment and personnel. For tailored industrial concealed socket solutions that support underground innovation, explore Nante.