When I play Virtua Tennis 2 in 2024, all I can see is physics. Once considered cutting edge graphics, Virtua Tennis 2 (also known as Tennis 2K2 in the USA and Power Smash 2 in Japan) on the SEGA Dreamcast presents the sport of tennis in a brightly colored visual format. The visuals emphasize its gameplay with sharp color contrasts, clearly defining the boundaries of its world in-play. My attention naturally narrows in on the action.
Perhaps more notable, is the tennis ball, traced with shadows and motion blur. It contrasts well with the matte-painted courts. There is minimal visual distortion and so the ball is easy to track. In turn, Virtua’s batted-ball physics have unexpectedly captured my attention and my imagination. And so I ask: what kind of shots can I pull off in this old-school arcade game?
Agents of Science
As game players in VT 2, we inhabit its Virtua world through the agency of digitized tennis stars. We not only compete in matches, but we experiment — with different shots, we leverage different angles, and we impose varying levels of force upon the spinning green globe. We can explore what is possible within the game’s white-painted lines.
In a way, us sports gamers unwittingly become sport-scientists, probing the hidden laws of gravity embedded within the source code of this SEGA Sports tennis universe. We can study the game engine’s rules through trial and error, akin to scientific inquiry in a digital medium.
The ball’s physics stood out to me the moment I powered on the game this past May. Now, it is all I see. Perhaps I’ll never glimpse Virtua’s actual source code, nor would I comprehend it, but games like VT 2 encourage us to ask questions about what’s achievable simply by playing.
As game players in VT 2, we inhabit its Virtua world through the agency of digitized tennis stars. We not only compete in matches, but we experiment — with different shots, we leverage different angles, and we impose varying levels of force upon the spinning green globe. We can explore what is possible within the game’s white-painted lines.
In a way, us sports gamers unwittingly become sport-scientists, probing the hidden laws of gravity embedded within the source code of this SEGA Sports tennis universe. We can study the game engine’s rules through trial and error, akin to scientific inquiry in a digital medium.
The ball’s physics stood out to me the moment I powered on the game this past May. Now, it is all I see. Perhaps I’ll never glimpse Virtua’s actual source code, nor would I comprehend it, but games like VT 2 encourage us to ask questions about what’s achievable simply by playing.
Virtua Tennis 2 upscaled in 4K on PC via ReDream software. SEGA | Hitmaker | 2001. |
Play and Discover
Virtua Tennis, with its smooth 128-bit color pallets, has a way of presenting the game of tennis in an elegantly clean form. The gameplay screen has just the right amount of information. Free from noise and commentary, VT 2 allows players to play tennis from a bird’s eye perspective — one that hones in on the fundamentals of tennis. Consequently, the game’s clean virtual court feels like an ideal test environment for game players to search for new ways to manipulate the ball and score points.
Further, when us sports gamers test new animations or explore game mechanics, we inadvertently sample the physics of the virtual world we inhabit. If we think about it, SEGA Sports gave us the ability to hypothesize and actively observe what is possible on its digital tennis court. Hence why the game can be viewed as a sports science sandbox, and the different shot types are the center of our experiments.
I once read that the beauty in sport can be found in its improvisation; and what is improvisation? Is it not a spontaneous hypothesis and inquiry into what is possible in a given moment; in a given circumstance? Virtua Tennis has glimmer of this magic.
I think it makes sense to think about games as our own test environments when we consider how the games are built. The development kits of the games themselves may speak more directly to the idea of 3D sports games as sports science test environments. For example. engineers test locomotion and physics in test environments before installing into the final build of a sports game. Scientific inquiry is already taking place at this stage.
To provide a specific example, we can look at one engineer’s public doctorial research. Data Scientist Sebastian Starke researche(s) data-driven character animation and deep learning as a part of his Ph.D. program at the University of Edinburgh, School of Informatics. Stark tests animations and physics in 3D test environments such as Unity engine, attempting to simulate the human body and its movements. Circumstantial evidence suggests Stark’s research contributed to Electronic Arts’ HyperMotion technology for their industry leading EA Sports FC and Madden NFL games.
Taking it one step further, I cannot help but wonder if sports game engines like Stark’s can help researchers study real-world sports-related phenomena. In theory, if we input the properties and physics accurately into a 3D modeling system such as a sports game engine, perhaps the game can become something else entirely. “Legend, Mr. Wayne.” Speaking of which, The Legend of Zelda: Tears of the Kingdom’s in-game engineering mechanics are being used to teach masters students about machine structure and design at the University of Maryland. The precedent for real-world application is there. Games can teach us things.
It follows that sports gamers are just one step removed from the technical side to sports gaming science where scientific inquiry clearly and purposefully takes place in the development stage. Comparatively, I contend that VT 2, with its hyper-efficient gameplay, would make for an amazing starter development kit in 2024 to trial new physics and animations.
And so Virtua Tennis 2 is more than a game to me. It is an example of what was possible in 2001, and simultaneously a promise of what our sports games can be. Maybe games like Virtua Tennis had more utility than many of us realized when it was released.
I like to romanticize about sports and gaming. And the potential for sports games to take on a new form and function — to support scientific inquiry — is one of my favorite possibilities for the genre.
Virtua Tennis, with its smooth 128-bit color pallets, has a way of presenting the game of tennis in an elegantly clean form. The gameplay screen has just the right amount of information. Free from noise and commentary, VT 2 allows players to play tennis from a bird’s eye perspective — one that hones in on the fundamentals of tennis. Consequently, the game’s clean virtual court feels like an ideal test environment for game players to search for new ways to manipulate the ball and score points.
Further, when us sports gamers test new animations or explore game mechanics, we inadvertently sample the physics of the virtual world we inhabit. If we think about it, SEGA Sports gave us the ability to hypothesize and actively observe what is possible on its digital tennis court. Hence why the game can be viewed as a sports science sandbox, and the different shot types are the center of our experiments.
I once read that the beauty in sport can be found in its improvisation; and what is improvisation? Is it not a spontaneous hypothesis and inquiry into what is possible in a given moment; in a given circumstance? Virtua Tennis has glimmer of this magic.
Serena Williams, Virtua Tennis 2. SEGA | Hitmaker | 2001. |
To provide a specific example, we can look at one engineer’s public doctorial research. Data Scientist Sebastian Starke researche(s) data-driven character animation and deep learning as a part of his Ph.D. program at the University of Edinburgh, School of Informatics. Stark tests animations and physics in 3D test environments such as Unity engine, attempting to simulate the human body and its movements. Circumstantial evidence suggests Stark’s research contributed to Electronic Arts’ HyperMotion technology for their industry leading EA Sports FC and Madden NFL games.
Taking it one step further, I cannot help but wonder if sports game engines like Stark’s can help researchers study real-world sports-related phenomena. In theory, if we input the properties and physics accurately into a 3D modeling system such as a sports game engine, perhaps the game can become something else entirely. “Legend, Mr. Wayne.” Speaking of which, The Legend of Zelda: Tears of the Kingdom’s in-game engineering mechanics are being used to teach masters students about machine structure and design at the University of Maryland. The precedent for real-world application is there. Games can teach us things.
It follows that sports gamers are just one step removed from the technical side to sports gaming science where scientific inquiry clearly and purposefully takes place in the development stage. Comparatively, I contend that VT 2, with its hyper-efficient gameplay, would make for an amazing starter development kit in 2024 to trial new physics and animations.
Animation testing by data scientist and sports game engine developer, Sebastian Stark, 2021 — in Unity. |
I like to romanticize about sports and gaming. And the potential for sports games to take on a new form and function — to support scientific inquiry — is one of my favorite possibilities for the genre.
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