Finally the BlinkAdapt ShockCube project has come to a relative close, well the company and product presentation was conducted today and the official play test is next week. Our presentation was pretty strong with a good mix of hard financial fact and visual dressing, also the promo film went down pretty well with the audience.

Anyway here it is, still a work in progress and will be updated with new footage from the focus group/play tests next week. You can also watch it in HD by clicking the HD link in the video (it will take you to the official vimeo page).

Though not a cheap solution (£180 after tax) it was our only real option for a reliable touch system.

Right: Our first unsuccessful attempt. Left: Shiny new expert version

We are currently testing a combination of backgrounds and design features to get the best out of the equipment we have and should have something more appropriate soon. Below are some features of the first design draft which we are now revising.

First Design Draft

So the basic process is

Flash > Arduino > Relay > Ab toner

The ab toners purchased run off mains power, we have however hooked them up to battery packs to grant portability to the system and will hopefully make the shocks a little safer for ShockCube players. Another added safety measure we have incorporated are large emergency power buttons, which when activated shut power off to the ab toner completely. This is achieved mechanically with buttons that simply break the connection between ab toner battery pack.

White Vellum is our projection layer of choice due to a good balance of clarity and thickness, in the end Rosco Grey was just too thick to produce decent blobs. The vellum also came in a handy A0 size which almost matched the width of our table minus a few centimeters. With the projection surface finally down we sealed off the sides with the last IR ribbon section and used electrical tape to block out all interfering IR light. Furthermore we were at last able to mount the camera and mirror into fixed positions beneath the screen due to the surface layer being finished.

As things now stand we have a working touch table minus screen calibration, which will be our next task.

Our table as it stands now (projecting white)

Projector, IR Camera and Mirror all fixed into their final positions

The IR Camera can capture the whole surface at a distance of 1 meter

Silicon material tests

Coming out of the last experiment with a somewhat negative attitude we decided against jumping straight in and coating the entire 1m² area. Instead 3 separate mini tests were conducted using various surface layer materials that have been used in the touch table community. Rosco Grey, Vellum tracing paper and normal tracing paper were given 3 coats of the custom silicon mix, which took around 2 days to complete. Then on the third day using a small scrap of the newly silicon coated Rosco Grey, success! Then again with the tracing paper, success! Full “blob” detection with minimal finger pressure on a combined perspex, compliant and surfaced layered sandwich.

In theory all that needs to be done now is scale up the silcon layer to our requirements (which is currently in progress) and we should have a rather large and working touch table. However as this project has taught us many times, theory and practice are two distinctly different concepts.

Silicon ripples drying from the first of 3 separate coats

Sulky Solvy applied to Perspex

The Compliant layer however is a slightly more problematic concept. When you introduce a projection layer the effect of you finger on the perspex and thus the IR light refracting inside it is dampened. This results in a poor “blob” production and makes it difficult for the computer to recognise finger contact. So what has been dubbed as a “Compliant Surface” must be introduced underneath the projection layer to amplify finger contact by increasing the pressure with minimal user effort. Many compliant solutions have been dreamt up and the first one we attempted was called “Sulky Solvy”, a silicon based American product used in material stitching. So before the live test our set up was as follows…
<----- Rosco Grey ----->
<----- Sulky Solvy ----->
<----- Perspex ----->

It failed. No blobs, nothing. The failure was probably due to the size of our table as we are quickly realising through the online communities that this is one of the largest touch tables using the FTIR method ever attempted. With 2 weeks to go this is a minor disaster but there are a few more methods to try yet. However on a good note our new custom modified £150 PS3eye camera from the US works like a dream. More on that to come.

Bare Perspex, cleaned and ready

Silicon based Sulky Solvy applied

Only 3 IR strips were used for quick testing

Below you can find a full document overview of all the arduino work for ShockCube:

Arduino Overview Documentation

So after taking these requirements into consideration we sketched out an idea for a lightweight skeleton frame strengthened by struts to which external aesthetically pleasing panels could be attached. The beauty of this design is that it accommodates for our fairly limited wood working skills by hiding the frame and allowing us to experiment over the final weeks with various panels types (wood or metal). Then as a team of men we decided that it would definitely work and set off to B&Q. The wood used is standard construction wood cut to our previously discussed dimensions of 950mm x 900mm x 870mm, which should give 4 players ample space to operate with an audience.

ShockCube as you see it below took about 3 days to complete and is very much a work in progress. Construction has been halted for now as another specialist IR camera is in transit from the US after the moderate failure of the first one.

3 L brackets were used to secure each cube corner

IR ribbon sunk into the metal frame

Adjustable bracket for the projector

The access panel will be built around here

State of the ShockCube table now.

IR ribbon around the perspex

Obviously this light spectrum is invisible to human eyes, so instead we utilise an infra-red camera, which when directed at the perspex ignores all visible light and sees only a beautiful glowing shard of infra-red. Now due to the light refraction created inside the perspex any objects when pressed against it, such as the finger, visibly effects the refracted light creating a disturbance that can be tracked via computer software. These disturbances are then delivered to authoring programs like Adobe Flash as co-ordinates, forming the basis for a working touch table!

The IR disturbances can be tracked

Regarding the camera, our already burgeoning £800 budget didn’t allow for an off the shelf solution so we simply opted for modifying a PS3eye webcam. This solution is widely used for custom touch tables by removing the IR filter from the camera and replacing it with a visible light filter.

As for the perspex we had that laser cut to a 900mm x 950mm specification for and extortionate £100.

900mm x 950mm