Compactness, Durability and Mobility

Kanayama:

In developing the FGDP, our goal was to create a product around 30 × 30 cm in size, meaning something that can rest in your lap and be played comfortably with ten fingers. We also looked at it from the perspective of something that’s neither too small nor too large, and something that you can easily pick up and carry with you.

Tabata:

To achieve powerful sound and sufficient volume, we decided to increase the size of the built-in speaker and the speaker enclosure as much as possible, given that the product’s size had already been determined.

That said, trying to secure enough space for the speaker enclosure inside the chassis was like battling with the other components. In addition to the speaker enclosure, but the motherboard and the other components, as well as the bosses (the cylindrical pillars that support the top and bottom of the unit) required to ensure the unit’s durability had to all be packed inside.

It's normal for a product’s body and internal structure to evolve as development progresses, and we used a 3-D printer to create and optimize the speaker enclosure amidst these repeated changes of specifications. Specifically, we created a bass reflex port so that we could comfortably and powerfully achieve a strong low end that’s typical of bass drum sounds. Also, to have a clear sound without wind noise or standing waves that are prone to occur, we made repeated alterations such as changing the shape of the speaker enclosure so that the sounds within the speaker reflect randomly, and amending the placement of absorption materials.

After finalizing the specifications of the speaker enclosure, we fine-tuned the sound using digital processing.

Kimizuka:

Aside from the chassis, we conducted durability testing on the pads. These tests involved resistance to dust, heat, cold, and high and low humidity.

For these tests, we prepared extremely cold and extremely hot rooms, where we took turns going inside to pound away at the units. We knew that doing so for long periods of time would be dangerous, so we did this with multiple people and worked to ensure everyone’s safety. As a result, we confirmed that the instrument could withstand the rigors of all sorts of environments, so that people living in all kinds of places around the world would be able to enjoy playing it.

Hayafuchi:

We thought that the unit had to be rechargeable so that users could take it along and play whenever they liked, which is why we stipulated in our planned specs this time that the unit should be able to be powered through recharging.

At that time, we had our eyes set on a type of lithium-ion battery using lithium-iron Phosphate, which hadn’t really proliferated in the market when we started developing this model. This was because although lithium iron phosphate batteries are not quite as good as other common lithium ion batteries used in smartphones and electric vehicles in terms of energy density (capacity), they last longer and are safer by far. Lithium iron phosphate batteries are excellent from a safety perspective, considering that these batteries won’t ignite when players are mashing the pads countless times while they’re playing or when the player happens to drop the unit and subjects it to impact.

When we consider the user’s convenience and safety, lithium iron phosphate batteries have a clear advantage. However, when we started developing the FGDP there were few lithium iron phosphate batteries available on the market that suited our products, so we tried various approaches in our efforts to finalize the specifications, including searching for ICs to monitor remaining battery capacity that were appropriate for use with our products.

Kimizuka:

As far as battery capacity and overall longevity goes, after studying the issue at length we set our targets at three hours of battery life under continuous play at maximum volume. It’s been a real challenge, creating an instrument that checks all the boxes in terms of product convenience, safety, and longevity.