Home Projects Facilitating CamelBak’s connected product innovation strategy

Facilitating CamelBak’s connected product innovation strategy

Facilitating CamelBak's connected product innovation strategy

The Challenge

CamelBak provides a range of innovative hydration packs, backpacks, and water bottles.

Its consumers know when they buy CamelBak, they are purchasing a durable, high-quality product, but after purchase they may not interact with the brand for several more years.

Consumers are increasingly using digital technologies such as smart watches, phones, and apps to manage their lives. CamelBak has previously embarked on a few digital technology projects but has encountered a range of challenges in successfully developing connected products.

CamelBak wanted to understand how other natively ‘physical’ product companies successfully made the transition to complementary connected offerings; and how it should structure and guide its own innovation in connected products.

The Approach​

Through an Ignite Exponential Learning Exchange, we brought CamelBak’s senior R&D and Product Management team together with experienced corporate innovation leaders from our network who have successfully navigated similar challenges in their own industries.

We screened more than 100 companies to shortlist those from whom CamelBak could learn the most. We set up virtual meetings, briefed the participants, and moderated the discussions translating insights between industries and sharing our own experience.

After the meetings we helped CamelBak distil what we learned through collaborative virtual workshops and to build a strategic framework for innovating in connected devices, and for transitioning from a physical to ‘digitally connected’ organization.

The Outcome

Our approach allowed CamelBak to learn about the technical and commercial capabilities it would need, as well as the impact of ‘soft’ factors such as partnership, purpose, and organizational culture. By drawing directly on the real-world experience of non-competing leaders it was able to build its confidence and internal alignment in a strategy for future connected products. The programme also created a rich network of cross-industry peers that can provide partnership to CamelBak long after the meetings.

The Learning Exchange process really helped us to recognize the value of partnership. It was like being able to see the future – by learning from these other companies we could see the challenges we’d face and what it would take to succeed before we started our journey. Without doubt, the project goal was met and this is now one of the biggest opportunities we have as a brand.”

Director of R&D

CamelBak


Related Technical Papers

View All
an image of our technical paper
Metamaterial-Based Ku-Band Flat-Panel High-Grain

This technical paper by Dr. Rabbani and his team presents research on metamaterial-based, high-gain, flat-panel antennas for Ku-band satellite communications. The study focuses on leveraging the unique electromagnetic properties of metamaterials to enhance the performance of flat-panel antenna designs, aiming for compact structures with high gain and efficiency. The research outlines the design methodology involving multi-layer metasurfaces and leaky-wave antennas to achieve a compact antenna system with a realised gain greater than +20 dBi and an operational bandwidth of 200 MHz. Simulations results confirm the antenna's high efficiency and performance within the specified Ku-band frequency range. Significant findings include the antenna's potential for application in low-cost satellite communication systems and its capabilities for THz spectrum operations through design modifications. The paper provides a detailed technical roadmap of the design process, supported by diagrams, simulation results, and references to prior work in the field. This paper contributes to the advancement of antenna technology and metamaterial applications in satellite communications, offering valuable insights for researchers and professionals in telecommunications.

an image of our technical paper
Sensing Auditory Evoked Potentials with Non-Invasive Electrodes and Low-Cost Headphones

This paper presents a sensor for measuring auditory brainstem responses to help diagnose hearing problems away from specialist clinical settings using non-invasive electrodes and commercially available headphones. The challenge of reliably measuring low level electronic signals in the presence of significant noise is addressed via a precision analog processing circuit which includes a novel impedance measurement approach to verify good electrode contact. Results are presented showing that the new sensor was able to reliably sense auditory brainstem responses using noninvasive electrodes, even at lower stimuli levels.

Contact Plextek

Got a project in mind?

Let’s talk

If you have got a project to discuss, or even just an idea, let's talk