Strategies and practices for growing ecosystems are increasingly important in shaping industries and markets. Sustaining productive innovation is not just about you. It depends on others as well as your willingness and ability to collaborate effectively. This book is about how to use, as well as develop, a co-innovation platform to accelerate innovation and sustain ecosystem growth. It will show how you, your team and your organization can create and foster collaborative innovation among a diverse set of organizations that are located outside of your company's hierarchy. A co-innovation platform provides an environment where firms can combine or recombine ideas to generate novel solutions. A distinctive feature of the co-innovation platform is its resource-open and hands-on approach to innovation. For many organizations, resource limitations, organizational obstacles and/or time constraints kill an idea before it takes shape. By providing access to demand-side and supply-side resources and capabilities to facilitate co-innovation, the platform solves this problem and shapes the ecosystem's innovation trajectory from the ground up. This book provides strategic and practical guidance for orchestrating collaborative problem solving and ecosystem growth.

This exciting new book examines the feasibility of using a method of doubling the capacity of cellular networks by simultaneously transmitting and receiving signals at the same frequency, a process known as full duplexing (FD). To realize full duplexing, changes in the hardware of the cell- base stations, relaying equipment, "hot spot" access points and mobile phones are necessary to prevent the hardware's transmitters from interfering with their own receivers. This requires looking at how to separate the strong transmitted signal from the very weak received signal, a process requiring both hardware (analog) changes and more complex digital signal processing. Different ways of achieving that goal are examined. The books reviews the merits of hardware changes involving new duplexing components that may be different depending on the frequency band and cell hardware being used. Developing full duplex (FD) systems in 5G LTE cellular communications and what can be achieved with ferrite-based circulators in terms of size reduction and performance enhancement, especially at millimetric frequencies, is considered. The relative merits of ferrite and non-ferrite circulators are compared in terms of their fundamental materials and device technologies, such as isolation, insertion loss, bandwidth and non-linearity. FD in the entire 5G cell is also examined and its resulting range of equipment and device communication. This includes front-hauling, more sophisticated back and front-hauling, backhaul beam switching, and cell extenders and relays, all of which could involve FD.