One who knows the truth is always certain that it is the senses that are engaged in observations, like seeing, hearing, smelling, touching, and tasting and is the involuntary participant of the actions happening around, just like opening and closing of eyelids. Such observations are not the part of the ultimate knowledge, but, when a seeker looks beyond them, finds the ultimate truth.

—The Bhagavad Gita (5.8 and 5.9)

Ernestina Cianca
Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Maurizia De Bellis
Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Enrico Del Re
Department of Information Engineering, University of Florence, Florence, Italy

Mauro De Sanctis
Interdepartmental Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Edoardo Di Maggio
I‐CTIF Steering Board (LAW‐Intellectual Property), Rome, Italy

Sudhir Dixit
CTIF Global Capsule (CGC), Rome, Italy Basic Internet Foundation, Oslo, Norway

Liljana Gavrilovska
Ss. Cyril and Methodius University in Skopje, Skopje, Macedonia

Bilal Habib
Wildlife Institute of India, Dehradun, India

Flemming Hynkemejer
RTX A/S, Wireless Wisdom, Norresundby, Denmark

Sara Jayousi
Department of Information Engineering, University of Florence, Florence, Italy

Geir M. Køien
Faculty of Engineering and Science, Department of ICT, University of Agder, Kristiansand, Norway

Pierpaolo Loreti
Interdepartmental Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Pradeep K. Mathur
Wildlife Institute of India, Dehradun, India

Prateek Mathur
CTIF, Aalborg University, Aalborg, Denmark

Helga E. Melcherts
Varias BVBA, Antwerp, Belgium

Albena Mihovska
Department of Electronic Systems CTIF, Aalborg University, Aalborg, Denmark

Seshadri Mohan
Systems Engineering, University of Arkansas at Little Rock, Little Rock, AR, USA

Simone Morosi
Department of Information Engineering, University of Florence, Florence, Italy

Lorenzo Mucchi
Department of Information Engineering, University of Florence, Florence, Italy

Federica Paganelli
CNIT, Research Unit of Florence, Florence, Italy

Milica Pejanovic
Faculty of Electrical Engineering, University of Montenegro, Podgorica, Montenegro

Ramjee Prasad
CTIF Global Capsule (CGC), Rome, Italy; School of Business and Social Sciences, Aarhus University, Aarhus, Denmark

Silvano Pupolin
Department of Information Engineering, University of Padua, Padua, Italy

Valentin Rakovic
Ss. Cyril and Methodius University in Skopje, Skopje, Macedonia

Luca Simone Ronga
CNIT, Research Unit of Florence, Florence, Italy

Marina Ruggieri
Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Gianpaolo Sannino
Center for Teleinfrastructures (I‐CTIF), University of Rome “Tor Vergata,” Rome, Italy

Sachin Sharma
Systems Engineering, University of Arkansas at Little Rock, Little Rock, AR, USA

Domenico Siciliano
Themis Law Firm, Rome, Italy

Dr. Sudhir Dixit recently joined the CTIF Global Capsule (CGC) as the Director of Home for Mind and Body, an international centre for peace, located in Rome, Italy. Additionally, he is a Fellow and Evangelist of basic Internet at the Basic Internet Foundation in Norway. He has also been the CEO and Cofounder of Skydoot, Inc., a start‐up at San Francisco Bay area in the content sharing and collaboration space. From December 2013 to April 2015, he was a Distinguished Chief Technologist and CTO of the Communications & Media Services for the Americas region of Hewlett Packard Enterprise Services in Palo Alto, CA, and prior to this he was the Director of Hewlett Packard Labs India from September 2009. From June 2009 to August 2009, he was a Director at HP Labs in Palo Alto. Prior to joining HP Labs Palo Alto, Dixit held a joint appointment with the Centre for Internet Excellence (CIE) and the Centre for Wireless Communications (CWC) at the University of Oulu, Finland. From 1996 to 2008, he held various positions with leading companies, such as with BlackBerry as Senior Director (2008), with Nokia and Nokia Networks in the United States as Senior Research Manager, Nokia Research Fellow, Head of Nokia Research Center (Boston), and Head of Network Technology (USA) (1996–2008). From 1987 to 1996, he was at NYNEX Science and Technology and GTE Laboratories (both now Verizon Communications) as a Staff Director and Principal Research Scientist.

Sudhir Dixit has 21 patents granted by the US PTO and has published over 200 papers and edited, coedited, or authored seven books (Wireless World in 2050 and Beyond: A Window into the Future (2016), Wi‐Fi, WiMAX and LTE Multi‐hop Mesh Networks by Wiley (2013), Globalization of Mobile and Wireless Communications by Springer (2011), Technologies for Home Networking by Wiley (2008), Content Networking in the Mobile Internet by Wiley (2004), IP over WDM by Wiley (2003), and Wireless IP and Building the Mobile Internet by Artech House (2002)). He is presently on the editorial boards of IEEE Spectrum Magazine, Cambridge University Press Wireless Series, and Springer’s Wireless Personal Communications Journal and Central European Journal of Computer Science (CEJS). He was a Technical Editor of IEEE Communications Magazine (2000–2002 and 2006–2012). He is a two‐time winner of the MIT’s Technology Review India Grand Challenge Award (2010).

From 2010 to 2012, he was an Adjunct Professor of Computer Science at the University of California, Davis, and, since 2010, he has been a Docent of Broadband Mobile Communications for Emerging Economies at the University of Oulu, Finland. A Life Fellow of the IEEE, and a Fellow of IET and IETE, Dixit received a Ph.D. degree in electronic science and telecommunications from the University of Strathclyde, Glasgow, UK and an M.B.A. from the Florida Institute of Technology, Melbourne, Florida. He received his M.E. degree in Electronics Engineering from Birla Institute of Technology and Science, Pilani, India, and B.E. degree from Maulana Azad National Institute of Technology, Bhopal, India.

Dr. Ramjee Prasad is a Professor in multibusiness model and technology innovation in the School of Business and Social Sciences, Aarhus University, Denmark. He is the Founder President of the CTIF Global Capsule (CGC). He has been a Founder Director of Center for TeleInFrastruktur (CTIF) since 2004. He is also the Founder Chairman of the Global ICT Standardisation Forum for India, established in 2009. GISFI has the purpose of increasing the collaboration between European, Indian, Japanese, North‐American and other worldwide standardization activities in the area of information and communications technology (ICT) and related application areas.

He was the Founder Chairman of the HERMES Partnership —a network of leading independent European research centers established in 1997, of which he is now the Honorary Chair. He is a Fellow of IEEE (USA), IETE (India), IET (UK), and Wireless World Research Forum (WWRF) and a member of the Netherlands Electronics and Radio Society (NERG) and the Danish Engineering Society (IDA).

He has received Ridderkorset af Dannebrogordenen (Knight of the Dannebrog) in 2010 from the Danish Queen for the internationalization of top‐class telecommunication research and education. He has been honored by the University of Rome Tor Vergata, Italy, as a Distinguished Professor of the Department of Clinical Sciences and Translational Medicine on March 15, 2016.

He has received several international awards such as IEEE Communications Society Wireless Communications Technical Committee Recognition Award in 2003 for making contribution in the field of “Personal, Wireless and Mobile Systems and Networks”; Telenor's Research Award in 2005 for impressive merits, both academic and organizational within the field of wireless and personal communication; 2014 IEEE AESS Outstanding Organizational Leadership Award for “Organizational Leadership in developing and globalizing the CTIF (Center for TeleInFrastruktur) Research Network”; and so on.

He is the Founder Editor in Chief of the Springer International Journal on Wireless Personal Communications. He is a member of the editorial board of other renowned international journals including those of River Publishers. Ramjee Prasad is Founder Cochair of the steering committees of many renowned annual international conferences, for example, Wireless Personal Multimedia Communications Symposium (WPMC) and Wireless VITAE and Global Wireless Summit (GWS).

He has published more than 30 books, 1000 plus journal and conference publications, and more than 15 patents and over 100 PhD graduates and a larger number of master’s students (over 250). Several of his students are today worldwide telecommunication leaders themselves.

Applications today have been enriched with multimedia content consisting of audio, video, augmented reality and consistently progressing toward multidimensional rendering, such as stereo, 3D, ultrahigh definition, and fidelity. In parallel, the user interaction with the devices and applications is delivering engaging experience through voice, gestures, gaze, touch, and so on. Wearable devices and body sensors are continually being integrated with applications and user devices, such as a smartphone, remote control, and finding useful applications in healthcare and remote monitoring. Humans interact with applications and consume content through optical and auditory senses. But the understanding is incomplete in the absence of information from and about the other three sensory inputs, namely, olfactory (smell), gustatory (taste), and tactile (touch). This is because all five senses interestingly interact among themselves and the environment, such that being able to sense them, transmit them, and render them at the receiver can potentially deliver powerful experiences. This book on human bond communication (HBC) is about utilizing all five senses to allow more expressive and holistic sensory information exchange through communication techniques for more human sentiment centric communication. The overall outcome is for the human brain to be holistically cognitive of the subject of interest. This complete perceptive information is well exchanged among humans through these senses and, when collectively agreed, becomes knowledge. This is the first book of its kind to motivate research and innovation in holistic communication and to launch a new era of novel products and services to disrupt the status quo of contemporary applications and services that only deal with aural and optical capture, transmission, and rendering of information.

This book focuses on all technologies and issues related to HBC. It also includes the use cases and business opportunities emanating from human‐to‐machine and machine‐to‐machine applications, interactions, and communication. The chapters have been authored by the experts in the various fields, which collectively would make HBC possible.

This book is intended for graduate students, academic teachers, scholars, researchers, industry professionals, and software developers interested in the design and development of more engaging and holistic interaction experiences. This book will also be of great interest to casual readers not necessarily familiar with sensor and communication technologies. Therefore, the content is more descriptive and qualitative than theoretical in style of writing.

We thank the contributors of this book for their time and effort to make this book possible in a short period of time. We particularly acknowledge their patience and for always responding promptly to numerous requests for revising their chapters.

1.1 Introduction

Information and communications technologies (ICT) have progressed rapidly in this millennium for people to communicate and exchange information using multimedia (speech, video/image, text), and the same has extended to Internet of things (IoT) and machine‐to‐machine and machine‐to‐human communication. This trend is only going to accelerate in the years to come with powerful human–computer interaction technologies to deliver engaging and intuitive experiences. But these developments have remained confined to only the sensing and transmission of aural and optical information in the digital domain through the use of microphone, camera, speaker, and display devices. However, the ability to integrate the other three sensory features, namely, olfactory (smell), gustatory (taste), and tactile (touch) in information transfer and replication to deliver “being there in‐person” experience, are still far from reality. Human bond communication (HBC) is a novel concept that incorporates all five sensory information from sensing, to digitization, to transmission and replication at the receiver to allow more expressive, engaging, realistic, and holistic information between humans [1] and in some cases between humans and machines such as in remote sensing and robotic control. Lack of inclusion of the other three senses in the digital world of ICT limits the full exploitation of the cognitive ability of the human mind for a fuller perceptive information experience. The five senses and the environment interact in interesting ways to become complete knowledge for human species as its brain has developed and evolved naturally from the time it came into existence on this planet. The profoundness of perceiving an object depends on the incisiveness and extensity of the sense organs. Incisiveness refers to the granularity and minute details or variations an organ can detect, and extensity refers to the range of the physical property that it can detect.

In the traditional world of digital information exchange, the subject is described and presented partially via its aural and optical rendering, which gives a sense of incompleteness and dissatisfaction in fully understanding the subject. In the present era of ever increasing competition through innovation, inclusion of all five senses to deliver complete experience is the holy grail of the research community. Products have begun to appear through wearables and other embedded sensors in the body, but sensors exploiting touch, taste, and smell and embedding them into products remains a distant reality and is an area of intense research today as would become evident from the chapters included in this book.

Auditory and optical sensing is wave based. In audio sound travels through waves and can be sensed and digitized. Similarly, light shining on an object is reflected in electromagnetic radiation, and a part of this spectrum (called visible light in the range of wavelength 390–700 nm) is visible to the human eye and when rendered on the retina becomes a visual formulation of the object in the nervous system. The camera does this nicely to capture an object visually and digitize it for transmission. When rendered remotely on a display device in 2‐D or 3‐D, a person can see the object as though he or she was seeing it by being physically present at a location where the camera was located. Other human senses (tactile, olfactory, gustatory) utilize particle‐based sensing and rely on smearing the object with the sensors. Building such sensors remains a technological challenge for the research community because each type of sensor must deal with large range of parameters and their wide spectrum. Digitization of these parameters is also a major challenge, and even if some finite widely prevalent values can be captured and digitized, their replication from the digital domain to the analog domain and their sensing by a person in an unobtrusive manner is a complex human‐sensor interface issue. Figure 1.1 illustrates the HBC system and depicts what is possible today and what is not.

HBC is about understanding the human sensory functionality and works similar to human sensory system, which includes providing a perceptually holistic understanding of an object combining all five senses while incorporating the object’s environment.

1.2 Human Bond Communication (HBC) Architecture

The HBS architecture extrapolates the contemporary communications architecture to include the missing three senses (or types of sensors): tactile, olfactory, and gustatory, not in use today along with the aural and optic sensors. Nevertheless, some limited deployments are happening in machine‐to‐machine and machine‐to‐human communication use cases where robots are being used, such as in industry, law enforcement, hazardous material handling, and surveillance. A proposed architecture is shown in Figure 1.2 [1]. It should be noted that the architecture goes beyond capturing just a person’s senses to also deploying all five types of sensors in any environment to capture smell (e.g., types of smoke, air pollutants), tactile information (e.g., surface roughness, temperature, wind speed), and taste (e.g., liquids, dirt, waste) and learning about an object or its surroundings.

The system consists of the three key building blocks: (i) senducers that sense the characteristic parameters through stimuli and transform those analog values to electrical and digital domain for further processing and transmission, (ii) human bond sensorium (HBS) that collects the data from the senducers, processes them to make them consumable for the human perceptive system (i.e., human consumption) by removing a large amount of nonusable and redundant data and information, transmits it to the far end to the receiver gateway, and (iii) human perceivable transposer (HPT) that transforms the received digital data to human consumable format, which includes replication of the senses to a form that one would expect if the person was physically present at the site where the sensory data were collected through senducers. Until such time the replication solutions are not available, the HPT may prefer to render the non‐audio–visual sense data through digital means (such as colors, emoticons, text, other gestures like vibration, pressure, temperature, etc.).