Here are 57 books that The Music of Life fans have personally recommended if you like
The Music of Life.
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I have taught psychology in UK universities for over 35 years. I love finding a 'way in' to the subject for my students. I challenge them to find a passion, and I love seeing that passion 'take off' in someone. In my experience, these are five books that have helped psychology students (me included) to find their passion.
I was captivated by the first chapter of this book, which summarises the case for considering language to be a human instinct. I love the way that it deploys rational thought and evidence in pursuit of intriguing 'grand theorizing'. It's a compelling read and expertly constructed introduction to the psychology (and sociology) of language. It is also a case study in how to build arguments.
The diminishing role of rational thought and evidence-based argument in the wider political sphere is one of the greatest threats to our world. So, when we read books like this, we are not simply making a personal decision. We are also making a political statement about the kind of world we want to live in.
'Dazzling... Pinker's big idea is that language is an instinct...as innate to us as flying is to geese... Words can hardly do justice to the superlative range and liveliness of Pinker's investigations' - Independent
'A marvellously readable book... illuminates every facet of human language: its biological origin, its uniqueness to humanity, it acquisition by children, its grammatical structure, the production and perception of speech, the pathology of language disorders and the unstoppable evolution of languages and dialects' - Nature
It is April 1st, 2038. Day 60 of China's blockade of the rebel island of Taiwan.
The US government has agreed to provide Taiwan with a weapons system so advanced that it can disrupt the balance of power in the region. But what pilot would be crazy enough to run…
I’m a scientist at the University of Cambridge who’s worked on
environmental research topics such as jet streams and the Antarctic
ozone hole. I’ve also worked on solar physics and musical acoustics.
And other branches of science have always interested me. Toward the
end of my career, I became fascinated by cutting-edge issues in
biological evolution and natural selection. Evolution is far
richer and more complex than you’d think from its popular description
in terms of ‘selfish genes’. The complexities are central to
understanding deep connections between the sciences, the arts, and
human nature in general, and the profound differences between human
intelligence and artificial intelligence.
I was blown away by the vistas it opened across classic work on
genetics and palaeoanthropology, and the implications for
understanding how our ancestors evolved.
It also showed how the
politics of so-called ‘sociobiology’ impeded that understanding,
through acrimonious disputes that later turned out to be pointless.
Those disputes were very much examples of what I call
‘dichotomization’, the unconscious assumption that an issue is
binary, an either-or question, when in reality it is far more
complex with many different aspects.
You might not suspect it, but we are currently living through a revolution in scientific knowledge. What we know about the human brain's workings and about the earliest history of our distant humanoid ancestors changes almost weekly. A new view of humanity is being forged - new theories appear all the time, splinter, are revised and adandoned. Scientists from different fields of research are finally co-operating and sharing their insights in order to map out a new view of the human brain. Paleaoanthropologists digging in Kenya, neuropyschologists building organic robots in their labs and geneticists unearthing the secret in all…
I’m a scientist at the University of Cambridge who’s worked on
environmental research topics such as jet streams and the Antarctic
ozone hole. I’ve also worked on solar physics and musical acoustics.
And other branches of science have always interested me. Toward the
end of my career, I became fascinated by cutting-edge issues in
biological evolution and natural selection. Evolution is far
richer and more complex than you’d think from its popular description
in terms of ‘selfish genes’. The complexities are central to
understanding deep connections between the sciences, the arts, and
human nature in general, and the profound differences between human
intelligence and artificial intelligence.
It achieves an important and unusual cross-fertilization between two
very different kinds of expertise. Both authors are highly
innovative, and creative, thinkers, Cohen in biology and Stewart in
mathematics.
Cohen is a biologist fascinated by the complexity
observed in the living world, and Stewart is an expert on the
mathematics of chaos and complexity. The result is a profound and
multifaceted view of many natural phenomena, and of evolution in
particular. It becomes very clear how selfish-gene theory fails to
take account of important evolutionary mechanisms.
Moving on from his books on chaos ("Does God Play Dice?") and symmetry ("Fearful Symmetry"), the author of this book deals with the wider field of complexity theory. The book tackles the question of how complexity arises in nature, of how life overcomes chaos and entropy to create developing order. Co-written with biologist Jack Cohen, the book will range across the central areas of modern science, from quantum mechanics and cosmology to evolution and intelligence, looking at the central questions of order, chaos, reductionism and complexity.
A Duke with rigid opinions, a Lady whose beliefs conflict with his, a long disputed parcel of land, a conniving neighbour, a desperate collaboration, a failure of trust, a love found despite it all.
Alexander Cavendish, Duke of Ravensworth, returned from war to find that his father and brother had…
I’m a scientist at the University of Cambridge who’s worked on
environmental research topics such as jet streams and the Antarctic
ozone hole. I’ve also worked on solar physics and musical acoustics.
And other branches of science have always interested me. Toward the
end of my career, I became fascinated by cutting-edge issues in
biological evolution and natural selection. Evolution is far
richer and more complex than you’d think from its popular description
in terms of ‘selfish genes’. The complexities are central to
understanding deep connections between the sciences, the arts, and
human nature in general, and the profound differences between human
intelligence and artificial intelligence.
It’s a powerful update on Noble’s book, zooming in on the workings
of the biomolecular circuits surrounding the DNA.
Some of the
circuits are studied in great detail, looking closely at how they
work, and at how they evolve in response to mutations in the DNA. A
disadvantageous mutation is eliminated by natural selection. But as
well as advantageous mutations it turns out that ‘neutral’ mutations,
conferring no immediate advantage, are important and indeed crucial.
That resolved one of the dichotomized disputes noted in Wills’ book.
The power of Darwin's theory of natural selection is beyond doubt, it explains how useful adaptations are preserved over generations. But evolution's biggest mystery eluded Darwin: how those adaptations arise in the first place. Can random mutations over a 3.8 billion years be solely responsible for wings, eyeballs, knees, photosynthesis, and the rest of nature's creative marvels? And by calling these mutations 'random', are we not just admitting our own ignorance? What if we could now uncover the wellspring of all biological innovation?
Renowned evolutionary biologist Andreas Wagner presents the missing piece in Darwin's theory. Using cutting-edge experimental and computational…
Mathematics and chemistry were my strongest subjects at school, and I started programming computers when I was 16, but life seemed most important. Hence I studied biochemistry in university but moved into molecular biology with programming to assist the data analysis. My track record in successfully predicting new biology through computing led to a pharmaceutical company recruiting me to do bioinformatics for them. However, not content with studying genes and proteins, I pushed for bioinformatics to move up into metabolism, anatomy, and physiology. That’s when I discovered systems biology. My international reputation lies at this interface and includes discoveries in microbial physiology, botany, agriculture, animal biology, and antenatal diseases.
Of the various books available on this subject, I very much prefer this one because it makes it far easier to do systems biology.
First, it shows you how to view biological regulatory processes as a set of interacting components and their effect on each other. This alone can give clues to the behaviour of the system under different circumstances. However, it then goes on to show how these processes can be defined mathematically, which then enables us to get a quantitative view of what is going on.
When the predicted and observed numbers don’t match, we know that there is a gap in our knowledge and, hence, the place to discover new biology. Using this approach, I have.
... superb, beautifully written and organized work that takes an engineering approach to systems biology. Alon provides nicely written appendices to explain the basic mathematical and biological concepts clearly and succinctly without interfering with the main text. He starts with a mathematical description of transcriptional activation and then describes some basic transcription-network motifs (patterns) that can be combined to form larger networks. - Nature
[This text deserves] serious attention from any quantitative scientist who hopes to learn about modern biology ... It assumes no prior knowledge of or even interest in biology ... One final…
Mathematics and chemistry were my strongest subjects at school, and I started programming computers when I was 16, but life seemed most important. Hence I studied biochemistry in university but moved into molecular biology with programming to assist the data analysis. My track record in successfully predicting new biology through computing led to a pharmaceutical company recruiting me to do bioinformatics for them. However, not content with studying genes and proteins, I pushed for bioinformatics to move up into metabolism, anatomy, and physiology. That’s when I discovered systems biology. My international reputation lies at this interface and includes discoveries in microbial physiology, botany, agriculture, animal biology, and antenatal diseases.
This book turns on its head what I was taught about what controls metabolite flow through a pathway. It covers highly remarkable discoveries concerning which steps control changes in metabolite levels: those at the end rather than the start of pathways. This is amazing because it explains why decades of effort by bioengineers to overproduce particular metabolites was unsuccessful.
In response to a request from such a project, I explained how to block the inhibitory regulation by the early pathway step but added that, according to metabolic control theory, this would leave the end-product levels unchanged. I was correct on both counts! When my group later provided results from using a systems biology approach, they achieved their production target levels.
The Duke's Christmas Redemption
by
Arietta Richmond,
A Duke who has rejected love, a Lady who dreams of a love match, an arranged marriage, a house full of secrets, a most unneighborly neighbor, a plot to destroy reputations, an unexpected love that redeems it all.
Lady Charlotte Wyndham, given in an arranged marriage to a man she…
Mathematics and chemistry were my strongest subjects at school, and I started programming computers when I was 16, but life seemed most important. Hence I studied biochemistry in university but moved into molecular biology with programming to assist the data analysis. My track record in successfully predicting new biology through computing led to a pharmaceutical company recruiting me to do bioinformatics for them. However, not content with studying genes and proteins, I pushed for bioinformatics to move up into metabolism, anatomy, and physiology. That’s when I discovered systems biology. My international reputation lies at this interface and includes discoveries in microbial physiology, botany, agriculture, animal biology, and antenatal diseases.
This is one of my most valued reference books, and I have referred to it many times.
With some explanatory text, it consists of a set of maps of biochemical pathways, differentiating between organism kingdoms, and includes how specific metabolites regulate the activity of particular enzymes. The pathways are very easy to find and easy to interpret. In contrast, the online equivalents can be difficult to interpret for a variety of reasons.
The book has the added advantage that it does not need a power supply or an internet connection and can be used in a far wider range of temperatures than computer hardware.
The pathways and networks underlying biological function
Now in its second edition, Biochemical Pathways continues to garner praise from students, instructors, and researchers for its clear, full-color illustrations of the pathways and networks that determine biological function.
Biochemical Pathways examines the biochemistry of bacteria, plants, and animals. It offers a quick overview of the metabolic sequences in biochemical pathways, the chemistry and enzymology of conversions, the regulation of turnover, the expression of genes, the immunological interactions, and the metabolic background of health disorders. A standard set of conventions is used in all illustrations, enabling readers to easily gather information and…
Mathematics and chemistry were my strongest subjects at school, and I started programming computers when I was 16, but life seemed most important. Hence I studied biochemistry in university but moved into molecular biology with programming to assist the data analysis. My track record in successfully predicting new biology through computing led to a pharmaceutical company recruiting me to do bioinformatics for them. However, not content with studying genes and proteins, I pushed for bioinformatics to move up into metabolism, anatomy, and physiology. That’s when I discovered systems biology. My international reputation lies at this interface and includes discoveries in microbial physiology, botany, agriculture, animal biology, and antenatal diseases.
This book has been a companion for almost three decades.
Any bona fide bioinformatician will write some program scripts if only to reformat data in new and useful ways. Perl is not the most efficient or widespread scripting language, but it has the advantage of being highly flexible. It offers many ways to write a program to carry out a given task, so even computationally naive programmers can generate effective code.
Even though I am no longer actively developing software, I still have occasions when it is quicker to script something in Perl than do battle with larger apps.
When it comes to learning Perl, programmers consider this book to be the undisputed bible. You not only learn every nuance of this language, you also get a unique perspective on the evolution of Perl and its future direction. The 4th edition has been thoroughly updated for version 5.14, with details on regular expressions, support for UNICODE, threads, and many other features. Many Perl books explain typeglobs, pseudohashes, and closures, but only this one shows the motivations behind these features and why they work the way they do. It's exactly what you'd expect from its prominent authors: Larry Wall is…
In my series on Ways of the World, my aim is to let the founder of each way tell us of their way in their words: the destination that they suggest we all seek; the directions that they offer to help us to reach the destination, and the strategies that they offer to help us to successfully follow their directions. I find it marvelous that we can listen to people, such as Epictetus, who lived thousands of years ago; people whose words can help us to improve our ways. You would be right if you have guessed that the books I recommend are primary sources.
Meditations is a collection of personal writings by Marcus Aurelius, a Stoic philosopher and Roman Emperor (at the other extreme, Epictetus was born a slave). The original title is unknown, and over the years many titles have be used, such as ‘The Book of Marcus’ and ‘Things to one’s self’. I suggest that the latter title, more accurately reflect its contents.
A timely book for today's world, Marcus Aurelius's Meditations explores how to endure hardship, how to cope with change and how to find something positive out of adversity.
Part of the Macmillan Collector's Library; a series of stunning, clothbound, pocket-sized classics with gold foiled edges and ribbon markers. These beautiful books make perfect gifts or a treat for any book lover. This edition is translated by A. S. L. Farquharson and features an introduction by John Sellars.
The Meditations are a set of personal reflections by Marcus Aurelius. He writes about the vicissitudes of his own life and explores how…
This book follows the journey of a writer in search of wisdom as he narrates encounters with 12 distinguished American men over 80, including Paul Volcker, the former head of the Federal Reserve, and Denton Cooley, the world’s most famous heart surgeon.
In these and other intimate conversations, the book…
As a psychologist with environmental interests people often ask me about hope. It goes something like this: “Climate change is pushing us toward disaster! What is your source of hope?” I finally figured out that I only have one source of hope. It is that we, as people, are able to work together just well enough to keep it all afloat. There’s a lot involved in working together – learning to listen with compassion, run good meetings, empower everyone to give of their best, and rebuild trust when it starts to break down. I’ve been researching these topics in community settings for the past 15 years.
After the first edition of Psychology for a Better World was published, I was on the search for a symbol or metaphor to capture the drive of so many people to contribute to the common good. It needed to be something that worked in secular settings and would resonate with the big social movements for the environment, justice, and wellbeing. I heard Carse speak about the infinite game on a podcast and immediately bought his book.
The notion is simple – in life, there are at least two kinds of games: finite games in which the object is to win, and the infinite game in which the object is to keep the game in play. That is it, I thought, life is about keeping the game in play. You don’t have to believe anything, but if you want, you can join the infinite game. Carse describes how these games play…
"There are at least two kinds of games," states James P. Carse as he begins this extraordinary book. "One could be called finite; the other infinite. A finite game is played for the purpose of winning, an infinite game for the purpose of continuing the play."
Finite games are the familiar contests of everyday life; they are played in order to be won, which is when they end. But infinite games are more mysterious. Their object is not winning, but ensuring the continuation of play. The rules may change, the boundaries may change, even the participants may change-as long as…
