Tag Archives: optimism

Afternoon Tee 5: Live Your Life, Love Your Life T-shirts

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Now at my Zazzle shop in Afternoon Tee: “Live Your Life, Love Your Life” tees.

Happiness is a mental state of well-being characterized by positive emotions ranging from contentment to intense joy. A variety of biological, psychological, religious, and philosophical approaches have striven to define happiness and identify its sources.

Various research groups, including Positive psychology, endeavor to apply the scientific method to answer questions about what “happiness” is, and how we might attain it.

Philosophers and religious thinkers often define happiness in terms of living a good life, or flourishing, rather than simply as an emotion. Happiness in this older sense was used to translate the Greek Eudaimonia, and is still used in virtue ethics.

Happiness economics suggests that measures of public happiness should be used to supplement more traditional economic measures when evaluating the success of public policy.

There are various factors that have been correlated with happiness, but no validated method has been found to improve happiness in a meaningful way for most people.

Psychologist Martin Seligman provides the acronym PERMA to summarize Positive Psychology’s correlational findings: humans seem happiest when they have

1. Pleasure (tasty foods, warm baths, etc.),
2. Engagement (or flow, the absorption of an enjoyed yet challenging activity),
3. Relationships (social ties have turned out to be extremely reliable indicator of happiness),
4. Meaning (a perceived quest or belonging to something bigger), and
5. Accomplishments (ving realized tangible goals).

(Visit Wikipedia for the complete original article on Happiness.)

Afternoon Tee 2: Happy Bee Tee

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Now at my Zazzle shop in Afternoon Tee:

“Physicists once said bees couldn’t fly… but no one told the bees so they flew anyway.”

a new fully customizable tee in 50 styles and colors to fit infants to 3X.

A bumble bee (also written as bumblebee) is any member of the bee genus Bombus, in the family Apidae. There are over 250 known species, existing primarily in the Northern Hemisphere although they are common in New Zealand and in the Australian state of Tasmania.

Bumble bees are social insects that are characterised by black and yellow body hairs, often in bands. However, some species have orange or red on their bodies, or may be entirely black. Another obvious (but not unique) characteristic is the soft nature of the hair (long, branched setae), called pile, that covers their entire body, making them appear and feel fuzzy. They are best distinguished from similarly large, fuzzy bees by the form of the female hind leg, which is modified to form a corbicula: a shiny concave surface that is bare, but surrounded by a fringe of hairs used to transport pollen (in similar bees, the hind leg is completely hairy, and pollen grains are wedged into the hairs for transport).

Like their relatives the honey bees, bumble bees feed on nectar and gather pollen to feed their young.

According to 20th century folklore, the laws of aerodynamics prove that the bumble bee should be incapable of flight, as it does not have the capacity (in terms of wing size or beats per second) to achieve flight with the degree of wing loading necessary. The origin of this claim has been difficult to pin down with any certainty. John McMasters recounted an anecdote about an unnamed Swiss aerodynamicist at a dinner party who performed some rough calculations and concluded, presumably in jest, that according to the equations, bumble bees cannot fly. In later years McMasters has backed away from this origin, suggesting that there could be multiple sources, and that the earliest he has found was a reference in the 1934 French book Le vol des insectes; they had applied the equations of air resistance to insects and found that their flight was impossible, but that “One shouldn’t be surprised that the results of the calculations don’t square with reality”.

Some credit physicist Ludwig Prandtl (1875–1953) of the University of Göttingen in Germany with popularizing the idea. Others say it was Swiss gas dynamicist Jacob Ackeret (1898–1981) who did the calculations.

In 1934, French entomologist Antoine Magnan included the following passage in the introduction to his book Le Vol des Insectes:

Tout d’abord poussé par ce qui se fait en aviation, j’ai appliqué aux insectes les lois de la résistance de l’air, et je suis arrivé avec M. Sainte-Laguë à cette conclusion que leur vol est impossible.

This translates to:

First prompted by what is done in aviation, I applied the laws of air resistance to insects, and I arrived, with Mr. Sainte-Laguë, at this conclusion that their flight is impossible.

Magnan refers to his assistant André Sainte-Laguë, a mathematician.

The calculations that purported to show that bumble bees cannot fly are based upon a simplified linear treatment of oscillating aerofoils. The method assumes small amplitude oscillations without flow separation. This ignores the effect of dynamic stall, an airflow separation inducing a large vortex above the wing, which briefly produces several times the lift of the aerofoil in regular flight. More sophisticated aerodynamic analysis shows that the bumblebee can fly because its wings encounter dynamic stall in every oscillation cycle.

Additionally, John Maynard Smith, a noted biologist with a strong background in aeronautics, has pointed out that bumble bees would not be expected to sustain flight, as they would need to generate too much power given their tiny wing area. However, in aerodynamics experiments with other insects he found that viscosity at the scale of small insects meant that even their small wings can move a very large volume of air relative to the size, and this reduces the power required to sustain flight by an order of magnitude.

Another description of a bee’s wing function is that the wings work similarly to helicopter blades, “reverse-pitch semirotary helicopter blades”.

Bees beat their wings approximately 200 times a second. Their thorax muscles do not expand and contract on each nerve firing but rather vibrate like a plucked rubber band.

(Visit Wikipedia for the complete original article on Bumble Bee.)


Click here for more customizable tees.

Morning Coffee 1: Happy Bee Mug

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Now at my Zazzle shop in Morning Coffee: “Physicists once said bees couldn’t fly… but no one told the bees so they flew anyway.” a new fully customizable mug in 34 styles and colors, including traditional, frosted and travel.

A bumble bee (also written as bumblebee) is any member of the bee genus Bombus, in the family Apidae. There are over 250 known species, existing primarily in the Northern Hemisphere although they are common in New Zealand and in the Australian state of Tasmania.

Bumble bees are social insects that are characterised by black and yellow body hairs, often in bands. However, some species have orange or red on their bodies, or may be entirely black. Another obvious (but not unique) characteristic is the soft nature of the hair (long, branched setae), called pile, that covers their entire body, making them appear and feel fuzzy. They are best distinguished from similarly large, fuzzy bees by the form of the female hind leg, which is modified to form a corbicula: a shiny concave surface that is bare, but surrounded by a fringe of hairs used to transport pollen (in similar bees, the hind leg is completely hairy, and pollen grains are wedged into the hairs for transport).

Like their relatives the honey bees, bumble bees feed on nectar and gather pollen to feed their young.

According to 20th century folklore, the laws of aerodynamics prove that the bumble bee should be incapable of flight, as it does not have the capacity (in terms of wing size or beats per second) to achieve flight with the degree of wing loading necessary. The origin of this claim has been difficult to pin down with any certainty. John McMasters recounted an anecdote about an unnamed Swiss aerodynamicist at a dinner party who performed some rough calculations and concluded, presumably in jest, that according to the equations, bumble bees cannot fly. In later years McMasters has backed away from this origin, suggesting that there could be multiple sources, and that the earliest he has found was a reference in the 1934 French book Le vol des insectes; they had applied the equations of air resistance to insects and found that their flight was impossible, but that “One shouldn’t be surprised that the results of the calculations don’t square with reality”.

Some credit physicist Ludwig Prandtl (1875–1953) of the University of Göttingen in Germany with popularizing the idea. Others say it was Swiss gas dynamicist Jacob Ackeret (1898–1981) who did the calculations.

In 1934, French entomologist Antoine Magnan included the following passage in the introduction to his book Le Vol des Insectes:

Tout d’abord poussé par ce qui se fait en aviation, j’ai appliqué aux insectes les lois de la résistance de l’air, et je suis arrivé avec M. Sainte-Laguë à cette conclusion que leur vol est impossible.

This translates to:

First prompted by what is done in aviation, I applied the laws of air resistance to insects, and I arrived, with Mr. Sainte-Laguë, at this conclusion that their flight is impossible.

Magnan refers to his assistant André Sainte-Laguë, a mathematician.

The calculations that purported to show that bumble bees cannot fly are based upon a simplified linear treatment of oscillating aerofoils. The method assumes small amplitude oscillations without flow separation. This ignores the effect of dynamic stall, an airflow separation inducing a large vortex above the wing, which briefly produces several times the lift of the aerofoil in regular flight. More sophisticated aerodynamic analysis shows that the bumblebee can fly because its wings encounter dynamic stall in every oscillation cycle.

Additionally, John Maynard Smith, a noted biologist with a strong background in aeronautics, has pointed out that bumble bees would not be expected to sustain flight, as they would need to generate too much power given their tiny wing area. However, in aerodynamics experiments with other insects he found that viscosity at the scale of small insects meant that even their small wings can move a very large volume of air relative to the size, and this reduces the power required to sustain flight by an order of magnitude.

Another description of a bee’s wing function is that the wings work similarly to helicopter blades, “reverse-pitch semirotary helicopter blades”.

Bees beat their wings approximately 200 times a second. Their thorax muscles do not expand and contract on each nerve firing but rather vibrate like a plucked rubber band.

(Visit Wikipedia for the complete original article on Bumble bee.)


Click here for more customizable mugs.