Wonderland
Wonderland

fuckyeahtattoos:

-Ta2man08

Eazy Street Tattoos

Miami,FL

Permalink (874 notes)Via: fuckyeahtattoos
fuckyeahtattoos: -Ta2man08 Eazy Street Tattoos Miami,FL
ZoomInfo

1ucasvb:

Different modes of oscillation for a pendulum

The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions.

Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system.

As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser.

The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity.

Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.

Permalink (23,648 notes) Via: 1ucasvb
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
1ucasvb: Different modes of oscillation for a pendulum The period of a simple pendulum is not a trivial thing, and it depends on the initial conditions. Shown here are ten different modes of oscillation for the same pendulum. The only difference is the total amount of mechanical energy in the system. As a result, each one has a completely different period of oscillation, unlike what the small-angle approximation (as taught in high-school) would suggest. They can’t be in sync. You may see some really interesting patterns based on the delay between them in your browser. The red graph above each pendulum represents the phase portrait for the respective mode of oscillation, with the current state marked as a blue dot. The horizontal axis represents angle (hence why it wraps around the sides) while the vertical axis represents angular velocity. Pendulums are very interesting dynamical systems, as they are relatively simple to understand but can produce surprisingly complex results in certain cases, such as the chaotic behavior of double pendulums and the odd behavior displayed by coupled pendulums.
Permalink (15 notes)Via: scottcampbelltattoo

thestarlighthotel:

Butterfly piece | Alexandr Pashkov

Permalink (4,351 notes)Source: facebook.comVia: fuckyeahtattoos
thestarlighthotel: Butterfly piece | Alexandr Pashkov

thestarlighthotel:

Fleur de lis watercolor tattoo | Koray Karagozler

Permalink (3,011 notes)Source: facebook.comVia: fuckyeahtattoos
thestarlighthotel: Fleur de lis watercolor tattoo | Koray Karagozler

tattr:

JULIAN OH

Malaysia // Traveling: AustriaAustralia,The PhilippinesThe Netherlands

julianoh.tumblr.com

Julian Oh Facebook

Email: zero.julian@gmail.com

Permalink (2,651 notes)Source: tattrVia: fuckyeahtattoos
tattr: JULIAN OH Malaysia // Traveling: Austria, Australia,The Philippines, The Netherlands julianoh.tumblr.com Julian Oh Facebook Email: zero.julian@gmail.com

fuckyeahtattoos:

Disciple Tattoo (Arizona) Done by. Rod Whitesinger

Im still in progress with this one but this is it so far! I plan on getting a graveyard scene on my other shoulder, plus a scary tree and a quote ”i have loved the stars too fondly to be fearful of the night” super excited! Getting this done because of my love for the night. I never really been a morning person, life begins at night! Bats are also my favorite animal! Go figure. I have loved everything horror and Halloween related my whole life so this is dedicated to the night. 

Permalink (1,040 notes)Via: fuckyeahtattoos
fuckyeahtattoos: Disciple Tattoo (Arizona) Done by. Rod Whitesinger Im still in progress with this one but this is it so far! I plan on getting a graveyard scene on my other shoulder, plus a scary tree and a quote ”i have loved the stars too fondly to be fearful of the night” super excited! Getting this done because of my love for the night. I never really been a morning person, life begins at night! Bats are also my favorite animal! Go figure. I have loved everything horror and Halloween related my whole life so this is dedicated to the night. 
ZoomInfo

natocartul:

Supermassive Black Hole by ELIA FERNANDEZ

Permalink (95,441 notes) Via: natocartul
natocartul: Supermassive Black Hole by ELIA FERNANDEZ
natocartul: Supermassive Black Hole by ELIA FERNANDEZ
natocartul: Supermassive Black Hole by ELIA FERNANDEZ
Permalink

thewallgroup:

Photographed by Enrique Badulescu for Metal Magazine October 2012. Makeup by Maki H.

Permalink (18,201 notes)Via: thewallgroup
thewallgroup: Photographed by Enrique Badulescu for Metal Magazine October 2012. Makeup by Maki H.