Ask me any question you like and I will answer. - GoFuckYourself.com

Paul Markham · 10-14-2012, 01:21 AM

Let it all begin.

Paul Markham · 10-14-2012, 03:15 AM

I will ask myself a question then.

What does Damian do for a living?

He sends emails.

johnnyloadproductions · 10-15-2012, 04:55 PM

Quote:

Originally Posted by Paul Markham

I will ask myself a question then.

What does Damian do for a living?

He sends emails.

What a great thing to have your kids say when other kids ask "what does your dad do?" Sends emails.

Paul Markham · 10-15-2012, 11:24 PM

Quote:

Originally Posted by johnnyloadproductions

What a great thing to have your kids say when other kids ask "what does your dad do?" Sends emails.

She tells them, he watches the TV a lot.

epitome · 10-18-2012, 04:44 PM

How much did you pay for your wife?

k0nr4d · 10-19-2012, 03:06 AM

what's the airspeed velocity of an unladen dildo?

Paul Markham · 10-19-2012, 04:28 AM

Quote:

Originally Posted by k0nr4d

what's the airspeed velocity of an unladen dildo?

With batteries or without?

k0nr4d · 10-19-2012, 04:45 AM

Quote:

Originally Posted by Paul Markham

With batteries or without?

i *JUST* said unladen man - eyes on the ball!

Paul Markham · 10-19-2012, 07:08 AM

Quote:

Originally Posted by k0nr4d

i *JUST* said unladen man - eyes on the ball!

I thought that meant with a woman attached.

So lubed or not, hard plastic or soft?

Paul Markham · 10-19-2012, 07:37 AM

So to be more precise, this is the

In Newtonian mechanics, an equation of motion M takes the general form of a 2nd order ordinary differential equation (ODE) in the position r (see below for details) of the object:

where t is time, and each overdot denotes a time derivative.
The initial conditions are given by the constant values at t = 0:

An alternative dynamical variable to r is the momentum p of the object (though less commonly used), i.e. a 2nd order ODE in p: with initial conditions (again constant values)

The solution r (or p) to the equation of motion, combined with the initial values, describes of the system for all times after t = 0. For more than one particle, there are separate equations for each (this is contrary to a statistical ensemble of many particles in statistical mechanics, and a many-particle system in quantum mechanics - where all particles are described by a single probability distribution). Sometimes, the equation will be linear and can be solved exactly. However in general, the equation is non-linear, and may lead to chaotic behaviour depending on how sensitive the system is to the initial conditions.

In the generalized Lagrangian mechanics, the generalized coordinates q (or generalized momenta p) replace the ordinary position (or momentum). Hamiltonian mechanics is slightly different, there are two 1st order equations in the generalized coordinates and momenta:

where q is a tuple of generalized coordinates and similarly p is the tuple of generalized momenta. The initial conditions are similarly defined.

Kinematic quantities of a classical particle: mass m, position r, velocity v, acceleration a.
From the instantaneous position r = r (t) (instantaneous meaning at an instant value of time t), the instantaneous velocity v = v (t) and acceleration a = a (t) have the general, coordinate-independent definitions;[5]

z The rotational analogues are the angular position (angle the particle rotates about some axis) θ = θ(t), angular velocity ω = ω(t), and angular acceleration a = a(t):

where

is a unit axial vector, pointing parallel to the axis of rotation, = unit vector in direction of r, = unit vector tangential to the angle.
NB: In these rotational definitions, the angle can be any angle about the specified axis of rotation. It is customary to use θ, but this does not have to be the polar angle used in polar coordinate systems.
For a rotating rigid body, the following relations useful for describing the motion hold:

These equations apply to a particle moving linearly, in three dimensions in a straight line, with constant acceleration.[6] Since the vectors are collinear (parallel, and lie on the same line) - only the magnitudes of the vectors are necessary, hence non-bold letters are used for magnitudes, and because the motion is along a straight line, the problem effectively reduces from three dimensions to one.

where r0 and v0 are the particle's initial position and velocity, r, v, a are the final position (displacement), velocity and acceleration of the particle after the time interval.

Here a is constant acceleration, or in the case of bodies moving under the influence of gravity, the standard gravity g is used. Note that each of the equations contains four of the five variables, so in this situation it is sufficient to know three out of the five variables to calculate the remaining two.
SUVAT equations

In elementary physics the above formulae are frequently written:

where u has replaced v0, s replaces r, and s0 = 0. They are often referred to as the "SUVAT" equations, eponymous from to the variables: s = displacement (s0 = initial displacement), u = initial velocity, v = final velocity, a = acceleration, t = time.

Elementary and frequent examples in kinematics involve projectiles, for example a ball thrown upwards into the air. Given initial speed u, one can calculate how high the ball will travel before it begins to fall. The acceleration is local acceleration of gravity g. At this point one must remember that while these quantities appear to be scalars, the direction of displacement, speed and acceleration is important. They could in fact be considered as uni-directional vectors. Choosing s to measure up from the ground, the acceleration a must be in fact −g, since the force of gravity acts downwards and therefore also the acceleration on the ball due to it.

At the highest point, the ball will be at rest: therefore v = 0. Using equation [4] in the set above, we have:

Substituting and cancelling minus signs gives:

Constant circular acceleration
The analogues of the above equations can be written for rotation. Again these axial vectors must all be parallel (to the axis of rotation), so only the magnitudes of the vectors are necessary:

where α is the constant angular acceleration, ω is the angular velocity, ω0 is the initial angular velocity, θ is the angle turned through (angular displacement), θ0 is the initial angle, and t is the time taken to rotate from the initial state to the final state.

General planar motion

These are the kinematic equations for a particle traversing a path in a plane, described by position r = r(t).[9] They are actually no more than the time derivatives of the position vector in plane polar coordinates in the context of physical quantities (like angular velocity ω).

The position, velocity and acceleration of the particle are respectively: where are the polar unit vectors. Notice for a the components (?rω2) and 2ωdr/dt are the centripetal and Coriolis accelerations respectively.

Special cases of motion described be these equations are summarized qualitatively in the table below. Two have already been discussed above, in the cases that either the radial components or the angular components are zero, and the non-zero component of motion describes uniform acceleration.

Are you with me so far?

gimme-website · 10-19-2012, 08:03 AM

Marmite. Love it or hate it?

Paul Markham · 10-19-2012, 08:12 AM

Quote:

Originally Posted by gimme-website

Marmite. Love it or hate it?

Hate it.

ottopottomouse · 10-19-2012, 08:14 AM

Am I on your imaginary ignore list today?

gimme-website · 10-19-2012, 09:08 AM

WHat was the coolest thing in the world when you were 14?
What was the coolest thing you could get for xmas as a 14 year old boy?

The defualt answer of 'girls' is null and void...

Paul Markham · 10-19-2012, 09:43 AM

What was the coolest thing in the world when you were 14? A blow job from a female.

What was the coolest thing you could get for Xmas as a 14 year old boy? Full sex with a female.

Other than those a Rolling Stones LP was high on the list.

epitome · 10-19-2012, 11:45 AM

Why are you talking about children and sex?

papill0n · 10-19-2012, 01:08 PM

Quote:

Originally Posted by Paul Markham

What was the coolest thing in the world when you were 14? A blow job from a female.

What was the coolest thing you could get for Xmas as a 14 year old boy? Full sex with a female.

Other than those a Rolling Stones LP was high on the list.

wow this has gone too far you senile fucking loser

pornmasta · 10-19-2012, 01:11 PM

the model with the pussy that stinks the most and the one that smells the best. (wife not allowed)

gimme-website · 10-20-2012, 12:28 AM

Ya could have said "a penny farthing"... That was the direction I was heading with my question.

DamianJ · 10-24-2012, 06:24 AM

Quote:

Originally Posted by Paul Markham

What was the coolest thing in the world when you were 14? A blow job from a female.

What was the coolest thing you could get for Xmas as a 14 year old boy? Full sex with a female.

You can't help yourself posting about kids and sex can you?

10-14-2012, 01:21 AM	#1
Paul Markham Too old to care Industry Role: Join Date: Jun 2001 Location: On the sofa, watching TV or doing my jigsaws. Posts: 52,943	Ask me any question you like and I will answer. Let it all begin. __________________ Blowout deal. 880 videos, 2,400 image sets, plus many RAW videos. $500. PM me for a deal. Skype Paulmarkham70

10-14-2012, 03:15 AM	#2
Paul Markham Too old to care Industry Role: Join Date: Jun 2001 Location: On the sofa, watching TV or doing my jigsaws. Posts: 52,943	I will ask myself a question then. What does Damian do for a living? He sends emails. __________________ Blowout deal. 880 videos, 2,400 image sets, plus many RAW videos. $500. PM me for a deal. Skype Paulmarkham70

10-19-2012, 03:06 AM	#6
k0nr4d Confirmed User Industry Role: Join Date: Aug 2006 Location: Poland Posts: 9,228	what's the airspeed velocity of an unladen dildo? __________________ Mechanical Bunny Media Mechbunny Tube Script \| Mechbunny Webcam Aggregator Script \| Custom Web Development

10-19-2012, 07:37 AM	#10
Paul Markham Too old to care Industry Role: Join Date: Jun 2001 Location: On the sofa, watching TV or doing my jigsaws. Posts: 52,943	So to be more precise, this is the In Newtonian mechanics, an equation of motion M takes the general form of a 2nd order ordinary differential equation (ODE) in the position r (see below for details) of the object: where t is time, and each overdot denotes a time derivative. The initial conditions are given by the constant values at t = 0: An alternative dynamical variable to r is the momentum p of the object (though less commonly used), i.e. a 2nd order ODE in p: with initial conditions (again constant values) The solution r (or p) to the equation of motion, combined with the initial values, describes of the system for all times after t = 0. For more than one particle, there are separate equations for each (this is contrary to a statistical ensemble of many particles in statistical mechanics, and a many-particle system in quantum mechanics - where all particles are described by a single probability distribution). Sometimes, the equation will be linear and can be solved exactly. However in general, the equation is non-linear, and may lead to chaotic behaviour depending on how sensitive the system is to the initial conditions. In the generalized Lagrangian mechanics, the generalized coordinates q (or generalized momenta p) replace the ordinary position (or momentum). Hamiltonian mechanics is slightly different, there are two 1st order equations in the generalized coordinates and momenta: where q is a tuple of generalized coordinates and similarly p is the tuple of generalized momenta. The initial conditions are similarly defined. Kinematic quantities of a classical particle: mass m, position r, velocity v, acceleration a. From the instantaneous position r = r (t) (instantaneous meaning at an instant value of time t), the instantaneous velocity v = v (t) and acceleration a = a (t) have the general, coordinate-independent definitions;[5] z The rotational analogues are the angular position (angle the particle rotates about some axis) θ = θ(t), angular velocity ω = ω(t), and angular acceleration a = a(t): where is a unit axial vector, pointing parallel to the axis of rotation, = unit vector in direction of r, = unit vector tangential to the angle. NB: In these rotational definitions, the angle can be any angle about the specified axis of rotation. It is customary to use θ, but this does not have to be the polar angle used in polar coordinate systems. For a rotating rigid body, the following relations useful for describing the motion hold: These equations apply to a particle moving linearly, in three dimensions in a straight line, with constant acceleration.[6] Since the vectors are collinear (parallel, and lie on the same line) - only the magnitudes of the vectors are necessary, hence non-bold letters are used for magnitudes, and because the motion is along a straight line, the problem effectively reduces from three dimensions to one. where r0 and v0 are the particle's initial position and velocity, r, v, a are the final position (displacement), velocity and acceleration of the particle after the time interval. Here a is constant acceleration, or in the case of bodies moving under the influence of gravity, the standard gravity g is used. Note that each of the equations contains four of the five variables, so in this situation it is sufficient to know three out of the five variables to calculate the remaining two. SUVAT equations In elementary physics the above formulae are frequently written: where u has replaced v0, s replaces r, and s0 = 0. They are often referred to as the "SUVAT" equations, eponymous from to the variables: s = displacement (s0 = initial displacement), u = initial velocity, v = final velocity, a = acceleration, t = time. Elementary and frequent examples in kinematics involve projectiles, for example a ball thrown upwards into the air. Given initial speed u, one can calculate how high the ball will travel before it begins to fall. The acceleration is local acceleration of gravity g. At this point one must remember that while these quantities appear to be scalars, the direction of displacement, speed and acceleration is important. They could in fact be considered as uni-directional vectors. Choosing s to measure up from the ground, the acceleration a must be in fact −g, since the force of gravity acts downwards and therefore also the acceleration on the ball due to it. At the highest point, the ball will be at rest: therefore v = 0. Using equation [4] in the set above, we have: Substituting and cancelling minus signs gives: Constant circular acceleration The analogues of the above equations can be written for rotation. Again these axial vectors must all be parallel (to the axis of rotation), so only the magnitudes of the vectors are necessary: where α is the constant angular acceleration, ω is the angular velocity, ω0 is the initial angular velocity, θ is the angle turned through (angular displacement), θ0 is the initial angle, and t is the time taken to rotate from the initial state to the final state. General planar motion These are the kinematic equations for a particle traversing a path in a plane, described by position r = r(t).[9] They are actually no more than the time derivatives of the position vector in plane polar coordinates in the context of physical quantities (like angular velocity ω). The position, velocity and acceleration of the particle are respectively: where are the polar unit vectors. Notice for a the components (?rω2) and 2ωdr/dt are the centripetal and Coriolis accelerations respectively. Special cases of motion described be these equations are summarized qualitatively in the table below. Two have already been discussed above, in the cases that either the radial components or the angular components are zero, and the non-zero component of motion describes uniform acceleration. Are you with me so far? __________________ Blowout deal. 880 videos, 2,400 image sets, plus many RAW videos. $500. PM me for a deal. Skype Paulmarkham70

10-19-2012, 08:03 AM	#11
gimme-website Confirmed User Industry Role: Join Date: Jun 2008 Location: Finland Posts: 1,588	Marmite. Love it or hate it? __________________ www.gimme-website.com

10-18-2012, 04:44 PM	#5
epitome So Fucking Lame Industry Role: Join Date: Jun 2009 Location: St. Petersburg, FL Posts: 12,158	How much did you pay for your wife?

10-19-2012, 08:14 AM	#13
ottopottomouse She is ugly, bad luck. Industry Role: Join Date: Jan 2010 Posts: 13,177	Am I on your imaginary ignore list today? __________________ ↑ see post ↑ 13101

10-19-2012, 09:08 AM	#14
gimme-website Confirmed User Industry Role: Join Date: Jun 2008 Location: Finland Posts: 1,588	WHat was the coolest thing in the world when you were 14? What was the coolest thing you could get for xmas as a 14 year old boy? The defualt answer of 'girls' is null and void... __________________ www.gimme-website.com

10-19-2012, 09:43 AM	#15
Paul Markham Too old to care Industry Role: Join Date: Jun 2001 Location: On the sofa, watching TV or doing my jigsaws. Posts: 52,943	What was the coolest thing in the world when you were 14? A blow job from a female. What was the coolest thing you could get for Xmas as a 14 year old boy? Full sex with a female. Other than those a Rolling Stones LP was high on the list. __________________ Blowout deal. 880 videos, 2,400 image sets, plus many RAW videos. $500. PM me for a deal. Skype Paulmarkham70

10-19-2012, 11:45 AM	#16
epitome So Fucking Lame Industry Role: Join Date: Jun 2009 Location: St. Petersburg, FL Posts: 12,158	Why are you talking about children and sex?

10-19-2012, 01:11 PM	#18
pornmasta Too lazy to set a custom title Join Date: Jun 2006 Posts: 18,949	the model with the pussy that stinks the most and the one that smells the best. (wife not allowed)

10-20-2012, 12:28 AM	#19
gimme-website Confirmed User Industry Role: Join Date: Jun 2008 Location: Finland Posts: 1,588	Ya could have said "a penny farthing"... That was the direction I was heading with my question. __________________ www.gimme-website.com