Hello community, here is the log from the commit of package step for openSUSE:Factory checked in at 2012-02-01 10:00:39 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Comparing /work/SRC/openSUSE:Factory/step (Old) and /work/SRC/openSUSE:Factory/.step.new (New) ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
Package is "step", Maintainer is "step" Changes: -------- --- /work/SRC/openSUSE:Factory/step/step.changes 2011-12-08 11:31:40.000000000 +0100 +++ /work/SRC/openSUSE:Factory/.step.new/step.changes 2012-02-01 10:00:41.000000000 +0100 @@ -1,0 +2,16 @@ +Wed Jan 18 21:01:25 CET 2012 - [email protected] + +- update to 4.8.0 + * first stable release of KDE 4.8 (only critical fixes over 4.7.98) + * see http://kde.org/announcements/4.8/ for details + + +------------------------------------------------------------------- +Tue Jan 10 18:48:28 CET 2012 - [email protected] + +- update to 4.7.98 + * RC2+ milestone release of KDE 4.8 + * see http://kde.org/announcements/4.8/ for details + + +------------------------------------------------------------------- Old: ---- step-4.7.4.tar.bz2 New: ---- step-4.8.0.tar.bz2 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Other differences: ------------------ ++++++ step.spec ++++++ --- /var/tmp/diff_new_pack.z2DP0W/_old 2012-02-01 10:00:42.000000000 +0100 +++ /var/tmp/diff_new_pack.z2DP0W/_new 2012-02-01 10:00:42.000000000 +0100 @@ -1,7 +1,7 @@ # # spec file for package step # -# Copyright (c) 2011 SUSE LINUX Products GmbH, Nuernberg, Germany. +# Copyright (c) 2012 SUSE LINUX Products GmbH, Nuernberg, Germany. # # All modifications and additions to the file contributed by third parties # remain the property of their copyright owners, unless otherwise agreed @@ -37,7 +37,7 @@ BuildRequires: ocaml BuildRequires: ocaml-facile %endif -Version: 4.7.4 +Version: 4.8.0 Release: 0 Summary: An interactive physics simulator License: GPL-2.0+ ++++++ step-4.7.4.tar.bz2 -> step-4.8.0.tar.bz2 ++++++ diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/cmake/modules/FindGSL.cmake new/step-4.8.0/cmake/modules/FindGSL.cmake --- old/step-4.7.4/cmake/modules/FindGSL.cmake 2011-10-02 15:25:56.000000000 +0200 +++ new/step-4.8.0/cmake/modules/FindGSL.cmake 2012-01-02 20:52:42.000000000 +0100 @@ -23,8 +23,7 @@ ENDIF(NOT WIN32) find_path(GSL_INCLUDE_DIR - NAMES gsl_cdf.h gsl_randist.h - PATH_SUFFIXES gsl + NAMES gsl/gsl_cdf.h gsl/gsl_randist.h PATHS ${_GSLIncDir}) set(GSL_LIBRARIES ${_GSLLinkFlags}) diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/doc/examples.docbook new/step-4.8.0/doc/examples.docbook --- old/step-4.7.4/doc/examples.docbook 2011-10-02 15:25:56.000000000 +0200 +++ new/step-4.8.0/doc/examples.docbook 2011-12-20 20:13:26.000000000 +0100 @@ -1,24 +1,145 @@ <chapter id="examples"> <title>&step; examples</title> -<para> - </para> +<para> + &step; package contains several instructive examples to help you understand the principles of the application work. To open an example from the default set choose <menuchoice><guimenu>File</guimenu> <guisubmenu>Examples</guisubmenu> <guimenuitem>Open Example...</guimenuitem></menuchoice> from the main window menu. +</para> + +<para> + You can share your own examples with <menuchoice><guimenu>File</guimenu> <guisubmenu>Examples</guisubmenu> <guimenuitem>Share Current Experiment...</guimenuitem></menuchoice> or download examples shared by other users with <menuchoice><guimenu>File</guimenu> <guisubmenu>Examples</guisubmenu> <guimenuitem>Download New Experiments...</guimenuitem></menuchoice>. Downloaded examples can be opened using <menuchoice><guimenu>File</guimenu> <guisubmenu>Examples</guisubmenu> <guimenuitem>Open Downloaded Example...</guimenuitem></menuchoice> menu item. +</para> + +<para> + You can find the descriptions of the default example files below. +</para> + +<variablelist> +<varlistentry id="brownian"> +<term>brownian.step</term> +<listitem><para>Plots trajectory of the rigid disk interacting with 40 particles that randomly drifting in a box. This example simulates <ulink url="http://en.wikipedia.org/wiki/Brownian_motion";>Brownian motion</ulink> of ideal gas particles.</para></listitem> +</varlistentry> + +<varlistentry id="pendulum"> +<term>doublependulum.step</term> +<listitem><para>This example simulates <ulink url="http://en.wikipedia.org/wiki/Double_pendulum";>double pendulum motion</ulink> using 2 massive particles and two sticks.</para></listitem> +</varlistentry> + +<varlistentry id="eightpendulum"> +<term>eightpendulum.step</term> +<listitem><para>This example is a simple demonstration of the famous <ulink url="http://en.wikipedia.org/wiki/Newton%27s_cradle";>Newton's cradle</ulink>. It is done in &step; using sticks, 8 discs and a box. The six balls in the middle are not moving because they just transfer momentum and energy, not a motion.</para></listitem> +</varlistentry> + +<varlistentry id="first"> +<term>first.step: First example</term> +<listitem><para>This example has two parts. The first part contains two particles connected +by a spring and the second part contains two charged particles.</para> + +<variablelist> +<varlistentry id="first-two-particles"> +<term>Two particles connected by a spring</term> +<listitem> + <para> + In this example two particles are added to the scene and spring is connected + between them. The properties of both the particles such as velocity, momentum, + position &etc; has been set in the properties browser. The properties of the + spring such as stiffness, restLength, damping &etc; also has been set in the + properties browser. + </para> + <para> + <emphasis>Explanation of the simulation:</emphasis> + </para> + <para> + This is good example of a simple harmonic motion. Here the acceleration of the + one particle is set in direction of positive x-axis and the acceleration of + the other particle is set along negative x-axis. As a result both the particles + pulls the spring in opposite directions, where as spring tries to bring the + two particles back to their original positions. Thus the system executes + simple harmonic motion. The simulation of the particles and spring under these + conditions can be seen on the scene. + </para> +</listitem> +</varlistentry> + +<varlistentry id="first-two-charged"> +<term>Two charged particles</term> +<listitem> + <para> + Velocity of the each charged particle is set in some direction so, the charged + particles moves in respective direction of their velocity but each particle + has been given a equal and opposite charge so the particles try to attract + each other. As a result the simulation of the charged particles under these + conditions can be seen on the scene. + </para> +</listitem> +</varlistentry> +</variablelist> +</listitem> +</varlistentry> + +<varlistentry id="fourpendula"> +<term>fourpendula.step</term> +<listitem><para>This example is a correct demonstration of the <ulink url="http://en.wikipedia.org/wiki/Newton%27s_cradle";>Newton's cradle</ulink>. As the system is imperfect two disks in the middle get visual movement with time.</para></listitem> +</varlistentry> + +<varlistentry id="gas"> +<term>gas.step</term> +<listitem><para>This example simulates ideal gas pressure caused by <ulink url="http://en.wikipedia.org/wiki/Brownian_motion";>Brownian motion</ulink>.</para></listitem> +</varlistentry> + +<varlistentry id="graph"> +<term>graph.step</term> +<listitem><para>Plots velocity vs. position graph for particle1 in the system of two particles connected with a spring.</para></listitem> +</varlistentry> + +<varlistentry id="liquid"> +<term>liquid.step</term> +<listitem><para>This example simulates monoatomic liquid.</para></listitem> +</varlistentry> + +<varlistentry id="lissajous"> +<term>lissajous.step</term> +<listitem><para>This example simulates <ulink url="http://en.wikipedia.org/wiki/Lissajous_curve";>Lissajous curve</ulink> using two-particle model. The parameters on the model can be changed using the controller at the center of the world.</para></listitem> +</varlistentry> + +<varlistentry id="motor1"> +<term>motor1.step</term> +<listitem><para>Simulates triangular rigid body under the loading of the three linear motors.</para></listitem> +</varlistentry> + +<varlistentry id="motor-example"> +<term>motor.step</term> +<listitem><para>Simulates interaction of the linear motor with a rigid rectangular body on a spring.</para></listitem> +</varlistentry> + +<varlistentry id="note-example"> +<term>note.step</term> +<listitem><para>Example with LaTeX formula (<ulink url="http://en.wikipedia.org/wiki/Divergence_theorem";>divergence theorem</ulink>) and embedded image.</para></listitem> +</varlistentry> + +<varlistentry id="resonance"> +<term>resonance.step</term> +<listitem><para>This example simulates resonance in the system with angular motor.</para></listitem> +</varlistentry> + +<varlistentry id="softbody"> +<term>softbody.step</term> +<listitem><para>This example simulates interaction of two rigid bodies with a soft body between them.</para></listitem> +</varlistentry> + +<varlistentry id="solar"> +<term>solar.step</term> +<listitem><para>This example simulates the motion of Solar system major bodies (Sun and the planets).</para></listitem> +</varlistentry> + +<varlistentry id="springs"> +<term>springs.step</term> +<listitem><para>This example simulates the motion of the planar system of five particles connected with four springs.</para></listitem> +</varlistentry> + +<varlistentry id="wave"> +<term>wave.step</term> +<listitem><para>The graph on the scene shows oscillations of the green particle. When you start simulation the wave starts to travel from the red particle. The blue particle will reflect the wave and it will travel in reverse direction until the red particle reflects in again. After some time the wave will vanish because springs have damping.</para></listitem> +</varlistentry> + +</variablelist> -<sect1 id="first"> -<title>first.step: First example</title> -<para> - </para> -</sect1> - -<sect1 id="brownian"> -<title>brownian.step</title> -<para> - </para> -</sect1> - -<sect1 id="pendulum"> -<title>doublependulum.step</title> -<para> - </para> -</sect1> - -<sect1 id="gas"> -<title>gas.step</title> -<para> - </para> -</sect1> </chapter> Files old/step-4.7.4/doc/index.cache.bz2 and new/step-4.8.0/doc/index.cache.bz2 differ diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/doc/index.docbook new/step-4.8.0/doc/index.docbook --- old/step-4.7.4/doc/index.docbook 2011-10-02 15:25:56.000000000 +0200 +++ new/step-4.8.0/doc/index.docbook 2011-12-20 20:13:26.000000000 +0100 @@ -122,7 +122,7 @@ </screenshot> <para>To help you get started, &step; integrates a series of tutorials which easily teach you how to build an experiment. Please see step by step to start with the first tutorial.</para> - +<!-- <sect1 id="board"> <title>The board</title> <para> @@ -136,12 +136,12 @@ - </para> </sect1> - +--> </chapter> &tutorials; &examples; - +<!-- <chapter id="commands"> <title>Command Reference</title> @@ -221,7 +221,7 @@ Not yet written </para> </chapter> - +--> <chapter id="credits"> <title>Credits and License</title> diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/step/data/examples/wave.step new/step-4.8.0/step/data/examples/wave.step --- old/step-4.7.4/step/data/examples/wave.step 2011-10-02 15:25:56.000000000 +0200 +++ new/step-4.8.0/step/data/examples/wave.step 2011-12-20 20:13:26.000000000 +0100 @@ -440,7 +440,7 @@ <html><head><meta name="qrichtext" content="1" /><style type="text/css"> p, li { white-space: pre-wrap; } </style></head><body style=" font-family:'Sans Serif'; font-size:10pt; font-weight:400; font-style:normal;"> -<p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">When you start simulation the wave starts to travel from the red particle. The blue particle will reflect the wave and it will travel in reverse direction unil the red particle reflects in again. After some time the wave will wanish because springs have damping.</p></body></html></text> +<p style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;">When you start simulation the wave starts to travel from the red particle. The blue particle will reflect the wave and it will travel in reverse direction until the red particle reflects in again. After some time the wave will vanish because springs have damping.</p></body></html></text> </item> diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/step/data/objinfo/LinearMotor.html new/step-4.8.0/step/data/objinfo/LinearMotor.html --- old/step-4.7.4/step/data/objinfo/LinearMotor.html 2011-10-02 15:25:56.000000000 +0200 +++ new/step-4.8.0/step/data/objinfo/LinearMotor.html 2011-12-20 20:13:26.000000000 +0100 @@ -8,6 +8,5 @@ <body> <p>A linear motor produces a linear force along it's length.</p> <p>you can set the desired linear force for an object by changing the force value in the properties browser.</p> -<p>For more details, please refer to the <a href="http://en.wikipedia.org/wiki/Linear_motor";>Linear Motor</a>.</p> </body> </html> diff -urN '--exclude=CVS' '--exclude=.cvsignore' '--exclude=.svn' '--exclude=.svnignore' old/step-4.7.4/step/step.desktop new/step-4.8.0/step/step.desktop --- old/step-4.7.4/step/step.desktop 2011-10-28 09:44:17.000000000 +0200 +++ new/step-4.8.0/step/step.desktop 2012-01-10 15:15:31.000000000 +0100 @@ -7,6 +7,7 @@ Terminal=false Name=Step Name[ast]=Step +Name[bg]=Step Name[bs]=Step Name[ca]=Step Name[ca@valencia]=Step @@ -30,6 +31,7 @@ Name[is]=Skref Name[it]=Step Name[ja]=Step +Name[kk]=Step Name[km]=ជំហាន Name[ko]=Step Name[lt]=Step @@ -54,6 +56,7 @@ Name[zh_TW]=物理_Step GenericName=Interactive Physical Simulator GenericName[ast]=Simulador físicu interactivu +GenericName[bg]=Интерактивен физически симулатор GenericName[bs]=Interaktivni simulator fizike GenericName[ca]=Simulador interactiu de física GenericName[ca@valencia]=Simulador interactiu de física @@ -74,6 +77,7 @@ GenericName[is]=Gagnvirkur eðlisfræðihemir GenericName[it]=Simulatore interattivo di fisica GenericName[ja]=対話式の物理シミュレータ +GenericName[kk]=Интерактивті физика иммитаторы GenericName[km]=កម្មវិធីត្រាប់តាមរូបសាស្ត្រអន្តរកម្ម GenericName[ko]=인터랙티브 물리학 시뮬레이터 GenericName[lt]=Interaktyvus fizikos modeliatorius @@ -95,6 +99,7 @@ GenericName[zh_TW]=互動式物理模擬器 Comment=Simulate physics experiments Comment[ast]=Simula esperimentos de física +Comment[bg]=Симулация на физически опити Comment[bs]=Simulira fizičke eksperimente Comment[ca]=Simuleu experiments de física Comment[ca@valencia]=Simuleu experiments de física @@ -117,6 +122,7 @@ Comment[is]=Líkir eftir eðlisfræðitilraunum Comment[it]=Simula esperimenti fisici Comment[ja]=物理の実験をシミュレートします +Comment[kk]=Физика эксперименттерінің иммитациясы Comment[km]=ត្រាប់តាមការពិសោធន៍រូបសាស្ត្រ Comment[ko]=물리 실험 시뮬레이션 Comment[lt]=Simuliuokite fizikos eksperimentus -- To unsubscribe, e-mail: [email protected] For additional commands, e-mail: [email protected]
