Received: from 173-13-139-235-sfba.hfc.comcastbusiness.net ([173.13.139.235]:52169 helo=jukni.digitalkingdom.org) by stodi.digitalkingdom.org with smtp (Exim 4.86) (envelope-from ) id 1aU4vz-0000el-Ny; Thu, 11 Feb 2016 20:02:24 -0800 Received: by jukni.digitalkingdom.org (sSMTP sendmail emulation); Thu, 11 Feb 2016 20:02:19 -0800 From: "Apache" Date: Thu, 11 Feb 2016 20:02:19 -0800 To: webmaster@lojban.org, curtis289@att.net Subject: [jvsw] Definition Edited At Word tartidu -- By krtisfranks Bcc: jbovlaste-admin@lojban.org Message-ID: <56bd594b.kf0xIqGBUYQ3dfH+%webmaster@lojban.org> User-Agent: Heirloom mailx 12.5 7/5/10 MIME-Version: 1.0 Content-Type: text/plain; charset=us-ascii Content-Transfer-Encoding: quoted-printable X-Spam-Score: 0.5 (/) X-Spam_score: 0.5 X-Spam_score_int: 5 X-Spam_bar: / X-Spam-Report: Spam detection software, running on the system "stodi.digitalkingdom.org", has NOT identified this incoming email as spam. The original message has been attached to this so you can view it or label similar future email. If you have any questions, see the administrator of that system for details. Content preview: In jbovlaste, the user krtisfranks has edited a definition of "tartidu" in the language "English". Differences: 5,5c5,5 < The equality should be exact in a model/in theory. If one is taking a linear approximation of a function which does not behave linearly with respect to $x_2$, then caveats must be included (such as by using a tanru in order to specify approximation) or by separation (using {be}; "f approximates g, which is proportional [{tartidu}] to h, with error z, which is proportional [{tartidu}] to w"). $x_2$ can be any of a fairly general class of nunvers, including a variable/unknown (with or without units) and a function (which need not be linear). Inverse or joint proportionality can simply be expressed using division and multiplication respectively. All terbri should be filled with either pure numbers (li; general) or quantified concepts (such as physical quantities). --- > $x_2$ may be an incomplete list of quantities. These should be variable. $x_3$ should be a fixed constant for the universe, situation, object in question. $x_4$ is possibly variable but may also be fixed by the environmwnt/context/situation. The equality should be exact in a model/in theory. If one is taking a linear approximation of a function which does not behave linearly with respect to $x_2$, then caveats must be included (such as by using a tanru in order to specify approximation) or by separation (using {be}; "f approximates g, which is proportional [{tartidu}] to h, with error z, which is proportional [{tartidu}] to w"). $x_2$ can be any of a fairly general class of nunvers, including a variable/unknown (with or without units) and a function (which need not be linear). Inverse or joint proportionality can simply be expressed using division and multiplication respectively. All terbri should be filled with either pure numbers (li; general) or quantified concepts (such as physical quantities). [...] Content analysis details: (0.5 points, 5.0 required) pts rule name description ---- ---------------------- -------------------------------------------------- 0.0 URIBL_BLOCKED ADMINISTRATOR NOTICE: The query to URIBL was blocked. See http://wiki.apache.org/spamassassin/DnsBlocklists#dnsbl-block for more information. [URIs: lojban.org] 1.4 RCVD_IN_BRBL_LASTEXT RBL: No description available. [173.13.139.235 listed in bb.barracudacentral.org] -1.9 BAYES_00 BODY: Bayes spam probability is 0 to 1% [score: 0.0004] 1.0 RDNS_DYNAMIC Delivered to internal network by host with dynamic-looking rDNS In jbovlaste, the user krtisfranks has edited a definition of "tartidu" in the language "English". Differences: 5,5c5,5 < =09=09The equality should be exact in a model/in theory. If one is ta= king a linear approximation of a function which does not behave linearl= y with respect to $x_2$, then caveats must be included (such as by usin= g a tanru in order to specify approximation) or by separation (using {b= e}; "f approximates g, which is proportional [{tartidu}] to h, with err= or z, which is proportional [{tartidu}] to w"). $x_2$ can be any of a f= airly general class of nunvers, including a variable/unknown (with or w= ithout units) and a function (which need not be linear). Inverse or joi= nt proportionality can simply be expressed using division and multiplic= ation respectively. All terbri should be filled with either pure number= s (li; general) or quantified concepts (such as physical quantities). --- > =09=09$x_2$ may be an incomplete list of quantities. These should be = variable. $x_3$ should be a fixed constant for the universe, situation,= object in question. $x_4$ is possibly variable but may also be fixed b= y the environmwnt/context/situation. The equality should be exact in a = model/in theory. If one is taking a linear approximation of a function = which does not behave linearly with respect to $x_2$, then caveats must= be included (such as by using a tanru in order to specify approximatio= n) or by separation (using {be}; "f approximates g, which is proportion= al [{tartidu}] to h, with error z, which is proportional [{tartidu}] to= w"). $x_2$ can be any of a fairly general class of nunvers, including = a variable/unknown (with or without units) and a function (which need n= ot be linear). Inverse or joint proportionality can simply be expressed= using division and multiplication respectively. All terbri should be f= illed with either pure numbers (li; general) or quantified concepts (su= ch as physical quantities). Old Data: =09Definition: =09=09$x_1$ is directly/linearly proportional to $x_2$ via coefficient/= constant of proportionality $x_3$ and background/constant offset $x_4$;= there exists constants $x_3$ and $x_4$ such that $x_1 =3D x_3*x_2 + x_= 4$. =09Notes: =09=09The equality should be exact in a model/in theory. If one is taki= ng a linear approximation of a function which does not behave linearly = with respect to $x_2$, then caveats must be included (such as by using = a tanru in order to specify approximation) or by separation (using {be}= ; "f approximates g, which is proportional [{tartidu}] to h, with error= z, which is proportional [{tartidu}] to w"). $x_2$ can be any of a fai= rly general class of nunvers, including a variable/unknown (with or wit= hout units) and a function (which need not be linear). Inverse or joint= proportionality can simply be expressed using division and multiplicat= ion respectively. All terbri should be filled with either pure numbers = (li; general) or quantified concepts (such as physical quantities). =09Jargon: =09=09 =09Gloss Keywords: =09=09Word: proportional, In Sense:=20 =09Place Keywords: New Data: =09Definition: =09=09$x_1$ is directly/linearly proportional to $x_2$ via coefficient/= constant of proportionality $x_3$ and background/constant offset $x_4$;= there exists constants $x_3$ and $x_4$ such that $x_1 =3D x_3*x_2 + x_= 4$. =09Notes: =09=09$x_2$ may be an incomplete list of quantities. These should be va= riable. $x_3$ should be a fixed constant for the universe, situation, o= bject in question. $x_4$ is possibly variable but may also be fixed by = the environmwnt/context/situation. The equality should be exact in a mo= del/in theory. If one is taking a linear approximation of a function wh= ich does not behave linearly with respect to $x_2$, then caveats must b= e included (such as by using a tanru in order to specify approximation)= or by separation (using {be}; "f approximates g, which is proportional= [{tartidu}] to h, with error z, which is proportional [{tartidu}] to w= "). $x_2$ can be any of a fairly general class of nunvers, including a = variable/unknown (with or without units) and a function (which need not= be linear). Inverse or joint proportionality can simply be expressed u= sing division and multiplication respectively. All terbri should be fil= led with either pure numbers (li; general) or quantified concepts (such= as physical quantities). =09Jargon: =09=09 =09Gloss Keywords: =09=09Word: proportional, In Sense:=20 =09Place Keywords: You can go to to see it.