sil ver

• sil ver 2 Feb 2019 21:01 UTC

  3 points

  on: What kind of in­for­ma­tion would serve as the best ev­i­dence for re­solv­ing the de­bate of whether a cen­trist or leftist Demo­cratic nom­i­nee is like­lier to take the White House in 2020?

  This does not an­swer the ques­tion, but it seems plau­si­ble to me that the leftist-cen­trist axis only has a very small im­pact on who is likely to win, which would be con­sis­tent with Pre­dic­tIt’s es­ti­mates.

• sil ver 1 Feb 2019 17:36 UTC

  13 points

  on: Drexler on AI Risk

  6.7 Sys­tems com­posed of ra­tio­nal agents need not max­i­mize a util­ity func­tion There is no canon­i­cal way to ag­gre­gate util­ities over agents, and game the­ory shows that in­ter­act­ing sets of ra­tio­nal agents need not achieve even Pareto op­ti­mal­ity.

  Is [un­der­lined] true? I know it’s true if you have agents fol­low­ing CDT, but does it still hold if agents fol­low FDT? (I think if you say ‘ra­tio­nal’ it should not mean ‘CDT’ since CDT is strictly worse than FDT).

• sil ver 4 Dec 2018 13:00 UTC

  1 point

  in reply to: TheWakalix's comment on: Topolog­i­cal Fixed Point Exercises

  $(v,w)$ is defined just for one par­tic­u­lar graph. It’s the first edge in that graph such that $f\left(v\right)<0<f\left(w\right)$. (So it could have been called $(v_n,w_n)$). Then for the next graph, it’s a differ­ent $v$. Ba­si­cally, $x_1$ looks at where the first graph skips over the zero mark, then picks the last ver­tex be­fore that point, then $x_2$ looks at the next larger graph, and if that graph skips later, it up­dates to the last ver­tex be­fore that point in that graph, etc. I think the rea­son I didn’t add in­dices to $(v,w)$ was just that there ar ealready the $v$ with two in­dices, but I see how it can be con­fus­ing since hav­ing no in­dex makes it sound like it’s the same value all through­out.

• sil ver 25 Nov 2018 22:52 UTC

  4 points

  in reply to: Charlie Steiner's comment on: How rapidly are GPUs im­prov­ing in price perfor­mance?

  That makes perfect sense. Thanks.

• sil ver 25 Nov 2018 21:47 UTC

  7 points

  in reply to: Charlie Steiner's comment on: How rapidly are GPUs im­prov­ing in price perfor­mance?

  When try­ing to fit an ex­po­nen­tial curve, don’t weight all the points equally.

  Um… why?

• sil ver 24 Nov 2018 23:23 UTC

  9 points

  AF

  on: Topolog­i­cal Fixed Point Exercises

  Ex 5 (fixed ver­sion)

  Let $D$ de­note the tri­an­gle. For each $n\in N$, con­struct a 2-d sim­plex $S_n$ with $(n+1{)}^2$ nodes in $D$, where the color of a point cor­re­sponds to the place in the disk that $f$ car­ries that point to, then choose $x_n$ to be a point within a trichro­matic tri­an­gle in the graph. Then $(x_n{)}_{n\in N}$ is a bounded se­quence hav­ing a limit point $x^{\ast }$. Let $t$ be the cen­ter of the disc; sup­pose that $f\left(x^{\ast }\right)\ne t$. Then there is at least one re­gion of the disc that $f\left(x^{\ast }\right)$ doesn’t touch. Let $ϵ$ be the dis­tance to the fur­thest side, that is, let $ϵ=\text{max}\left\{d\right(f\left(x^{\ast }\right),G),d(f\left(x^{\ast }\right),R),d(f\left(x^{\ast }\right),B\left)\right\}$. Since the sides are closed re­gions, we have $ϵ>0$. Us­ing con­ti­nu­ity of $f$, choose $\delta \in R_{+}$ small enough such that $B_d(x^{\ast },\delta )\subset B_d\left(f\right(x^{\ast }),ϵ)$. Then choose $n\in N$ large enough so that (1) all tri­an­gles in $S_n$ have di­ame­ter less than $\frac{\delta }{2}$ and (2) $d(x_n,x^{\ast })<\frac{\delta }{2}$. Then, given any other point $y$ in the tri­an­gle around $x_n$ in $S_n$, we have that $d(y,x^{\ast })\le d(y,x_n)+d(x_n,x^{\ast })<\frac{\delta }{2}+\frac{\delta }{2}=\delta$, so that $d\left(f\right(y),f(x^{\ast }\left)\right)<ϵ$. This proves that the tri­an­gle in $S_n$ does not map points to all three sides of the disc, con­tra­dict­ing the fact that it is trichro­matic.

  Ex 6

  (This is way eas­ier to demon­strate in a pic­ture in a way that leaves no doubt that it works than it is to write down, but I tried to do it any­way con­sid­er­ing that to be part of the difficulty.)

  (As­sume the tri­an­gle $T=\overline{ABO}$ is equilat­eral.) Imbed $T$ into $R^2$ such that $O=(0,0)$, $A=(-\frac{1}{2},\frac{1}{2}\sqrt{3})$, $B=(\frac{1}{2},\frac{1}{2}\sqrt{3})$. Let $f:T\mapsto T$ be con­tin­u­ous. Then $h:T\mapsto R^2$ given by $h:x\mapsto f\left(x\right)-x$ is also con­tin­u­ous. If $h\left(x\right)=O=(0,0)$ then $(0,0)=h\left(x\right)=f\left(x\right)-x⟹f\left(x\right)=x$. Let $R$ be the cir­cle with ra­dius 2 around $O$; then $h\left(T\right)\subset R$ be­cause $||h\left(x\right)||=||f\left(x\right)-x||\le ||f\left(x\right)||+||x||\le 2$ (it is in fact con­tained in the cir­cle with ra­dius 1, but the size of the cir­cle is in­con­se­quen­tial). We will use ex­er­cise 5 to show that $h$ maps a point to the cen­ter, which is $O$, from which the de­sired re­sult fol­lows. For this, we shall show that it has the needed prop­er­ties, with the mod­ifi­ca­tion that points on any side may map pre­cisely into the cen­ter. It’s ob­vi­ous that weak­en­ing the re­quire­ment in this way pre­serves the re­sult.

  Ro­tate the disk so that the red shape is on top. In po­lar co­or­di­nates, the green area now con­tains all points with an­gles be­tween ${60}^{\circ }$ and ${180}^{\circ }$ , the blue area con­tains those be­tween ${180}^{\circ }$ and ${300}^{\circ }$, and the red area those be­tween $0^{\circ }$ and ${60}^{\circ }$ and those be­tween ${300}^{\circ }$ and ${360}^{\circ }$. We will show that $h\left(\overline{AB}\right)$ does not in­ter­sect the red area, ex­cept at the ori­gin. First, note that we have

  $h\left(\overline{AB}\right)=\left\{f\right(x)-x|x\in \overline{AB}\}\subset \{y-x|x\in \overline{AB},y\in T\}=\{T-x|x\in \overline{AB}\}=T-\overline{AB}$

  Since both $T$ and $\overline{AB}$ are con­vex com­bi­na­tions of finitely many points, it suffices to check all com­bi­na­tions that re­sult by tak­ing a cor­ner from each. This means we need to check the points

  $A-A$ and $B-A$ and $C-A$ and $A-B$ and $B-B$ and $C-B$.

  Which are eas­ily com­puted to be

  $(0,0)$ and $(-1,0)$ and $(\frac{1}{2},-\frac{1}{2}\sqrt{3})$ and $(1,0)$ and $(0,0)$ and $(-\frac{1}{2},-\frac{1}{2}\sqrt{3})$

  Two of those are pre­cisely the ori­gin, the other four have an­gles ${270}^{\circ }$ and ${150}^{\circ }$ and ${90}^{\circ }$ and ${210}^{\circ }$. In­deed, they are all be­tween ${60}^{\circ }$ and ${300}^{\circ }$.

  Now one needs to do the same for the sets $T-\overline{OA}$ and $T-\overline{BO}$, but it goes through analo­gously.

• sil ver 23 Nov 2018 21:22 UTC

  13 points

  AF

  on: Topolog­i­cal Fixed Point Exercises

  I’m late, but I’m quite proud of this proof for #4:

  Call the large tri­an­gle a graph and the $n^2$ tri­an­gles sim­ply tri­an­gles. First, note that for any size, there is a graph where the top node is col­ored red, the re­main­ing nodes on the right di­ag­o­nal are col­ored green, and all nodes not on the right di­ag­o­nal are col­ored blue. This graph meets the con­di­tions, and has ex­actly one trichro­matic tri­an­gle, namely the one at the top (no other tri­an­gle con­tains a red node). It is triv­ial to see that this graph can be changed into an ar­bi­trary graph by re-col­or­ing finitely many nodes. This will af­fect up to six tri­an­gles; we say that a tri­an­gle has changed iff it was trichro­matic be­fore the re­col­or­ing but not af­ter, or vice versa, and we shall show that re-col­or­ing any node leads to an even num­ber of tri­an­gles be­ing changed. This proves that the num­ber of trichro­matic tri­an­gles never stops be­ing odd.

  La­bel the three col­ors $x,y$, and $z$. Let $v$ be the node be­ing re­col­ored, wlog from $x$ to $y$. Sup­pose first that $v$ has six neigh­bors. It is easy to see that a tri­an­gle be­tween $v$ and two neigh­bors has changed if and only if one of the neigh­bors has color $z$ and the other has color $x$ or $y$. Thus, we must show that the num­ber of such tri­an­gles is even. If all neigh­bors have color $z$, or if none of them do, then no tri­an­gles have changed. If ex­actly one node has color $z$, then the two ad­ja­cent tri­an­gles have changed. Other­wise, let $j$ and $k$ de­note two differ­ent neigh­bors of color $z$. There are two paths us­ing only neigh­bors of $v$ be­tween $j$ and $k$. Both start and end at a node of color $z$. By the 1-D Sperner Lemma (as­sum­ing the more gen­eral re­sult), it fol­lows that both paths have an even num­ber of edges be­tween nodes of color $z$ and $\{x,y\}$; these cor­re­spond to the tri­an­gles that have changed.

  If $v$ is a node on one of the graph’s bound­aries chang­ing color from $x$ to $y$, it has ex­actly 4 neigh­bors and three ad­ja­cent tri­an­gles. The two neigh­bors that are also on the bound­ary can­not have color $z$, so ei­ther none, one, or both of the ones that aren’t do. If it’s none, no tri­an­gle has changed; if it’s one, the two neigh­bor­ing tri­an­gles have changed; and if it’s both, then the two tri­an­gles with two nodes on the graph’s bound­ary have changed.

• sil ver 22 Nov 2018 20:12 UTC

  10 points

  AF

  on: Topolog­i­cal Fixed Point Exercises

  Ex 1

  Let $V=\{v_0,...,v_n\}$ and $e_k:=(v_{k-1},v_k)$. Given an edge $e$, let ${\varphi }_e$ de­note the map that maps the color of the left to that of the right node. Given a $k\in \{1,...,n\}$, let ${\varphi }_k={\varphi }_{e_k}\circ ...\circ {\varphi }_{e_1}$. Let $b$ de­note the color blue and $g$ the color green. Let $c\left(k\right)$ be 1 if edge $e_k$ is bichro­matic, and 0 oth­er­wise. Then we need to show that ${\varphi }_n\left(b\right)=g⟹\left({\sum }_{k=1}^{n}c\right(k\left)\right)\text{is odd}$. We’ll show $\left({\sum }_{k=1}^{n}c\right(k\left)\right)\text{is even}⟺{\varphi }_n\left(b\right)=b$, which is a stri­clty stronger state­ment than the con­tra­pos­i­tive.

  For $n=1$, the LHS is equiv­a­lent to $c\left({\varphi }_1\right)=1$, and in­deed $\varphi \left(e_1\right)\left(b\right)$ equals $g$ if $e_1$ is bichro­matic, and $b$ oth­er­wise. Now let $n>1$ and let it be true for $n-1$. Sup­pose ${\sum }_{k=1}^{n}c\left(k\right)\text{is even}$. Then, if $c\left(e_n\right)=1$, that means $\left({\sum }_{k=1}^{n-1}c\right(k\left)\right)\text{is odd}$, so that ${\varphi }_n\left(b\right)={\varphi }_{e_n}\left({\varphi }_{n-1}\right(b\left)\right)={\varphi }_{e_n}\left(g\right)=b$, and if $c\left(e_n\right)=0$, then $\left({\sum }_{k=1}^{n-1}c\right(k\left)\right)\text{is even}$, so that ${\varphi }_n\left(b\right)={\varphi }_{e_n}\left({\varphi }_{n-1}\right(b\left)\right)={\varphi }_{e_n}\left(b\right)=b$. Now sup­pose ${\sum }_{k=1}^{n}c\left(k\right)\text{is odd}$. If $c\left(e_n\right)=1$, then $\left({\sum }_{k=1}^{n-1}c\right(k\left)\right)\text{is even}$, so that ${\varphi }_n\left(b\right)={\varphi }_{e_n}\left({\varphi }_{n-1}\right(b\left)\right)={\varphi }_{e_n}\left(b\right)=g$, and if $c\left(e_n\right)=0$, then $\left({\sum }_{k=1}^{n-1}c\right(k\left)\right)\text{is odd}$, so that ${\varphi }_n\left(b\right)={\varphi }_{e_n}\left({\varphi }_{n-1}\right(b\left)\right)={\varphi }_{e_n}\left(g\right)=g$. This proves the lemma by in­duc­tion.

  Ex 2

  Or­di­nar­ily I’d proof by con­tra­dic­tion, us­ing se­quences, that $inf\{x\in [0,1\left]|f\right(x)>0\}$ can nei­ther be greater nor smaller than 0. I didn’t man­age a short way to do it us­ing the two lem­mas, but here’s a long way.

  Set $x_0=0$. Given $n\in N_{+}$, let $G_n$ be a path graph of $n+1$ ver­tices $\{v_{n,0},...,v_{n,n}\}$, where $v_{n,k}=\frac{k}{n}$. If for any $n$ and $k$ we have $f\left(v_{n,k}\right)=0$, then we’re done, so as­sume we don’t. Define $c(v,v^{\prime })$ to be 1 if $f\left(v\right)$ and $f\left(v^{\prime }\right)$ have s differ­ent sign, and 0 oth­er­wise. Sperner’s Lemma says that the num­ber of edges $e$ with $c\left(e\right)=1$ are odd; in par­tic­u­lar, there’s at least one. Let the first one be de­noted $(v,w)$, then set $x_n=max\{v,x_{n-1}\}$.

  Now con­sider the se­quence $(x_n{)}_{n\in N}$. It’s bounded be­cause $x_k\in [0,1]$. Us­ing the Bolzano-Weier­strass the­o­rem, let $(x_n^{\prime }{)}_{n\in N}\mapsto x^{\ast }$ be a con­ver­gent sub­se­quence. Since $f\left(x_k\right)>0$ for all $k\in N_{+}$, we have $f\left(x^{\ast }\right)\ge 0$. On the other hand, if $f\left(x^{\ast }\right)>0$, then, us­ing con­ti­nu­ity of $f$, we find a num­ber $x^{\prime }>x^{\ast }$ such that $f(x^{\ast },x^{\prime })>0$. Choose $n$ and $k$ such that $v_{n,k}\in (x^{\ast },x^{\prime })$, then $c\left(v_{n,j}\right)=0$ for all $j<k$, so that $x_n\ge v_{n,k}>x^{\ast }$ and then $x_{\ell }\ge x_n$ for all $\ell \ge k$, so that $x^{\ast }\ge x_n\ge v_{n,k}>x^{\ast }$, a con­tra­dic­tion.

  Ex 3

  Given such a func­tion $f$, let $g:[0,1]\mapsto [-1,1]$ be defined by $g\left(x\right)=f\left(x\right)-x$. We have $g\left(0\right)=f\left(0\right)-0\ge 0\ge f\left(1\right)-1=g\left(1\right)$. If ei­ther in­equal­ity isn’t strict, we’re done. Other­wise, $g\left(0\right)>0>g\left(1\right)$. Tak­ing for granted that the in­ter­me­di­ate value the­o­rem gen­er­al­izes to this case, find a root $x^{\ast }$ of $g$, then $f\left(x^{\ast }\right)=f\left(x^{\ast }\right)-x^{\ast }+x^{\ast }=g\left(x^{\ast }\right)+x^{\ast }=x^{\ast }$.

• sil ver 21 Nov 2018 18:03 UTC

  3 points

  on: Preschool: Much Less Than You Wanted To Know

  Mostly agreed. But I think the ob­vi­ous counter point is that you’re ar­gu­ing for a slightly differ­ent stan­dard. Like, if the ques­tion is ‘does pre-school ba­si­cally make sense’ then you’re right, it doesn’t, and the black box ap­proach is weird. But if the ques­tion is ‘should you send your chil­dren to pre-school’ then the black box ap­proach seems solid. Even if you could come up with some­thing bet­ter in five min­utes, you can’t im­ple­ment it, so the stan­dard for it be­ing worth­while might be re­ally low.

• sil ver 18 Nov 2018 23:11 UTC

  13 points

  AF

  on: Di­ag­o­nal­iza­tion Fixed Point Exercises

  Ex 4

  Given a com­putable func­tion $\varphi :S\mapsto \text{Comp}(S,\{T,F\left\}\right)$, define a func­tion $f:S\mapsto \{T,F\}$ by the rule $f\left(s\right)=\{\begin{array}{cc}T& \varphi \left(s\right)\left(s\right)=F\\ F& \varphi \left(s\right)\left(s\right)=T\end{array}$. Then $f$ is com­putable, how­ever, $f\notin \varphi \left(S\right)$ be­cause for $s\in S$, we have that $\varphi \left(s\right)\left(s\right)=F⟹f\left(s\right)=T⟹\varphi \left(s\right)\ne f$ and $\varphi \left(s\right)\left(s\right)=T⟹f\left(s\right)=F⟹\varphi \left(s\right)\ne f$.

  Ex 5:

  We show the con­tra­pos­i­tive: given a func­tion halt, we con­struct a sur­jec­tive func­tion $f$ from $S$ to $\text{Comp}(S,\{T,F\left\}\right)$ as fol­lows: enu­mer­ate all tur­ing ma­chines, such that each cor­re­sponds to a string. Given a $t\in S$, if $t$ does not de­code to a tur­ing ma­chine, set $f\left(t\right)\equiv F$. If it does, let $\left[t\right]$ de­note that turn­ing ma­chine. Let $f\left(t\right)$ with in­put $s\in S$ first run halt$(t,s)$; if halt re­turns $F$, put out $F$, oth­er­wise $\left[t\right]$ will halt on in­put $s$; run $\left[t\right]$ on $s$ and put out the re­sult.

  Given a com­putable func­tion $g:S\mapsto \{T,F\}$, there is a string $t^{\ast }\in S$ such that $\left[t^{\ast }\right]$ im­ple­ments $g$ (if the tur­ing the­sis is true). Then $g=f\left(t^{\ast }\right)$, so that $f$ is sur­jec­tive.

  Ex 6:

  Let $h:R\mapsto S$ be a parametriza­tion of the cir­cle given by $h\left(r\right)\mapsto \left(\cos \right(r),\sin (r\left)\right)$. Given $p\in S$ and $r\in R$, write $p+r$ to de­note the point $h(p^{\prime }+r)$, where $p^{\prime }\in h^{-1}\left(\right\{p\left\}\right)$. First, note that, re­gard­less of the topol­ogy on $X$, it holds true that if $f:X\mapsto S$ is con­tin­u­ous, then so is $f_r:x\mapsto f\left(x\right)+r$ for any $r\in R$, be­cause given a ba­sis el­e­ment $\left(h\right(a),h(b\left)\right)$ of the cir­cle, we have $f_r^{-1}\left(B\right)=f^{-1}\left(h\right(a)-r,h(b)-r)$ which is open be­cause $f$ is con­tin­u­ous.

  Let $\varphi$ be a con­tin­u­ous func­tion from $X$ to $\text{Cont}(X,S)$. Then ${\varphi }^{\prime }:X\times X\mapsto S$ is con­tin­u­ous, and so is the di­ag­o­nal func­tion $h:x\mapsto \varphi (x,x)$. Fix any $r\in (0,2\pi )$, then $f:X\mapsto S$ given by $f:x\mapsto \left({\varphi }^{\prime }\right(x,x)+r))$ is also con­tin­u­ous, but given any $x\in X$, one has $\varphi \left(x\right)\left(x\right)={\varphi }^{\prime }(x,x)\ne {\varphi }^{\prime }(x,x)+r=f\left(x\right)$ and thus $\varphi \left(x\right)\ne f$. It fol­lows that $\varphi$ is not sur­jec­tive.

  Ex 7:

  I did it in java. There’s prob­a­bly eas­ier ways to do this, es­pe­cially in other lan­guages, but it still works. It was in­cred­ibly fun to do. My ba­sic idea was to have a loop iter­ate 2 times, the first time print­ing the pro­gram, the sec­ond time print­ing the print­ing com­mand. Es­cap­ing the ” char­ac­ters is the biggest prob­lem, the main idea here was to have a string q that equals ” in the first iter­a­tion and ” + q + ” in the sec­ond. That sec­ond string (as part of the code in an ex­pres­sion where a string is printed) will print it­self in the con­sole out­put. Code:

  pack­age maths;pub­lic class Quine{pub­lic static void main(String[]args){for(int i=0;i<2;i++){String o=i==1?“”+(char)34:“”;String q=“”+(char)34;q=i==1?q+“+q+“+q:q;String e=i==1?o+“+e);}}}“:”Sys­tem.out.print(o+“;Sys­tem.out.print(o+“pack­age maths;pub­lic class Quine{pub­lic static void main(String[]args){for(int i=0;i<2;i++){String o=i==1?“+q+“”+q+“+(char)34:“+q+“”+q+“;String q=“+q+“”+q+“+(char)34;q=i==1?q+“+q+“+q+“+q+“+q:q;String e=i==1?o+“+q+“+e);}}}“+q+“:”+q+“Sys­tem.out.print(o+“+q+“;”+e);}}}

• sil ver 18 Nov 2018 20:57 UTC

  11 points

  AF

  on: Di­ag­o­nal­iza­tion Fixed Point Exercises

  Ex 1

  Ex­er­cise 1: Let $f:S\mapsto P\left(S\right)$ and let $A=\{x\in S|x\notin f(x\left)\right\}$. Sup­pose that $A\in f\left(S\right)$, then let $x\in S$ be an el­e­ment such that $f\left(x\right)=A$. Then $x\notin f\left(x\right)=A⟹x\in A$ by defi­ni­tion, and $x\in A=f\left(x\right)⟹x\notin A$. So $x\notin A⟺x\in A$, a con­tra­dic­tion. Hence $A\notin f\left(S\right)$, so that $f$ is not sur­jec­tive.

  Ex 2

  Ex­er­cise 2: Since $T$ is nonempty, it con­tains at least one el­e­ment $t_0$. Let $h:T\mapsto T$ be a func­tion with­out a fixed point, then $t_0\ne h\left(t_0\right)=:t_1$, so that $t_0$ and $t_1$ are two differ­ent el­e­ments in $T$ (this is the only thing we shall use the func­tion $h$ for).

  Let $\Psi :S\mapsto T^S$ for $S$ nonempty. Sup­pose by con­tra­dic­tion that $\Psi$ is sur­jec­tive. Define a map $f:S\mapsto P\left(S\right)$ by the rule $f\left(x\right)=\{s\in S|\Psi (x\left)\right(s)=t_0\}$. Given any sub­set $U\subset S$, let $g:S\mapsto T$ be given by $g:x\mapsto \{\begin{array}{cc}{t}_0& x\in U\\ t_1& x\notin U\end{array}$ Since $\Psi$ is sur­jec­tive, we find a $s^{\ast }\in S$ such that $\Psi \left(s^{\ast }\right)=g$. Then $f\left(s^{\ast }\right)=U$. This proves that $f$ is sur­jec­tive, which con­tra­dicts the re­sult from (a).

  Ex 3

  Ex­er­cise 3: By (2) we know that $T=\left\{x\right\}$, and so $f=\left\{\right(x,x\left)\right\}$ and $g=\left\{\right(s,h)|s\in S\}$ where $h=\left\{\right(s,x)|s\in S\}$. That means $x=g\left(s\right)\left(s^{\prime }\right)=f^n\left(g\right(s\left)\right(s^{\prime }\left)\right)$ for any $s,s^{\prime }\in S$. and $n\in N$.

• sil ver 16 Nov 2018 19:32 UTC

  5 points

  on: Sam Har­ris and the Is–Ought Gap

  Good post. I think Car­roll’s PoV is cor­rect and Sam’s is prob­a­bly cor­rect. Think­ing about it, I would have phrased that one very differ­ently, but I think there’d be zero differ­ence on sub­stance.

  Edit: Hav­ing caught my­self refer­enc­ing this to ex­plain Har­ris po­si­tion, I amend my post to say that the way you put is ac­tu­ally ex­actly right, and the way I would have put it would at best have been a mildly con­fused ver­sion of the same thing.

• sil ver 4 Sep 2018 13:04 UTC

  2 points

  in reply to: ChristianKl's comment on: Open Thread Septem­ber 2018

  I wouldn’t call the an­swer ob­vi­ous. I’m not even sure if I could have guessed the ma­jor­ity view on this be­fore­hand. Why do you think it’s ob­vi­ous? Are there no up­sides to chang­ing or are the down­sides too sig­nifi­cant?

• sil ver 24 Aug 2018 19:29 UTC

  7 points

  on: Turn­ing Up the Heat: In­sights from Tao’s ‘Anal­y­sis II’

  There’s a lot I wanted to say here about topol­ogy, but I don’t think my un­der­stand­ing is good enough to break things down—I’ll have to read an ac­tual book on the sub­ject.

  I’m work­ing through Munkres’ book on topol­ogy at the mo­ment, which is part of Miri’s re­ser­ach guide. It’s su­per awe­some; rigor­ous, com­pre­hen­sive, el­e­gant, and quite long (with lots of ex­er­cises). I’m plan­ing to do a similar post once I’m done, but it’s tak­ing me a while. if you get to it even­tu­ally, you’ll prob­a­bly beat me to it.

• sil ver 28 Jul 2018 15:22 UTC

  1 point

  in reply to: cousin_it's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  1000:1 on tails (with tails → cre­ate large uni­verse). It’s a very good ques­tion. My an­swer is late be­cause it made me think about some stuff that con­fused me at first, an I wanted to make sure that ev­ery­thing I say now is co­her­ent with ev­ery­thing I said in the post.

  If god flipped enough log­i­cal coins for you to be able to make the ap­prox­i­ma­tion that half of them came up heads, you can up­date on the color of your log­i­cal coin based on the fact that your cur­rent ver­sion is green. This is a thou­sand times as likely if the green coin came up tails vs heads. You can’t do the same if god only cre­ated one uni­verse.

  If god cre­ated more than one but still only a few uni­verses, let’s say two, then the chance that your coin came up heads is a bit more than a quar­ter, which comes from the heads-heads case. The heads-tails case is pos­si­ble but highly un­likely.

• sil ver 25 Jul 2018 14:35 UTC

  1 point

  in reply to: cousin_it's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  Yes.

  I’m not used to the con­cept of a log­i­cal coin, but yes, that’s equiv­a­lent.

  You need the con­scious­ness con­di­tion & that god only does this once. Then my the­ory out­puts the SSA an­swer.

• sil ver 24 Jul 2018 21:28 UTC

  1 point

  in reply to: cousin_it's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  No; like I said, pro­ce­dures tend to be re­peat­able. Maybe there is one, but I haven’t come up with one yet. What’s wrong with the pre­sump­tu­ous philoso­pher prob­lem (about two pos­si­ble uni­verses) as an ex­am­ple?

• sil ver 24 Jul 2018 14:56 UTC

  1 point

  in reply to: TAG's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  Ok, so I think our ex­change can be sum­ma­rized like this: I am op­er­at­ing on the as­sump­tion that nu­mer­i­cal non-iden­tity given qual­i­ta­tive iden­tity is not a thing, and you doubt that as­sump­tion. We both agree that the as­sump­tion is nec­es­sary for the ar­gu­ment I made to be con­vinc­ing.

• sil ver 24 Jul 2018 14:23 UTC

  1 point

  in reply to: TAG's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  I was un­der the im­pres­sion that the op­po­site was the case, that nu­mer­i­cal non-iden­tity given qual­i­ta­tive iden­tity is moon­sh­ine. I’m not a physi­cian though, so I can’t ar­gue with you on the ob­ject level. Do you think that your po­si­tion would be a ma­jor­ity view on LW?

• sil ver 24 Jul 2018 13:27 UTC

  1 point

  in reply to: TAG's comment on: An­thropic Prob­a­bil­ities: a differ­ent approach

  You mean The two bod­ies aren’t the self­same body (nu­mer­i­cal iden­tity)

  You mean iden­tity of par­ti­cles? I was just as­sum­ing that there is no such thing. I agree that if there was, that would be a sim­pler ex­pla­na­tion.