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Aleph-1

Last Updated: 12/10/2009

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Status: Single
City: Undisclosed Location
State: Michigan
Country: US
Signup Date: 11/22/2006

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Tuesday, January 06, 2009

END OF AN ERA: Blind Pig Jan 17th

YO! Peeps!

The upcoming Blind Pig show is the end of an era for Aleph-1

I'll be leaving the drum seat open and the January 17th Blind Pig show will be my last one playing with the group (dun dun dun). In accordance with the Myspace Band Member Departure Blog Committee, I feel some tasteless nostalgia is in order. I've had a ridiculously FUN time playing in the group, meeting new people, enjoying the company of said people and really having the time of my life. WAY too many good times to count. WAY too many great people to name.

Listening back to the older tapes, I realized that most of my development as a musician came with the band; I wish my personality had refined a bit too but that's life. I've loved playing the tunes and trying to put as much of myself into it as possible... especially The Shank. We all really tried to make the shows as ridiculously fast paced, energetic and as out of control as possible, despite Founders telling us we scared away their dinner crowd. With that said, I want to shift into "open internet letter" mode, an inherently creep show mode to be in but alas I digress. Its been an incredible privilege to play with Duwe and JP, I really can't put it into words; they are just fucking stellar musicians/people. Upon revising this blog posting I wanted to emphasize the previous sentence but bold lettering and emoticons only go so far.

In the coming months, another manifestation of Aleph-1 will probably arrise, starting where I'll leave off. JP and Duwe write the hooks so everything will be fine. As for me, I'll be leaving town Feb 14th to begin an expansive three month European Tour with the group Capillary Action. Before we leave we'll be doing a brief tour through the Midwest and East Coast (with dates in Ann Arbor). You can keep up with any show stuff going on with any of us using the links below.

Lovingly,
Dirty Suth

LINKS:
JP
Duwe
Dan

10:36 AM

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Wednesday, May 16, 2007

What our name means

In the branch of mathematics known as set theory, the aleph numbers are a sequence of numbers used to represent the cardinality (or size) of infinite sets. They are named after the symbol used to denote them, the Hebrew letter aleph ( $..aleph$ ).

The cardinality of the natural numbers is $..aleph_0$ (aleph-null, also aleph-naught, aleph-zero or aleph-nought); the next larger cardinality is aleph-one $..aleph_1$ , then $..aleph_2$ and so on. Continuing in this manner, it is possible to define a cardinal number $..aleph_..alpha$ for every ordinal number a, as described below.

The concept goes back to Georg Cantor, who defined the notion of cardinality and realized that infinite sets can have different cardinalities.

The aleph numbers differ from the infinity (8) commonly found in algebra and calculus. Alephs measure the sizes of sets; infinity, on the other hand, is commonly defined as an extreme limit of the real number line, or an extremal point of the extended real number line. While some alephs are larger than others, 8 is just 8.

Aleph-one

$..aleph_1$ is the cardinality of the set of all countable ordinal numbers, called ?₁ or O. Notice ?₁ is an uncountable set. This definition implies (already in ZF, Zermelo-Fraenkel set theory without the axiom of choice) that no cardinal number is between $..aleph_0$ and $..aleph_1$ . If the axiom of choice (AC) is used, it can be further proved that the class of cardinal numbers is totally ordered, and thus $..aleph_1$ is the second-smallest infinite cardinal number. Using AC we can show one of the most useful properties of the set O (the standard example of a set of size $..aleph_1$ ): any countable subset of O has an upper bound (with respect to the standard well-ordering of ordinals) in O (the proof is easy: a countable union of countable sets is countable; this is one of the most common applications of AC). This fact is analogous to the situation in $..aleph_0$ : any finite set of natural numbers (subset of ?) has a maximum which is also a natural number (has an upper bound in ?) — finite unions of finite sets are finite.

O is actually a useful concept, if somewhat exotic-sounding. An example application is "closing" with respect to countable operations; e.g., trying to explicitly describe the s-algebra generated by an arbitrary collection of subsets. This is harder than most explicit descriptions of "generation" in algebra (for example vector spaces, groups, etc.) because in those cases we only have to close with respect to finite operations — sums, products, and the like. The process involves defining, for each countable ordinal, via transfinite induction, a set by "throwing in" all possible countable unions and complements, and taking the union of all that over all of O.