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Theorem List for Metamath Proof Explorer - 20101-20200   *Has distinct variable group(s)
TypeLabelDescription
Statement
 
Theoremringcmnd 20101 A ring is a commutative monoid. (Contributed by SN, 1-Jun-2024.)
(๐œ‘ โ†’ ๐‘… โˆˆ Ring)    โ‡’   (๐œ‘ โ†’ ๐‘… โˆˆ CMnd)
 
Theoremringpropd 20102* If two structures have the same base set, and the values of their group (addition) and ring (multiplication) operations are equal for all pairs of elements of the base set, one is a ring iff the other one is. (Contributed by Mario Carneiro, 6-Dec-2014.) (Revised by Mario Carneiro, 6-Jan-2015.)
(๐œ‘ โ†’ ๐ต = (Baseโ€˜๐พ))    &   (๐œ‘ โ†’ ๐ต = (Baseโ€˜๐ฟ))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต)) โ†’ (๐‘ฅ(+gโ€˜๐พ)๐‘ฆ) = (๐‘ฅ(+gโ€˜๐ฟ)๐‘ฆ))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต)) โ†’ (๐‘ฅ(.rโ€˜๐พ)๐‘ฆ) = (๐‘ฅ(.rโ€˜๐ฟ)๐‘ฆ))    โ‡’   (๐œ‘ โ†’ (๐พ โˆˆ Ring โ†” ๐ฟ โˆˆ Ring))
 
Theoremcrngpropd 20103* If two structures have the same group components (properties), one is a commutative ring iff the other one is. (Contributed by Mario Carneiro, 8-Feb-2015.)
(๐œ‘ โ†’ ๐ต = (Baseโ€˜๐พ))    &   (๐œ‘ โ†’ ๐ต = (Baseโ€˜๐ฟ))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต)) โ†’ (๐‘ฅ(+gโ€˜๐พ)๐‘ฆ) = (๐‘ฅ(+gโ€˜๐ฟ)๐‘ฆ))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต)) โ†’ (๐‘ฅ(.rโ€˜๐พ)๐‘ฆ) = (๐‘ฅ(.rโ€˜๐ฟ)๐‘ฆ))    โ‡’   (๐œ‘ โ†’ (๐พ โˆˆ CRing โ†” ๐ฟ โˆˆ CRing))
 
Theoremringprop 20104 If two structures have the same ring components (properties), one is a ring iff the other one is. (Contributed by Mario Carneiro, 11-Oct-2013.)
(Baseโ€˜๐พ) = (Baseโ€˜๐ฟ)    &   (+gโ€˜๐พ) = (+gโ€˜๐ฟ)    &   (.rโ€˜๐พ) = (.rโ€˜๐ฟ)    โ‡’   (๐พ โˆˆ Ring โ†” ๐ฟ โˆˆ Ring)
 
Theoremisringd 20105* Properties that determine a ring. (Contributed by NM, 2-Aug-2013.)
(๐œ‘ โ†’ ๐ต = (Baseโ€˜๐‘…))    &   (๐œ‘ โ†’ + = (+gโ€˜๐‘…))    &   (๐œ‘ โ†’ ยท = (.rโ€˜๐‘…))    &   (๐œ‘ โ†’ ๐‘… โˆˆ Grp)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต) โ†’ (๐‘ฅ ยท ๐‘ฆ) โˆˆ ๐ต)    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ ((๐‘ฅ ยท ๐‘ฆ) ยท ๐‘ง) = (๐‘ฅ ยท (๐‘ฆ ยท ๐‘ง)))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ (๐‘ฅ ยท (๐‘ฆ + ๐‘ง)) = ((๐‘ฅ ยท ๐‘ฆ) + (๐‘ฅ ยท ๐‘ง)))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ ((๐‘ฅ + ๐‘ฆ) ยท ๐‘ง) = ((๐‘ฅ ยท ๐‘ง) + (๐‘ฆ ยท ๐‘ง)))    &   (๐œ‘ โ†’ 1 โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต) โ†’ ( 1 ยท ๐‘ฅ) = ๐‘ฅ)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต) โ†’ (๐‘ฅ ยท 1 ) = ๐‘ฅ)    โ‡’   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)
 
Theoremiscrngd 20106* Properties that determine a commutative ring. (Contributed by Mario Carneiro, 7-Jan-2015.)
(๐œ‘ โ†’ ๐ต = (Baseโ€˜๐‘…))    &   (๐œ‘ โ†’ + = (+gโ€˜๐‘…))    &   (๐œ‘ โ†’ ยท = (.rโ€˜๐‘…))    &   (๐œ‘ โ†’ ๐‘… โˆˆ Grp)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต) โ†’ (๐‘ฅ ยท ๐‘ฆ) โˆˆ ๐ต)    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ ((๐‘ฅ ยท ๐‘ฆ) ยท ๐‘ง) = (๐‘ฅ ยท (๐‘ฆ ยท ๐‘ง)))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ (๐‘ฅ ยท (๐‘ฆ + ๐‘ง)) = ((๐‘ฅ ยท ๐‘ฆ) + (๐‘ฅ ยท ๐‘ง)))    &   ((๐œ‘ โˆง (๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต โˆง ๐‘ง โˆˆ ๐ต)) โ†’ ((๐‘ฅ + ๐‘ฆ) ยท ๐‘ง) = ((๐‘ฅ ยท ๐‘ง) + (๐‘ฆ ยท ๐‘ง)))    &   (๐œ‘ โ†’ 1 โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต) โ†’ ( 1 ยท ๐‘ฅ) = ๐‘ฅ)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต) โ†’ (๐‘ฅ ยท 1 ) = ๐‘ฅ)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ต โˆง ๐‘ฆ โˆˆ ๐ต) โ†’ (๐‘ฅ ยท ๐‘ฆ) = (๐‘ฆ ยท ๐‘ฅ))    โ‡’   (๐œ‘ โ†’ ๐‘… โˆˆ CRing)
 
Theoremringlz 20107 The zero of a unital ring is a left-absorbing element. (Contributed by FL, 31-Aug-2009.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ ( 0 ยท ๐‘‹) = 0 )
 
Theoremringrz 20108 The zero of a unital ring is a right-absorbing element. (Contributed by FL, 31-Aug-2009.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ (๐‘‹ ยท 0 ) = 0 )
 
Theoremringsrg 20109 Any ring is also a semiring. (Contributed by Thierry Arnoux, 1-Apr-2018.)
(๐‘… โˆˆ Ring โ†’ ๐‘… โˆˆ SRing)
 
Theoremring1eq0 20110 If one and zero are equal, then any two elements of a ring are equal. Alternately, every ring has one distinct from zero except the zero ring containing the single element {0}. (Contributed by Mario Carneiro, 10-Sep-2014.)
๐ต = (Baseโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต) โ†’ ( 1 = 0 โ†’ ๐‘‹ = ๐‘Œ))
 
Theoremring1ne0 20111 If a ring has at least two elements, its one and zero are different. (Contributed by AV, 13-Apr-2019.)
๐ต = (Baseโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง 1 < (โ™ฏโ€˜๐ต)) โ†’ 1 โ‰  0 )
 
Theoremringinvnz1ne0 20112* In a unital ring, a left invertible element is different from zero iff 1 โ‰  0. (Contributed by FL, 18-Apr-2010.) (Revised by AV, 24-Aug-2021.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ โˆƒ๐‘Ž โˆˆ ๐ต (๐‘Ž ยท ๐‘‹) = 1 )    โ‡’   (๐œ‘ โ†’ (๐‘‹ โ‰  0 โ†” 1 โ‰  0 ))
 
Theoremringinvnzdiv 20113* In a unital ring, a left invertible element is not a zero divisor. (Contributed by FL, 18-Apr-2010.) (Revised by Jeff Madsen, 18-Apr-2010.) (Revised by AV, 24-Aug-2021.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ โˆƒ๐‘Ž โˆˆ ๐ต (๐‘Ž ยท ๐‘‹) = 1 )    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ ((๐‘‹ ยท ๐‘Œ) = 0 โ†” ๐‘Œ = 0 ))
 
Theoremringnegl 20114 Negation in a ring is the same as left multiplication by -1. (rngonegmn1l 36809 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ ((๐‘โ€˜ 1 ) ยท ๐‘‹) = (๐‘โ€˜๐‘‹))
 
Theoremringnegr 20115 Negation in a ring is the same as right multiplication by -1. (rngonegmn1r 36810 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ (๐‘‹ ยท (๐‘โ€˜ 1 )) = (๐‘โ€˜๐‘‹))
 
Theoremringmneg1 20116 Negation of a product in a ring. (mulneg1 11650 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ ((๐‘โ€˜๐‘‹) ยท ๐‘Œ) = (๐‘โ€˜(๐‘‹ ยท ๐‘Œ)))
 
Theoremringmneg2 20117 Negation of a product in a ring. (mulneg2 11651 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ (๐‘‹ ยท (๐‘โ€˜๐‘Œ)) = (๐‘โ€˜(๐‘‹ ยท ๐‘Œ)))
 
Theoremringm2neg 20118 Double negation of a product in a ring. (mul2neg 11653 analog.) (Contributed by Mario Carneiro, 4-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ ((๐‘โ€˜๐‘‹) ยท (๐‘โ€˜๐‘Œ)) = (๐‘‹ ยท ๐‘Œ))
 
Theoremringsubdi 20119 Ring multiplication distributes over subtraction. (subdi 11647 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    โˆ’ = (-gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ (๐‘‹ ยท (๐‘Œ โˆ’ ๐‘)) = ((๐‘‹ ยท ๐‘Œ) โˆ’ (๐‘‹ ยท ๐‘)))
 
Theoremringsubdir 20120 Ring multiplication distributes over subtraction. (subdir 11648 analog.) (Contributed by Jeff Madsen, 19-Jun-2010.) (Revised by Mario Carneiro, 2-Jul-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    โˆ’ = (-gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐‘ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ ((๐‘‹ โˆ’ ๐‘Œ) ยท ๐‘) = ((๐‘‹ ยท ๐‘) โˆ’ (๐‘Œ ยท ๐‘)))
 
Theoremmulgass2 20121 An associative property between group multiple and ring multiplication. (Contributed by Mario Carneiro, 14-Jun-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.gโ€˜๐‘…)    &    ร— = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง (๐‘ โˆˆ โ„ค โˆง ๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต)) โ†’ ((๐‘ ยท ๐‘‹) ร— ๐‘Œ) = (๐‘ ยท (๐‘‹ ร— ๐‘Œ)))
 
Theoremring1 20122 The (smallest) structure representing a zero ring. (Contributed by AV, 28-Apr-2019.)
๐‘€ = {โŸจ(Baseโ€˜ndx), {๐‘}โŸฉ, โŸจ(+gโ€˜ndx), {โŸจโŸจ๐‘, ๐‘โŸฉ, ๐‘โŸฉ}โŸฉ, โŸจ(.rโ€˜ndx), {โŸจโŸจ๐‘, ๐‘โŸฉ, ๐‘โŸฉ}โŸฉ}    โ‡’   (๐‘ โˆˆ ๐‘‰ โ†’ ๐‘€ โˆˆ Ring)
 
Theoremringn0 20123 Rings exist. (Contributed by AV, 29-Apr-2019.)
Ring โ‰  โˆ…
 
Theoremringlghm 20124* Left-multiplication in a ring by a fixed element of the ring is a group homomorphism. (It is not usually a ring homomorphism.) (Contributed by Mario Carneiro, 4-May-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ (๐‘ฅ โˆˆ ๐ต โ†ฆ (๐‘‹ ยท ๐‘ฅ)) โˆˆ (๐‘… GrpHom ๐‘…))
 
Theoremringrghm 20125* Right-multiplication in a ring by a fixed element of the ring is a group homomorphism. (It is not usually a ring homomorphism.) (Contributed by Mario Carneiro, 4-May-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ (๐‘ฅ โˆˆ ๐ต โ†ฆ (๐‘ฅ ยท ๐‘‹)) โˆˆ (๐‘… GrpHom ๐‘…))
 
Theoremgsummulc1OLD 20126* Obsolete version of gsummulc1 20128 as of 7-Mar-2025. (Contributed by Mario Carneiro, 19-Dec-2014.) (Revised by AV, 10-Jul-2019.) (Proof modification is discouraged.) (New usage is discouraged.)
๐ต = (Baseโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &    + = (+gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘˜ โˆˆ ๐ด) โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹) finSupp 0 )    โ‡’   (๐œ‘ โ†’ (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ (๐‘‹ ยท ๐‘Œ))) = ((๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹)) ยท ๐‘Œ))
 
Theoremgsummulc2OLD 20127* Obsolete version of gsummulc2 20129 as of 7-Mar-2025. (Contributed by Mario Carneiro, 19-Dec-2014.) (Revised by AV, 10-Jul-2019.) (Proof modification is discouraged.) (New usage is discouraged.)
๐ต = (Baseโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &    + = (+gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘˜ โˆˆ ๐ด) โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹) finSupp 0 )    โ‡’   (๐œ‘ โ†’ (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ (๐‘Œ ยท ๐‘‹))) = (๐‘Œ ยท (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹))))
 
Theoremgsummulc1 20128* A finite ring sum multiplied by a constant. (Contributed by Mario Carneiro, 19-Dec-2014.) (Revised by AV, 10-Jul-2019.) Remove unused hypothesis. (Revised by SN, 7-Mar-2025.)
๐ต = (Baseโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘˜ โˆˆ ๐ด) โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹) finSupp 0 )    โ‡’   (๐œ‘ โ†’ (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ (๐‘‹ ยท ๐‘Œ))) = ((๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹)) ยท ๐‘Œ))
 
Theoremgsummulc2 20129* A finite ring sum multiplied by a constant. (Contributed by Mario Carneiro, 19-Dec-2014.) (Revised by AV, 10-Jul-2019.) Remove unused hypothesis. (Revised by SN, 7-Mar-2025.)
๐ต = (Baseโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘Œ โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘˜ โˆˆ ๐ด) โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹) finSupp 0 )    โ‡’   (๐œ‘ โ†’ (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ (๐‘Œ ยท ๐‘‹))) = (๐‘Œ ยท (๐‘… ฮฃg (๐‘˜ โˆˆ ๐ด โ†ฆ ๐‘‹))))
 
Theoremgsummgp0 20130* If one factor in a finite group sum of the multiplicative group of a commutative ring is 0, the whole "sum" (i.e. product) is 0. (Contributed by AV, 3-Jan-2019.)
๐บ = (mulGrpโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ CRing)    &   (๐œ‘ โ†’ ๐‘ โˆˆ Fin)    &   ((๐œ‘ โˆง ๐‘› โˆˆ ๐‘) โ†’ ๐ด โˆˆ (Baseโ€˜๐‘…))    &   ((๐œ‘ โˆง ๐‘› = ๐‘–) โ†’ ๐ด = ๐ต)    &   (๐œ‘ โ†’ โˆƒ๐‘– โˆˆ ๐‘ ๐ต = 0 )    โ‡’   (๐œ‘ โ†’ (๐บ ฮฃg (๐‘› โˆˆ ๐‘ โ†ฆ ๐ด)) = 0 )
 
Theoremgsumdixp 20131* Distribute a binary product of sums to a sum of binary products in a ring. (Contributed by Mario Carneiro, 8-Mar-2015.) (Revised by AV, 10-Jul-2019.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐ฝ โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   ((๐œ‘ โˆง ๐‘ฅ โˆˆ ๐ผ) โ†’ ๐‘‹ โˆˆ ๐ต)    &   ((๐œ‘ โˆง ๐‘ฆ โˆˆ ๐ฝ) โ†’ ๐‘Œ โˆˆ ๐ต)    &   (๐œ‘ โ†’ (๐‘ฅ โˆˆ ๐ผ โ†ฆ ๐‘‹) finSupp 0 )    &   (๐œ‘ โ†’ (๐‘ฆ โˆˆ ๐ฝ โ†ฆ ๐‘Œ) finSupp 0 )    โ‡’   (๐œ‘ โ†’ ((๐‘… ฮฃg (๐‘ฅ โˆˆ ๐ผ โ†ฆ ๐‘‹)) ยท (๐‘… ฮฃg (๐‘ฆ โˆˆ ๐ฝ โ†ฆ ๐‘Œ))) = (๐‘… ฮฃg (๐‘ฅ โˆˆ ๐ผ, ๐‘ฆ โˆˆ ๐ฝ โ†ฆ (๐‘‹ ยท ๐‘Œ))))
 
Theoremprdsmgp 20132 The multiplicative monoid of a product is the product of the multiplicative monoids of the factors. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘†Xs๐‘…)    &   ๐‘€ = (mulGrpโ€˜๐‘Œ)    &   ๐‘ = (๐‘†Xs(mulGrp โˆ˜ ๐‘…))    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘† โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘… Fn ๐ผ)    โ‡’   (๐œ‘ โ†’ ((Baseโ€˜๐‘€) = (Baseโ€˜๐‘) โˆง (+gโ€˜๐‘€) = (+gโ€˜๐‘)))
 
Theoremprdsmulrcl 20133 A structure product of rings has closed binary operation. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘†Xs๐‘…)    &   ๐ต = (Baseโ€˜๐‘Œ)    &    ยท = (.rโ€˜๐‘Œ)    &   (๐œ‘ โ†’ ๐‘† โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘…:๐ผโŸถRing)    &   (๐œ‘ โ†’ ๐น โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐บ โˆˆ ๐ต)    โ‡’   (๐œ‘ โ†’ (๐น ยท ๐บ) โˆˆ ๐ต)
 
Theoremprdsringd 20134 A product of rings is a ring. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘†Xs๐‘…)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘† โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘…:๐ผโŸถRing)    โ‡’   (๐œ‘ โ†’ ๐‘Œ โˆˆ Ring)
 
Theoremprdscrngd 20135 A product of commutative rings is a commutative ring. Since the resulting ring will have zero divisors in all nontrivial cases, this cannot be strengthened much further. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘†Xs๐‘…)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘† โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘…:๐ผโŸถCRing)    โ‡’   (๐œ‘ โ†’ ๐‘Œ โˆˆ CRing)
 
Theoremprds1 20136 Value of the ring unity in a structure family product. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘†Xs๐‘…)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘Š)    &   (๐œ‘ โ†’ ๐‘† โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘…:๐ผโŸถRing)    โ‡’   (๐œ‘ โ†’ (1r โˆ˜ ๐‘…) = (1rโ€˜๐‘Œ))
 
Theorempwsring 20137 A structure power of a ring is a ring. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐ผ โˆˆ ๐‘‰) โ†’ ๐‘Œ โˆˆ Ring)
 
Theorempws1 20138 Value of the ring unity in a structure power. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    &    1 = (1rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐ผ โˆˆ ๐‘‰) โ†’ (๐ผ ร— { 1 }) = (1rโ€˜๐‘Œ))
 
Theorempwscrng 20139 A structure power of a commutative ring is a commutative ring. (Contributed by Mario Carneiro, 11-Mar-2015.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    โ‡’   ((๐‘… โˆˆ CRing โˆง ๐ผ โˆˆ ๐‘‰) โ†’ ๐‘Œ โˆˆ CRing)
 
Theorempwsmgp 20140 The multiplicative group of the power structure resembles the power of the multiplicative group. (Contributed by Mario Carneiro, 12-Mar-2015.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    &   ๐‘€ = (mulGrpโ€˜๐‘…)    &   ๐‘ = (๐‘€ โ†‘s ๐ผ)    &   ๐‘ = (mulGrpโ€˜๐‘Œ)    &   ๐ต = (Baseโ€˜๐‘)    &   ๐ถ = (Baseโ€˜๐‘)    &    + = (+gโ€˜๐‘)    &    โœš = (+gโ€˜๐‘)    โ‡’   ((๐‘… โˆˆ ๐‘‰ โˆง ๐ผ โˆˆ ๐‘Š) โ†’ (๐ต = ๐ถ โˆง + = โœš ))
 
Theorempwspjmhmmgpd 20141* The projection given by pwspjmhm 18711 is also a monoid homomorphism between the respective multiplicative groups. (Contributed by SN, 30-Jul-2024.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    &   ๐ต = (Baseโ€˜๐‘Œ)    &   ๐‘€ = (mulGrpโ€˜๐‘Œ)    &   ๐‘‡ = (mulGrpโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐ผ)    โ‡’   (๐œ‘ โ†’ (๐‘ฅ โˆˆ ๐ต โ†ฆ (๐‘ฅโ€˜๐ด)) โˆˆ (๐‘€ MndHom ๐‘‡))
 
Theorempwsexpg 20142 Value of a group exponentiation in a structure power. Compare pwsmulg 18999. (Contributed by SN, 30-Jul-2024.)
๐‘Œ = (๐‘… โ†‘s ๐ผ)    &   ๐ต = (Baseโ€˜๐‘Œ)    &   ๐‘€ = (mulGrpโ€˜๐‘Œ)    &   ๐‘‡ = (mulGrpโ€˜๐‘…)    &    โˆ™ = (.gโ€˜๐‘€)    &    ยท = (.gโ€˜๐‘‡)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    &   (๐œ‘ โ†’ ๐ผ โˆˆ ๐‘‰)    &   (๐œ‘ โ†’ ๐‘ โˆˆ โ„•0)    &   (๐œ‘ โ†’ ๐‘‹ โˆˆ ๐ต)    &   (๐œ‘ โ†’ ๐ด โˆˆ ๐ผ)    โ‡’   (๐œ‘ โ†’ ((๐‘ โˆ™ ๐‘‹)โ€˜๐ด) = (๐‘ ยท (๐‘‹โ€˜๐ด)))
 
Theoremimasring 20143* The image structure of a ring is a ring. (Contributed by Mario Carneiro, 14-Jun-2015.)
(๐œ‘ โ†’ ๐‘ˆ = (๐น โ€œs ๐‘…))    &   (๐œ‘ โ†’ ๐‘‰ = (Baseโ€˜๐‘…))    &    + = (+gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &   (๐œ‘ โ†’ ๐น:๐‘‰โ€“ontoโ†’๐ต)    &   ((๐œ‘ โˆง (๐‘Ž โˆˆ ๐‘‰ โˆง ๐‘ โˆˆ ๐‘‰) โˆง (๐‘ โˆˆ ๐‘‰ โˆง ๐‘ž โˆˆ ๐‘‰)) โ†’ (((๐นโ€˜๐‘Ž) = (๐นโ€˜๐‘) โˆง (๐นโ€˜๐‘) = (๐นโ€˜๐‘ž)) โ†’ (๐นโ€˜(๐‘Ž + ๐‘)) = (๐นโ€˜(๐‘ + ๐‘ž))))    &   ((๐œ‘ โˆง (๐‘Ž โˆˆ ๐‘‰ โˆง ๐‘ โˆˆ ๐‘‰) โˆง (๐‘ โˆˆ ๐‘‰ โˆง ๐‘ž โˆˆ ๐‘‰)) โ†’ (((๐นโ€˜๐‘Ž) = (๐นโ€˜๐‘) โˆง (๐นโ€˜๐‘) = (๐นโ€˜๐‘ž)) โ†’ (๐นโ€˜(๐‘Ž ยท ๐‘)) = (๐นโ€˜(๐‘ ยท ๐‘ž))))    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    โ‡’   (๐œ‘ โ†’ (๐‘ˆ โˆˆ Ring โˆง (๐นโ€˜ 1 ) = (1rโ€˜๐‘ˆ)))
 
Theoremimasringf1 20144 The image of a ring under an injection is a ring (imasmndf1 18664 analog). (Contributed by AV, 27-Feb-2025.)
๐‘ˆ = (๐น โ€œs ๐‘…)    &   ๐‘‰ = (Baseโ€˜๐‘…)    โ‡’   ((๐น:๐‘‰โ€“1-1โ†’๐ต โˆง ๐‘… โˆˆ Ring) โ†’ ๐‘ˆ โˆˆ Ring)
 
Theoremxpsringd 20145 A product of two rings is a ring (xpsmnd 18665 analog). (Contributed by AV, 28-Feb-2025.)
๐‘Œ = (๐‘† ร—s ๐‘…)    &   (๐œ‘ โ†’ ๐‘† โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    โ‡’   (๐œ‘ โ†’ ๐‘Œ โˆˆ Ring)
 
Theoremxpsring1d 20146 The multiplicative identity element of a binary product of rings. (Contributed by AV, 16-Mar-2025.)
๐‘Œ = (๐‘† ร—s ๐‘…)    &   (๐œ‘ โ†’ ๐‘† โˆˆ Ring)    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    โ‡’   (๐œ‘ โ†’ (1rโ€˜๐‘Œ) = โŸจ(1rโ€˜๐‘†), (1rโ€˜๐‘…)โŸฉ)
 
Theoremqusring2 20147* The quotient structure of a ring is a ring. (Contributed by Mario Carneiro, 14-Jun-2015.)
(๐œ‘ โ†’ ๐‘ˆ = (๐‘… /s โˆผ ))    &   (๐œ‘ โ†’ ๐‘‰ = (Baseโ€˜๐‘…))    &    + = (+gโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &   (๐œ‘ โ†’ โˆผ Er ๐‘‰)    &   (๐œ‘ โ†’ ((๐‘Ž โˆผ ๐‘ โˆง ๐‘ โˆผ ๐‘ž) โ†’ (๐‘Ž + ๐‘) โˆผ (๐‘ + ๐‘ž)))    &   (๐œ‘ โ†’ ((๐‘Ž โˆผ ๐‘ โˆง ๐‘ โˆผ ๐‘ž) โ†’ (๐‘Ž ยท ๐‘) โˆผ (๐‘ ยท ๐‘ž)))    &   (๐œ‘ โ†’ ๐‘… โˆˆ Ring)    โ‡’   (๐œ‘ โ†’ (๐‘ˆ โˆˆ Ring โˆง [ 1 ] โˆผ = (1rโ€˜๐‘ˆ)))
 
Theoremcrngbinom 20148* The binomial theorem for commutative rings (special case of csrgbinom 20055): (๐ด + ๐ต)โ†‘๐‘ is the sum from ๐‘˜ = 0 to ๐‘ of (๐‘C๐‘˜) ยท ((๐ดโ†‘๐‘˜) ยท (๐ตโ†‘(๐‘ โˆ’ ๐‘˜)). (Contributed by AV, 24-Aug-2019.)
๐‘† = (Baseโ€˜๐‘…)    &    ร— = (.rโ€˜๐‘…)    &    ยท = (.gโ€˜๐‘…)    &    + = (+gโ€˜๐‘…)    &   ๐บ = (mulGrpโ€˜๐‘…)    &    โ†‘ = (.gโ€˜๐บ)    โ‡’   (((๐‘… โˆˆ CRing โˆง ๐‘ โˆˆ โ„•0) โˆง (๐ด โˆˆ ๐‘† โˆง ๐ต โˆˆ ๐‘†)) โ†’ (๐‘ โ†‘ (๐ด + ๐ต)) = (๐‘… ฮฃg (๐‘˜ โˆˆ (0...๐‘) โ†ฆ ((๐‘C๐‘˜) ยท (((๐‘ โˆ’ ๐‘˜) โ†‘ ๐ด) ร— (๐‘˜ โ†‘ ๐ต))))))
 
10.3.5  Opposite ring
 
Syntaxcoppr 20149 The opposite ring operation.
class oppr
 
Definitiondf-oppr 20150 Define an opposite ring, which is the same as the original ring but with multiplication written the other way around. (Contributed by Mario Carneiro, 1-Dec-2014.)
oppr = (๐‘“ โˆˆ V โ†ฆ (๐‘“ sSet โŸจ(.rโ€˜ndx), tpos (.rโ€˜๐‘“)โŸฉ))
 
Theoremopprval 20151 Value of the opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘‚ = (opprโ€˜๐‘…)    โ‡’   ๐‘‚ = (๐‘… sSet โŸจ(.rโ€˜ndx), tpos ยท โŸฉ)
 
Theoremopprmulfval 20152 Value of the multiplication operation of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘‚ = (opprโ€˜๐‘…)    &    โˆ™ = (.rโ€˜๐‘‚)    โ‡’    โˆ™ = tpos ยท
 
Theoremopprmul 20153 Value of the multiplication operation of an opposite ring. Hypotheses eliminated by a suggestion of Stefan O'Rear, 30-Aug-2015. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by Mario Carneiro, 30-Aug-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘‚ = (opprโ€˜๐‘…)    &    โˆ™ = (.rโ€˜๐‘‚)    โ‡’   (๐‘‹ โˆ™ ๐‘Œ) = (๐‘Œ ยท ๐‘‹)
 
Theoremcrngoppr 20154 In a commutative ring, the opposite ring is equivalent to the original ring (for theorems like unitpropd 20231). (Contributed by Mario Carneiro, 14-Jun-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐‘‚ = (opprโ€˜๐‘…)    &    โˆ™ = (.rโ€˜๐‘‚)    โ‡’   ((๐‘… โˆˆ CRing โˆง ๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต) โ†’ (๐‘‹ ยท ๐‘Œ) = (๐‘‹ โˆ™ ๐‘Œ))
 
Theoremopprlem 20155 Lemma for opprbas 20157 and oppradd 20159. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by AV, 6-Nov-2024.)
๐‘‚ = (opprโ€˜๐‘…)    &   ๐ธ = Slot (๐ธโ€˜ndx)    &   (๐ธโ€˜ndx) โ‰  (.rโ€˜ndx)    โ‡’   (๐ธโ€˜๐‘…) = (๐ธโ€˜๐‘‚)
 
TheoremopprlemOLD 20156 Obsolete version of opprlem 20155 as of 6-Nov-2024. Lemma for opprbas 20157 and oppradd 20159. (Contributed by Mario Carneiro, 1-Dec-2014.) (New usage is discouraged.) (Proof modification is discouraged.)
๐‘‚ = (opprโ€˜๐‘…)    &   ๐ธ = Slot ๐‘    &   ๐‘ โˆˆ โ„•    &   ๐‘ < 3    โ‡’   (๐ธโ€˜๐‘…) = (๐ธโ€˜๐‘‚)
 
Theoremopprbas 20157 Base set of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.) (Proof shortened by AV, 6-Nov-2024.)
๐‘‚ = (opprโ€˜๐‘…)    &   ๐ต = (Baseโ€˜๐‘…)    โ‡’   ๐ต = (Baseโ€˜๐‘‚)
 
TheoremopprbasOLD 20158 Obsolete proof of opprbas 20157 as of 6-Nov-2024. Base set of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.) (New usage is discouraged.) (Proof modification is discouraged.)
๐‘‚ = (opprโ€˜๐‘…)    &   ๐ต = (Baseโ€˜๐‘…)    โ‡’   ๐ต = (Baseโ€˜๐‘‚)
 
Theoremoppradd 20159 Addition operation of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.) (Proof shortened by AV, 6-Nov-2024.)
๐‘‚ = (opprโ€˜๐‘…)    &    + = (+gโ€˜๐‘…)    โ‡’    + = (+gโ€˜๐‘‚)
 
TheoremoppraddOLD 20160 Obsolete proof of opprbas 20157 as of 6-Nov-2024. Addition operation of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.) (New usage is discouraged.) (Proof modification is discouraged.)
๐‘‚ = (opprโ€˜๐‘…)    &    + = (+gโ€˜๐‘…)    โ‡’    + = (+gโ€˜๐‘‚)
 
Theoremopprring 20161 An opposite ring is a ring. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by Mario Carneiro, 30-Aug-2015.)
๐‘‚ = (opprโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ Ring โ†’ ๐‘‚ โˆˆ Ring)
 
Theoremopprringb 20162 Bidirectional form of opprring 20161. (Contributed by Mario Carneiro, 6-Dec-2014.)
๐‘‚ = (opprโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ Ring โ†” ๐‘‚ โˆˆ Ring)
 
Theoremoppr0 20163 Additive identity of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐‘‚ = (opprโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’    0 = (0gโ€˜๐‘‚)
 
Theoremoppr1 20164 Multiplicative identity of an opposite ring. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐‘‚ = (opprโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    โ‡’    1 = (1rโ€˜๐‘‚)
 
Theoremopprneg 20165 The negative function in an opposite ring. (Contributed by Mario Carneiro, 5-Dec-2014.) (Revised by Mario Carneiro, 2-Oct-2015.)
๐‘‚ = (opprโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    โ‡’   ๐‘ = (invgโ€˜๐‘‚)
 
Theoremopprsubg 20166 Being a subgroup is a symmetric property. (Contributed by Mario Carneiro, 6-Dec-2014.)
๐‘‚ = (opprโ€˜๐‘…)    โ‡’   (SubGrpโ€˜๐‘…) = (SubGrpโ€˜๐‘‚)
 
Theoremmulgass3 20167 An associative property between group multiple and ring multiplication. (Contributed by Mario Carneiro, 14-Jun-2015.)
๐ต = (Baseโ€˜๐‘…)    &    ยท = (.gโ€˜๐‘…)    &    ร— = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง (๐‘ โˆˆ โ„ค โˆง ๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต)) โ†’ (๐‘‹ ร— (๐‘ ยท ๐‘Œ)) = (๐‘ ยท (๐‘‹ ร— ๐‘Œ)))
 
10.3.6  Divisibility
 
Syntaxcdsr 20168 Ring divisibility relation.
class โˆฅr
 
Syntaxcui 20169 Units in a ring.
class Unit
 
Syntaxcir 20170 Ring irreducibles.
class Irred
 
Definitiondf-dvdsr 20171* Define the (right) divisibility relation in a ring. Access to the left divisibility relation is available through (โˆฅrโ€˜(opprโ€˜๐‘…)). (Contributed by Mario Carneiro, 1-Dec-2014.)
โˆฅr = (๐‘ค โˆˆ V โ†ฆ {โŸจ๐‘ฅ, ๐‘ฆโŸฉ โˆฃ (๐‘ฅ โˆˆ (Baseโ€˜๐‘ค) โˆง โˆƒ๐‘ง โˆˆ (Baseโ€˜๐‘ค)(๐‘ง(.rโ€˜๐‘ค)๐‘ฅ) = ๐‘ฆ)})
 
Definitiondf-unit 20172 Define the set of units in a ring, that is, all elements with a left and right multiplicative inverse. (Contributed by Mario Carneiro, 1-Dec-2014.)
Unit = (๐‘ค โˆˆ V โ†ฆ (โ—ก((โˆฅrโ€˜๐‘ค) โˆฉ (โˆฅrโ€˜(opprโ€˜๐‘ค))) โ€œ {(1rโ€˜๐‘ค)}))
 
Definitiondf-irred 20173* Define the set of irreducible elements in a ring. (Contributed by Mario Carneiro, 4-Dec-2014.)
Irred = (๐‘ค โˆˆ V โ†ฆ โฆ‹((Baseโ€˜๐‘ค) โˆ– (Unitโ€˜๐‘ค)) / ๐‘โฆŒ{๐‘ง โˆˆ ๐‘ โˆฃ โˆ€๐‘ฅ โˆˆ ๐‘ โˆ€๐‘ฆ โˆˆ ๐‘ (๐‘ฅ(.rโ€˜๐‘ค)๐‘ฆ) โ‰  ๐‘ง})
 
Theoremreldvdsr 20174 The divides relation is a relation. (Contributed by Mario Carneiro, 1-Dec-2014.)
โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   Rel โˆฅ
 
Theoremdvdsrval 20175* Value of the divides relation. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by Mario Carneiro, 6-Jan-2015.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’    โˆฅ = {โŸจ๐‘ฅ, ๐‘ฆโŸฉ โˆฃ (๐‘ฅ โˆˆ ๐ต โˆง โˆƒ๐‘ง โˆˆ ๐ต (๐‘ง ยท ๐‘ฅ) = ๐‘ฆ)}
 
Theoremdvdsr 20176* Value of the divides relation. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   (๐‘‹ โˆฅ ๐‘Œ โ†” (๐‘‹ โˆˆ ๐ต โˆง โˆƒ๐‘ง โˆˆ ๐ต (๐‘ง ยท ๐‘‹) = ๐‘Œ))
 
Theoremdvdsr2 20177* Value of the divides relation. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   (๐‘‹ โˆˆ ๐ต โ†’ (๐‘‹ โˆฅ ๐‘Œ โ†” โˆƒ๐‘ง โˆˆ ๐ต (๐‘ง ยท ๐‘‹) = ๐‘Œ))
 
Theoremdvdsrmul 20178 A left-multiple of ๐‘‹ is divisible by ๐‘‹. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   ((๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต) โ†’ ๐‘‹ โˆฅ (๐‘Œ ยท ๐‘‹))
 
Theoremdvdsrcl 20179 Closure of a dividing element. (Contributed by Mario Carneiro, 5-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   (๐‘‹ โˆฅ ๐‘Œ โ†’ ๐‘‹ โˆˆ ๐ต)
 
Theoremdvdsrcl2 20180 Closure of a dividing element. (Contributed by Mario Carneiro, 5-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆฅ ๐‘Œ) โ†’ ๐‘Œ โˆˆ ๐ต)
 
Theoremdvdsrid 20181 An element in a (unital) ring divides itself. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by Mario Carneiro, 30-Apr-2015.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ ๐‘‹ โˆฅ ๐‘‹)
 
Theoremdvdsrtr 20182 Divisibility is transitive. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘Œ โˆฅ ๐‘ โˆง ๐‘ โˆฅ ๐‘‹) โ†’ ๐‘Œ โˆฅ ๐‘‹)
 
Theoremdvdsrmul1 20183 The divisibility relation is preserved under right-multiplication. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘ โˆˆ ๐ต โˆง ๐‘‹ โˆฅ ๐‘Œ) โ†’ (๐‘‹ ยท ๐‘) โˆฅ (๐‘Œ ยท ๐‘))
 
Theoremdvdsrneg 20184 An element divides its negative. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &   ๐‘ = (invgโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ ๐‘‹ โˆฅ (๐‘โ€˜๐‘‹))
 
Theoremdvdsr01 20185 In a ring, zero is divisible by all elements. ("Zero divisor" as a term has a somewhat different meaning, see df-rlreg 20899.) (Contributed by Stefan O'Rear, 29-Mar-2015.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ ๐‘‹ โˆฅ 0 )
 
Theoremdvdsr02 20186 Only zero is divisible by zero. (Contributed by Stefan O'Rear, 29-Mar-2015.)
๐ต = (Baseโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &    0 = (0gโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐ต) โ†’ ( 0 โˆฅ ๐‘‹ โ†” ๐‘‹ = 0 ))
 
Theoremisunit 20187 Property of being a unit of a ring. A unit is an element that left- and right-divides one. (Contributed by Mario Carneiro, 1-Dec-2014.) (Revised by Mario Carneiro, 8-Dec-2015.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    &   ๐‘† = (opprโ€˜๐‘…)    &   ๐ธ = (โˆฅrโ€˜๐‘†)    โ‡’   (๐‘‹ โˆˆ ๐‘ˆ โ†” (๐‘‹ โˆฅ 1 โˆง ๐‘‹๐ธ 1 ))
 
Theorem1unit 20188 The multiplicative identity is a unit. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ Ring โ†’ 1 โˆˆ ๐‘ˆ)
 
Theoremunitcl 20189 A unit is an element of the base set. (Contributed by Mario Carneiro, 1-Dec-2014.)
๐ต = (Baseโ€˜๐‘…)    &   ๐‘ˆ = (Unitโ€˜๐‘…)    โ‡’   (๐‘‹ โˆˆ ๐‘ˆ โ†’ ๐‘‹ โˆˆ ๐ต)
 
Theoremunitss 20190 The set of units is contained in the base set. (Contributed by Mario Carneiro, 5-Oct-2015.)
๐ต = (Baseโ€˜๐‘…)    &   ๐‘ˆ = (Unitโ€˜๐‘…)    โ‡’   ๐‘ˆ โŠ† ๐ต
 
Theoremopprunit 20191 Being a unit is a symmetric property, so it transfers to the opposite ring. (Contributed by Mario Carneiro, 4-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐‘† = (opprโ€˜๐‘…)    โ‡’   ๐‘ˆ = (Unitโ€˜๐‘†)
 
Theoremcrngunit 20192 Property of being a unit in a commutative ring. (Contributed by Mario Carneiro, 18-Apr-2016.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    1 = (1rโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ CRing โ†’ (๐‘‹ โˆˆ ๐‘ˆ โ†” ๐‘‹ โˆฅ 1 ))
 
Theoremdvdsunit 20193 A divisor of a unit is a unit. (Contributed by Mario Carneiro, 18-Apr-2016.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    โˆฅ = (โˆฅrโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ CRing โˆง ๐‘Œ โˆฅ ๐‘‹ โˆง ๐‘‹ โˆˆ ๐‘ˆ) โ†’ ๐‘Œ โˆˆ ๐‘ˆ)
 
Theoremunitmulcl 20194 The product of units is a unit. (Contributed by Mario Carneiro, 2-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ Ring โˆง ๐‘‹ โˆˆ ๐‘ˆ โˆง ๐‘Œ โˆˆ ๐‘ˆ) โ†’ (๐‘‹ ยท ๐‘Œ) โˆˆ ๐‘ˆ)
 
Theoremunitmulclb 20195 Reversal of unitmulcl 20194 in a commutative ring. (Contributed by Mario Carneiro, 18-Apr-2016.)
๐‘ˆ = (Unitโ€˜๐‘…)    &    ยท = (.rโ€˜๐‘…)    &   ๐ต = (Baseโ€˜๐‘…)    โ‡’   ((๐‘… โˆˆ CRing โˆง ๐‘‹ โˆˆ ๐ต โˆง ๐‘Œ โˆˆ ๐ต) โ†’ ((๐‘‹ ยท ๐‘Œ) โˆˆ ๐‘ˆ โ†” (๐‘‹ โˆˆ ๐‘ˆ โˆง ๐‘Œ โˆˆ ๐‘ˆ)))
 
Theoremunitgrpbas 20196 The base set of the group of units. (Contributed by Mario Carneiro, 25-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐บ = ((mulGrpโ€˜๐‘…) โ†พs ๐‘ˆ)    โ‡’   ๐‘ˆ = (Baseโ€˜๐บ)
 
Theoremunitgrp 20197 The group of units is a group under multiplication. (Contributed by Mario Carneiro, 2-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐บ = ((mulGrpโ€˜๐‘…) โ†พs ๐‘ˆ)    โ‡’   (๐‘… โˆˆ Ring โ†’ ๐บ โˆˆ Grp)
 
Theoremunitabl 20198 The group of units of a commutative ring is abelian. (Contributed by Mario Carneiro, 19-Apr-2016.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐บ = ((mulGrpโ€˜๐‘…) โ†พs ๐‘ˆ)    โ‡’   (๐‘… โˆˆ CRing โ†’ ๐บ โˆˆ Abel)
 
Theoremunitgrpid 20199 The identity of the group of units of a ring is the ring unity. (Contributed by Mario Carneiro, 2-Dec-2014.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐บ = ((mulGrpโ€˜๐‘…) โ†พs ๐‘ˆ)    &    1 = (1rโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ Ring โ†’ 1 = (0gโ€˜๐บ))
 
Theoremunitsubm 20200 The group of units is a submonoid of the multiplicative monoid of the ring. (Contributed by Mario Carneiro, 18-Jun-2015.)
๐‘ˆ = (Unitโ€˜๐‘…)    &   ๐‘€ = (mulGrpโ€˜๐‘…)    โ‡’   (๐‘… โˆˆ Ring โ†’ ๐‘ˆ โˆˆ (SubMndโ€˜๐‘€))
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