Teoremas Relativos a Integral Definida (Parte 2)
Teorema 1: (Teorema do Valor Médio Para Integrais) Se ![[;f;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_s-s5cvJl2XAPFJZBdy-OZLZwEXkO5TuTOI7TkX0uCfAmDZWqCX8zvZRyijit52PsL9nK63UNWU11U=s0-d "f")
é contínua em ![[;[a,b];]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tJJAxTCr1xNJxEr8RwTlmQKvRNh2w--InWcUrpzqm_QptdRdsaingDlH78WM0pwx5E-fXBTploxmNFNX_ra1Eyww=s0-d "[a,b]")
, então existe sobre este segmento um ponto ![[;\xi;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sACR75O81ocoFycGXuZbctCZ7PDs7ohs7-PRvJk-OMm6gCsFPtLbZh-o1e2fCVMNmAGvVGPvwsb-_7wC0=s0-d "\xi")
tal que
![[;\frac{1}{b - a}\int_{a}^{b}f(x)dx = f(\xi);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tZ5EPYfed_gtglKGM66B0VHvOYQ1Fph24SJo_fLB3t6c6ecMDrsjfB8wD3E_0b_y6cFrKq6YTtt6QfzFPDH7eFFuVyunDjWFb5C3JO2ftyT3-rUQrBjn0gYfPSY39mmkB1PbIn3ZNFBSDyVO3LdJOkCykgDqc3MZP9j1iSfyd81IYZOq8cYsxRwA=s0-d "\frac{1}{b - a}\int_{a}^{b}f(x)dx = f(\xi)")
Sendouma função contínua no intervalo fechado e limitado , ela assume o valor mínimo absoluto ![[;m;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sVceF0d8ek74qT96z7l1ds_6_uRKcCGvu9H5THBtah-i5TT1BVucQUlto3nmiDWVqOok4AQMvUSA=s0-d "m")
e o valor máximo absoluto ![[;M;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uqzYrUtjqCkSZ57EkEOV-BaHpLNxx9tBC_mITjfad8kqefCi_VwVz9gaTdurhTO6lYoI19YGvrpLo=s0-d "M")
neste intervalo. Assim, ![[;m \leq f(x) \leq M;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sZXU4YqHhu82HIZiP-WqhPuAbB5Z_P85AnGrjk9s0VRoIOzCfRxRiblTEOu7yMWqpmOluoEWvl5rFlbRIe4ReQpRwP9mUhdyauF9FVkXOn_lKI009wxf8ckhs=s0-d "m \leq f(x) \leq M")
para todo ![[;x \in [a,b];]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uS2vNlTyDLcjN2CcRBxu3iPTp8ubMzKiulj_2PGEqTZYRh1ORjO5fzB10_Z2mCgIuchtrhRT8NEZ5T6U60a4vGGRmXI0nyQTadCvC2=s0-d "x \in [a,b]")
. Integrando esta expressão de ![[;a;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tJzOhPzL7Fnomuxv_rOHTvkDqAJKk130nwPZ9hbF_BXuyItQEofPrEwKXwhQI4you5CdOfAxWvZJ4=s0-d "a")
a ![[;b;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_vIH0ezP7G-ZP-a4pth1IPtQMp4DfEf6nEyt4Isyhh5luHTWIbB-85HIZ6gCqRybhS2BI1HwYmE0Q=s0-d "b")
, temos
![[;\int_{a}^{b}m dx \leq \int_{a}^{b}f(x)dx \leq \int_{a}^{b}Mdx \quad \Rightarrow \quad m(b - a) \leq \int_{a}^{b}f(x)dx \leq M(b - a);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_vgp23iKJ3OJ3cMwAbJduxsIh80TRaPgV3LdQ5Fixs9ZAzEr4SRYjovLv2rK92D0qKkhmSne1TyNiKHS5E5yWbWSb4U5Jgo-KQtO53O1suUPCQ3IxmZZLtuN6npYfBInWIHsrVvz8jMkJdPrVdPt45zoEU5NjYJ1cikIN5BKO_q74rmSdfbJKIz65tYJwZFpNm_AtZs9MyQxUmsSYhM5qtZSkerNlXKyFvdf5aS2tdLSK9xrQ16F5UPPQ3QM_ZHX6L7d1N0jpHPzUBCLRSXg_zha7IUOSqMV1o7wewck7l2CG6KNcAbKJO3l-12d34qX53sxYHIZkT3JEhpaZziJmBo598CdRqSbGt4i_vEguyKd66Vw4BnN7vsmjGD-LcWngBqUE4hgl_cwxqGB-k=s0-d "\int_{a}^{b}m dx \leq \int_{a}^{b}f(x)dx \leq \int_{a}^{b}Mdx \quad \Rightarrow \quad m(b - a) \leq \int_{a}^{b}f(x)dx \leq M(b - a)")
Fazendo
![[;\mu = \frac{1}{b - a}\displaystyle{\int_{a}^{b}}f(x)dx;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_v5r7hbDPr0nBTdFIYH9ReomL6_QTQ_8zcuaibllLDY56j7HfK2MIbaI_IFc8l0VXwV3QGA4YtwHFhS7muDzZ-MCDYyh4F4VVpbcB-1tm2BeivLOMGqC0rCzvqCVHqqBJ1Ypt9enuffcXuOwX5TUbFuW0b9OjNUBGC07Vt6i8R0Lin3aXf6MOftCI3eQnUnX2QzZfcwyKoe=s0-d "\mu = \frac{1}{b - a}\displaystyle{\int_{a}^{b}}f(x)dx")
![[;f(\xi) = \mu = \frac{1}{b - a}\displaystyle{\int_{a}^{b}}f(x)dx;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_smFuY5W3_cCwsYIgDY3U9CzB48eojfgKXP1IuiV1pC7U5_lScM2Q9WNCMVQBOGZQZIsljnRZxVhVxXZPesW4cV0LAIjPgOWks1BWHST7K_lr4xjTu8yEMvKCmiSr6DdhLZHAFv_CkwkqL5qH2UorS9qjjYvdMbP5XN0srUl1Z8L0f4DkxRuKl66jVqzxnuiCoEHNqVXcDnDVnigt0R7_MMxPcpe4S5YiozSIFG=s0-d "f(\xi) = \mu = \frac{1}{b - a}\displaystyle{\int_{a}^{b}}f(x)dx")
![[;A = \displaystyle{\int_{a}^{b}}f(x)dx;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_u-JsGFbh8TGj8k9CqneD9I6FprH0zHntPKU0fS1l1WNrvgt8A8O0u-h1VaDoSF927rUtcgwtg9M_EtH57HayTodjToRYnVKxAJ4gK2vWBZYVepoNoujw1s5-gh6h3g6iXu5XOQVq891lCgwlMhCuk82n4OhkCYpA=s0-d "A = \displaystyle{\int_{a}^{b}}f(x)dx")
Seja![[;A(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_t3lcWEygJClIJd9vPJpwP4kczldvYmRkmydm24w5fXlV7GcF8S2AT9KydgBkJIcSq7clzdlyYpECHRsjStxTHH=s0-d "A(x)")
a área sob o gráfico de de a ![[;x\;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uxj-zhoWctcrg9c845W6Z2puhdSNHDgfGTsGWJ21cIfpE-bXxHdin-lonWgEWyatW5v4iIjtADhvPpjKA=s0-d "x\")
conforme a figura abaixo:
Teorema 2: Seja uma função contínua no intervalo . Então a função
![[;A(x) = \int_{a}^{x}f(t)dt;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sei5SdaKE6q9n5uaIUpZL6aDtZwiZ4o70hlmI0jqk23CHpW1glvKMtiwVmW3NYbnSiRzAFNgewxJqewBFRA0Zux5usrSEs0OumP6xAhdAxkANUcEHynZgffjAgcBAZea2t_e8nXYi7F7s=s0-d "A(x) = \int_{a}^{x}f(t)dt")
é uma anti-derivada ou primitiva de![[;f(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_ucPbu6u-GzD0UdOD8PH87LIBFQ8ulCwb-VJPVDbn1ko29bYMIdDysVQEV5vOruycQfQXV2ZgEpKbcMgNjF7uqj=s0-d "f(x)")
, isto é, ![[;A^{\prime}(x) = f(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sAY57hwWjNpRVUj2B2qWhMs9quC8vyCyH5VIR_epAvIDRXtPeHYCoHTQX-9HkRDcpEyqTmuc1EpXl-9K_JAYHq6tFJANS2UyHfcdgHEkf5a7gH7H7SsC-x2N2eu5xn-xE=s0-d "A^{\prime}(x) = f(x)")
.
Demonstração: Note que
![[;A(x + \Delta x) - A(x) = \int_{a}^{x + \Delta x}f(t)dt - \int_{a}^{x}f(t)dt = \int_{x}^{x + \Delta x}f(t)dt;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_t9En3YXHuJmULZ69EY_Eoh0mqzqQ-V4J5zd8Fphke4LAsTj6qjzw-2lHAFrF7tjcmgHLHpCN7Je0zTGLVvJIr38eYE_F_bTHCTkXV1SFbbv0BC8_Ynoo_B2hnVt_KkDiVoioxYVrSMi7BFS6_ClrehKh-Hd_q_Wk3ZRPSAvgZYIRpaK_6e2Rw0kNxDOhwKM0At24KfBeT26kk2MUVWK1ZmoD6LwL8nSB1ofS9KUayzklqQ0jJbC5RBKU2UTUGQynNmw9PG7GZZ2p4PhczVhVCfBMNXosKJu7IXYs00ixOiD511CBdN7dyE5DRP4BeVQhTUgJ7JfxXLxYPuJjylzUDLm1BZ=s0-d "A(x + \Delta x) - A(x) = \int_{a}^{x + \Delta x}f(t)dt - \int_{a}^{x}f(t)dt = \int_{x}^{x + \Delta x}f(t)dt")
Dividindo esta expressão por![[;\Delta x;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_vc8Z_ixr_tWHos-GNTcD2m2df0UsjYo0c8eHuD9CiAQrUvipwlCqg7k0mkSwld4Z6NvZS_ojWtzl06uyrZy-b0q3hC=s0-d "\Delta x")
, temos:
![[;\frac{A(x + \Delta x) - A(x)}{\Delta x} = \frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt \qquad (1);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sqDkjKT_F2mgZjM3bzk4HgPZV0MrL_8b8IPyB_kxnbgNSQHt8PAq0NyZil30naMWxWqE4T9TG5SbKr65G5fiG3MG1suX6zCOYHW9bFFssPJ7Gv-bKKUxhTI_YUdMwpSFLQ3b_Uq05q1usZirB5QoJe9PoI-er9wa-E_9A0QCVAilhSkhArqBLzA71EMUUtWTpeo7LjX5PrWTSPpGVqQ8eBmcOP7AcpsDMfci4x8VDwJ48BiJ1esiXlP3LwUjo5tZkUqKz6u62ms2VpD2Px_y_qJHBainuvrLUvc3DVuF9pl7oofdE18N8iVCtnQX_GJm9Yn64=s0-d "\frac{A(x + \Delta x) - A(x)}{\Delta x} = \frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt \qquad (1)")
Pelo Teorema do Valor Médio para Integrais, existe![[;\xi \in [x,x + \Delta x];]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uFN_LAYEibRt3_NbielegcDkx_WWrI9Ol0bKHFm91wTIADin_cPtL_a5VFGrDb3rFNS_ZiZJqDHBzCRl_-6T9qwkgA2uKhcu0h95uCJMaCaBLGNKIdQPxk36dv7_0QmIB52ovr=s0-d "\xi \in [x,x + \Delta x]")
tal que
![[;\frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt = f(\xi) \qquad (2);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tHuSctyIYyWUIdIqv2ZRaQAsWXKVoyiOkWatn_GaciGrqdA610edAYI2YYgTCTZzXfy-DDdFZxulrxd4rZSH8jgBvqTMtcl60VecuZNp39QM4V8XkcQUvFbTLMetyhBbwp6mtUR2GMBPdui5KsEEN5OMVnu46tAWYPtdNPTYNIK1VIArxmSwpLsWJDk24sj1U6agoejHDIrp3ma5P4WXOx2edsGGQQ50aXsMTTziBbqOevf72A3Q=s0-d "\frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt = f(\xi) \qquad (2)")
Assim, fazendo![[;\Delta x \to 0;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_u41XQBUz43gvC_cRctvidFMfrvdNBTl9RonuCP2bpvCPudm8e066w9owamkHJyDKYwh-Kgf0rPW-u9CXnvlvisTC35whJUgn4nn4tHBXEN=s0-d "\Delta x \to 0")
em ![[;(1);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_vHhv7h184X_jiKa81WZfj_8Rza4JWWvMtAv_YSS9l_9v0dKiKdyhxPaLaHZR0wOjwKjOBsMWcGtRDLEREekA=s0-d "(1)")
e usando ![[;(2);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uPonQaAzQyus7nukpipFP_-N6mxDRY9NLuijcmxZ4bOvluEIdX1npnJUHXTxjjewRHJhU8Mwvw4RBwvXrtRw=s0-d "(2)")
, segue que
![[;A^{\prime}(x) = \lim_{\Delta x \to 0}\frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt = \lim_{\Delta x \to 0}f(\xi) = f(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tRoAArtb4BWbiSKgzTroeXJSTSMp1Uu1W6pbRaVvVdKqf6bslBaIiZyq3H3yMOukQS_eNviy82-ildt9ShWUIQkw1O7zv-6ukUnNEsOmrNeTJpPK_35iUWoZ-53z5eZ-tklsE8vYHYjia9AUfa5KSogdD2GccMqwvIM4trt7ASNzIMBZarvKHy8QOCAcBeaCHelezL_sd_tWW8LZcWHmqQ4IbmrdcUAReo3nqBhfBbLc0wExaJabYy2klm0ICRC9ehlXGiLNSQJ7iAVIbgpIcuGJZI7QceMDPWxSQZgDHjMpkl6ibqzuxvtu1u0ddCSA_tUEVCLS5Pa3jHyEuI6jIkiQzAorsCvf-nBLn7zZktex0y7jWf6iB0IoA=s0-d "A^{\prime}(x) = \lim_{\Delta x \to 0}\frac{1}{\Delta x}\int_{x}^{x + \Delta x}f(t)dt = \lim_{\Delta x \to 0}f(\xi) = f(x)")
é contínua em , então existe sobre este segmento um ponto tal queSendo
uma função contínua no intervalo fechado e limitado , ela assume o valor mínimo absoluto e o valor máximo absoluto neste intervalo. Assim, para todo . Integrando esta expressão de a , temosFazendo
segue que ![[;m \leq \mu \leq M;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tT_PIimWLYN84D0gPCsKm8ndBjcDGXaagyxIyZpMPFqI0uKEEtjyK1jguMu0_i6w8r8VYlk-fMfKk1A8KHQbcB3PQyxGB0w3aOOWEjDF3qygL2M-e1urg=s0-d "m \leq \mu \leq M")
e sendo contínua em , existe neste intervalo tal que
e sendo contínua em , existe neste intervalo tal que
Lembremos que se uma função é contínua e não-negativa em um intervalo , então a área sob o gráfico de neste intervalo é representado pela integral definida
, então a área sob o gráfico de neste intervalo é representado pela integral definidaSeja
a área sob o gráfico de de a conforme a figura abaixo:
Teorema 2: Seja uma função contínua no intervalo . Então a funçãoé uma anti-derivada ou primitiva de
, isto é, .Demonstração: Note que
Dividindo esta expressão por
, temos:Pelo Teorema do Valor Médio para Integrais, existe
tal queAssim, fazendo
em e usando , segue que
Observação 1: No caso em que a função é não-negativa em , a função representa a área sob o gráfico de e o eixo , e entre as ordenadas ![[;x = a;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_va7oBBsFLrsvSlsis1LYl9jdDvOjUUb-mD3Tb0bDGgtCmRV5mkW9tFyd1FsoB9-LFei1Z7EEfNBblMmXMVaWDl=s0-d "x = a")
e ![[;x = b;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sgsMBSgnEVXGC7DvyQVuFN89JNXkOczD1_dXN6_JrDdFsF8YnMmKn-UmxH3LuNaj4tIk0gUo_CEMNNgoLEX1PJ=s0-d "x = b")
.
é não-negativa em , a função representa a área sob o gráfico de e o eixo , e entre as ordenadas e .
Obrigado por difundir os posts do blog Fatos Matemáticos. Em breve, publicarei a terceira parte.
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