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_tqGrSHu4E0Ij-uYJrm6Z909iu5861BM3Zg02PpXQ0iz4wHd9c5YJ5LAxxkVoiS2AHphOA1dJyEiOg=s0-d "f")
é contínua em ![[;[a,b];]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tH7a1hcMYH6VvmpK8mHUquYjYGVIYQUakVx0HRxo2AZ0-43LHtmTMhmViPrJgi8ArljXQIcJkfkzIWgnm7tGAC7Q=s0-d "[a,b]")
, então existe sobre este segmento um ponto ![[;\xi;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_voKs9z7D2yzfbDVlF3ui-17u0KE2sFSUOXaDr0gISAv8xfrBhCzG9Snu7pTcQ6tAy503RZPLyRSwdqS4Y=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_vE-6eeNZKmlk6c6QV7Fbt6yO-0bG0mbjYWHFYCYoLVWe1NNQR7fvFlm1NGhIwoT3RmqFjYkS0zWN9tsNd6UX5OPlIEvskXJSxZ8-ZORAbb6dKitCRmiXRuuTnZJC7QPWgvpQ-RAk31D9ThTzNGIEhh1cyPp_-QFUGolUYAgnig6wjJOvkvaoh_Qw=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_sUquhGOo9xWFTa-l6hKW0rNuaTr4v-wp__0ZmBcXqJzBpPQDXxecx_RQVDorOuZ0d7t9h8vxK9Ig=s0-d "m")
e o valor máximo absoluto ![[;M;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tF0dAMns9mljMafa34HaXLxVPCY-4Lzd0dDcxkfjxn9y4EAsFP2k2q2Z3vifwnyESlrzLKyvy-2xA=s0-d "M")
neste intervalo. Assim, ![[;m \leq f(x) \leq M;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tXSon6GssXW-qI1byDVL7gsQxyTj0igjFtX5xY_4sQWbulY736Szc9sxAWEd5ZibGOqdVSHjeBba_ThxRo_ZtaWIo2sjdut1wue4yDSMZtT4_wCGvLSUuLY4o=s0-d "m \leq f(x) \leq M")
para todo ![[;x \in [a,b];]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_sEo6Rb_QuiAsacaF6vm45pUNjQDvsEt7m9Uo0whrmNJbJ9Rn5Gqzwc8A_ycUuj_dMYG1B86zEoFPU1O_xW62AhQ-2xNmerxT22PP8C=s0-d "x \in [a,b]")
. Integrando esta expressão de ![[;a;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_vCtjz6zxSESbSzM85WBgs00Vvi9TIKkCFJzoGUAVHirU1K3SKBKi4DQyxK_NwYfQStwl-eCqudFgo=s0-d "a")
a ![[;b;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_v3qkkeNf_nteROjzuw23GBxu6MXO9HrPf2_Z9ZCAGuloLSUBFY1TO9ELpXR0UHMvVPJyCuTo7dag=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_vwYEaRtrZl1zBqOCWySCxy8KuLL0f7jOUmV7xF1vhMmr7HuulNjBf-uzr3A0vKq5zc3HgUrXM5woyZhJLWfXlO4NioTJIKbbJQWNTbG3xAw1bx7B3K3zq9yWnAv4bsepTl2ztVpoHGE1lxMaoLX69cBa-jcnZHn1VSO2MLyn-PIPPX7H0tfwRodxGYMZt8LlZOFT1PsPaMlfBJpAMHxuqAV12tAf1AH9IeSkwIdHCGeshJ5m7DWpia1s1cK8Y7sOpMhjXIOPAJ8l-uo1cJjTWNijEhaCEkrGnEqviTk51oV-P-loUh-ajgBoh0lRW_NkFJoucncftvVWcI109f0KtOQoyTYULdR1sxTamhXyUbAlmN7y1ecDkpm55MTgu4YGQS0a5wGbmxWJMctsc=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_tJdP46GF4QcScPtRri2zgzFcB5lnJDXiJuFtOcOI6f7p8-Asq56bQOQHQc7s9Dv8dpbjzpmGYyjg5Hnr7AxRhh0LZ2sKwXIZDNgYqq9uFODQroqlHGj6ETjxXuJnCMJ9qlAkL1KASqMk62JHqiCSL0yD8d3nafBk_lp-b2N-ZOu5v6tG32702iq9wM8-3w9Phtc9fT8V6u=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_vTxvBVjFsUjQOXgaiBtKKRtmTyhIIiLnsr0zCPcB_oh7ZoWMm2F5Jig4JqnYVGuIsf8Nry4dHpiNIckgF8SHUjpu69zuXB_YrV2lsrTz2nZqHPUQVyyZXoDOGrIEbyUUGmPK62EEQGUhYSU2O9ENHzIjLDC8LSWXgT-i5sfeu-FgTsOd94W88KW1cnput3X77emd38OTxy9lnjEAA2e6KZ26vSth7N9xWQYkk8=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_vtuio2hbKghWvsIi3qgsHZUmueFEXpm9MCoDcnZQ2cvdmLoQTwsKdSrpQMBSgB0oG_etxLXqGi-GrR0adhpEUAmiWeoqKcwl-80fAHVa6o6NGC5nrrjE7hb7VI9KHqLQ-kZNDWig-ksUGODV7_-NKYamYLjugdAg=s0-d "A = \displaystyle{\int_{a}^{b}}f(x)dx")
Seja![[;A(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_snVxqbKtMnTyYwCrSpJn7Aqqr7Q7Pg8-iLU8-Te-8NZq1WQGX4AmrH2VKEPvk8e3EqJEkrfBXyiMYIaKIbg6qr=s0-d "A(x)")
a área sob o gráfico de de a ![[;x\;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tcg5UTwzgy2ukGc4dFyLPGBqro4m3HSE7EIknV0jNxOwFY2s5oPSOdoHAmSMAwaQvPDaib6kClqGeCxKQ=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_sxJW3zgc9jVQj3waRWt6-4DwfHritEe5oO5IPFo2cJQ19V2RDyJHGEDEoCps5pnWU8Z8m97plRYQzZnCeMf38Gw6nwUQqLv04t1F7BtgHjzP4PEfEn_ds1M2aNY4kVHrTs-ShrAFUdgJ0=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_t_Pfdrs_Rdlk6fwc85-5R_wnlfBMbKzmL5-uhJBtreD7qwqQLpBSaBHWFcq8VK7_Tr7XbfdsPhfA0cFiLDqUFG=s0-d "f(x)")
, isto é, ![[;A^{\prime}(x) = f(x);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_tqcb9x897L_85erVearTc8SMGMmNNyqj6zpIMJ8mk4XHvpUDNnzBQp5t4uw6IsmZt4ePtUVPVL2s3hWDboB-upge3SS0md3o0oE9JZY_EHplUX2UNJcEsbtdSWBreDSok=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_vrsYM5tyH4eGYlXaXvr5dFgoLmvJX9UpdJu_RT7OpJ5YcyYZVFlb0Q0JdQ91MNoJjlTrf6YhJGU8Z74k_wEGrAtyK1J0pvg9Uid9Jw_0Jlc2UzHR5OgFRU1i0wTRTk3U7EVymV9ApI_JyC5zt7b2peAbYPOPGsD-VzhO7ZqNKeXqbWQcxCKRiPLf_ATySREtmJ95Vv20G6GYZWNBFKyF0I3VO7TpEEvZEQMvVgb2S3NH5epG_jpX-aWzDi193heo_b_SV9SPOMOpehhuy7oTJWubNecETy44uPpXgJqa3Rw_Pp6TeUQA05CANtmUIQWNUJQxYTcarfaxrZ0WAymHNGnhSS=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_vyPokFHXQJAi8kdV2Lw8wyz9UNzUIOEGSYsGP7xF6ZGPg99iz1fWGZrYo_j686tJTknFQZ1dOEXJZpthsalG4wqEBt=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_tQ3m7yvz5bA8gO6Wt8trltWuoZQDNw0p7lzL2acAlJ0zOfxkFKQuj5SLD8kbsbK9OV1KKqvu2YsUrHPP5ZP0h7pwQ9AlH_6cWyH1TvWM4StHlvddGXHQyxYizzTbvzP7_xGeGhWtBiwUcrZqP6V_0uF7qLh2DHjIDn-oCqHmEbPMwiahEC1dM7yacCwetsDf5DT7BD_rTFu-rJLsnolUH5Zg030G0GeAB6OUEeYDY6Pd8_k99L3qmTibYmRNieCz75EZx-AOwn5shoOt59nMVFE5RwiHfiki9K2T39qTzt81GffwH272weHmYRCQKY69w5Dno=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_tsExhHX9-AOO5euv03uocB669vyMO0upSRIt2Goqpn2jspLXW0fB0ODOoYplFNJAnLaHI1RkLq70icvwETVH-mS1UTwDyfj66_HO2tpP-lHqTcuKLaaAk_9aVN-wLX2SkDnXrs=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_t9odvUAjhDIGQIPIYiYKNIVBzwhFKzmmNUSwEEPI-rNjR_sv5k12HdZzZflCz44NEVHUPad907USgNh2O6kYzgYViLI6202fKJUGdPMElAhl7mvJ8mb5-HRJb5T4cEphBCKlbQwh8iN-8uwnAwsQXKMGfZ1g7UIYaaql9sOQ-nkyFLktLIqTMgwt3a4ZO_vUbb7B4FDOkLjz2e1eLUi2I6H6rk9igSKbXsRC4Vaid0O_DdYYTX5Q=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_vphOLfLXxJT5h4RQrCYcYvelDl7hBTNDnxVVoRjJIVr2WjjjDaN6TVFWsR8qRbiHNsgnigk1RNMAzQ0jmKIi9fdBf8TOrOIXo1K63keevZ=s0-d "\Delta x \to 0")
em ![[;(1);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_t4qB25SMH7mwYId2mfPqOyDMGfXgIZwq2euv4LRCw3FpfFRLAicqIJQdvApITxV4QQxOts_e-Udn3pRwDbYQ=s0-d "(1)")
e usando ![[;(2);]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_uKM1M7JLLyLEDv9JNikzPLt4OBV4uqA-uKAEXIK8kMbBhzzpUcFcW6MDygmIgo9A9bUYxbCE06y--VsHK4Hg=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_t9UUWMkMm-UbxOKXkURA44YLZ_cWoHxxrtAyyzbIlIdzsOLtY69sF7D6ddZhKSidE-D8dLhAQYE5ICtkz_OYLzLT4MtlquXObAcp5aJG3uH9u8xlqpwzJsdApcDtxHycREttd1ct8sIQlnb05OvPZd4JjQuY7BOwecRKbbrIOBaA8RaZeLd5rog5sKHzAtALXeZD78zDLeflsjjPK1TmnwP05GdJ6dA4E6hcHOOh2Egyn4i3RdJwU4ZLYfdW7Ecc02y9nlJMep_hcvRhv0FjsFR2dZkiF19TRapj3Jm9H43mHq7W1VIHS-_5wXBfojHLGaO9S4TFcSHtcWWaZkdxe2rCQrnSnM3uPynKPHniOPy5x1ucAJWGE2VtE=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_vGbaUHLauodSDRKjZDQEvzyh-10coZ4ReTM1bC0zzjYqfURZjH1EcaGrO9MvoeHBBnbqlH7cz6MMx_oeNIS4qnHG7QY8naIe1ENijgqwUuwILaIYQnOkw=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_vC2P8Kceom6DVP5BNWjSFDK0OtNzqNpOpEmSPnKK3hxQpxJ64L0aGAaMAASEnUQjrQClDV8VVjlkWI70AoRnxT=s0-d "x = a")
e ![[;x = b;]](https://lh3.googleusercontent.com/blogger_img_proxy/AEn0k_thBUM8igqx7cbMoODdPkY8tvEpGY2KMT1Fvq9x7n9kBtyEPwbHxNSQQlX2_jXYuOUv9URYUW-U3hblRU8w3kbo=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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