- Home
- Mathematics
- Mathematical Analysis
- The Divergence Theorem and Sets of Finite Perimeter
The Divergence Theorem and Sets of Finite Perimeter
List Price:
$89.99
- Availability: Confirm prior to ordering
- Branding: minimum 50 pieces (add’l costs below)
- Check Freight Rates (branded products only)
Branding Options (v), Availability & Lead Times
- 1-Color Imprint: $2.00 ea.
- Promo-Page Insert: $2.50 ea. (full-color printed, single-sided page)
- Belly-Band Wrap: $2.50 ea. (full-color printed)
- Set-Up Charge: $45 per decoration
- Availability: Product availability changes daily, so please confirm your quantity is available prior to placing an order.
- Branded Products: allow 10 business days from proof approval for production. Branding options may be limited or unavailable based on product design or cover artwork.
- Unbranded Products: allow 3-5 business days for shipping. All Unbranded items receive FREE ground shipping in the US. Inquire for international shipping.
- RETURNS/CANCELLATIONS: All orders, branded or unbranded, are NON-CANCELLABLE and NON-RETURNABLE once a purchase order has been received.
Product Details
Author:
Washek F. Pfeffer
Format:
Paperback
Pages:
259
Publisher:
CRC Press (September 5, 2019)
Language:
English
Audience:
Professional and scholarly
ISBN-13:
9780367381516
Weight:
12.875oz
Dimensions:
6.125" x 9.1875"
File:
TAYLORFRANCIS-TayFran_260411045344499-20260411.xml
Folder:
TAYLORFRANCIS
List Price:
$89.99
Country of Origin:
United States
Case Pack:
20
As low as:
$85.49
Publisher Identifier:
P-CRC
Discount Code:
H
Pub Discount:
30
Imprint:
Chapman and Hall/CRC
Overview
This book presents a detailed development of the divergence theorem. The framework is that of Lebesgue integration—no generalized Riemann integrals of Henstock–Kurzweil variety are involved. The first part of the book establishes the divergence theorem by a combinatorial argument involving dyadic cubes. Only elementary properties of the Lebesgue integral and Hausdorff measures are used. The second part introduces the sets of finite perimeter and the last part proves the general divergence theorem for bounded vector fields.
