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D a t a Ty p e s , L i t e r a l s , a n d Va r i a b l e s
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V2*(h) = 1 - 1.080760 cos(2ph) + 0.72051 cos(6ph) + 0.006176 cos(10ph) + 0.001470 cos(14ph) + 0.000520 cos(18ph) + 0.000229 cos(22ph) + 0.000116 cos(26ph) + 0.000065 cos(30ph). 13.6.6 Conclusion
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void display(int num[]) { int i; for(i=0; i<10; i++) cout << num[i] << ' '; } qr code reader
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SOLUTION The time constant is found by multiplying the resistance and capacitance together. In this case = (5 )(1/10 F) = 0.5 s
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Here, myfunc( ) is overloaded so that it can take arguments of either type float or type double. In the unambiguous line, myfunc(double) is called because, unless explicitly specified as float, all floating-point constants in C++ are automatically of type double. Hence, that call is unambiguous. However, when myfunc( ) is called using the integer 10, ambiguity is introduced because the compiler has no way of knowing whether it should be converted to a float or to a double. This causes an error message to be displayed, and the program will not compile. As preceding example illustrates, it is not the overloading of myfunc( ) relative to double and float that causes the ambiguity. Rather, it is the specific call to myfunc( ) using an indeterminate type of argument that causes the confusion. Put differently, the error is not caused by the overloading of myfunc( ), but by the specific invocation. Here is another example of ambiguity caused by C++ s automatic type conversions:
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OSPF Con guration
Thevenin s and Norton s Theorems
D.1 INTRODUCTION 561 D.2 COMPUTER SOFTWARE LISTING 561 5, Cam Motion Synthesis Using Spline Functions 561 6, Elements of Cam Pro le Geometry 561 7, Geometry of Planar Cam Pro les 562 12, Cam System Dynamics Analysis 563 13, Cam System Dynamics Response 563 16, Automotive Camshaft Dynamics 563
string FormatNumber(number input_parameter; string number_format)
11 11
RTP over IP
Decode display formats. Protocol decodes typically are displayed in three formats: a summary decode, a detailed decode, and a data decode (Figures 24.6a, 24.6b, and 24.6c). These examples show a frame captured from the World Wide Web. The HTTP protocol is executing over TCP/IP on a 10Base-T network. The summary decode shows a consolidated view of the frame information. The contents of each frame are summarized into one line on the display. This is used to quickly determine the type of traffic being transmitted on the network and to determine the upper-layer protocol conversations that are occurring. The summary decode uses an underline cursor to aid in viewing a specific frame, as well as to indicate the frame that is examined in further detail using a drill-down user interface. In Figure 24.6a, frame number 4624 is underlined. The summary decode gives a reference number for the frame, a timestamp for the specific frame, the source and destination addresses (in this case the MAC addresses), and the description field of the information contained in the frame, including encapsulated protocols, address and control information, and error information. The detailed decode (Figure 24.6b) breaks out all of the protocols in the underlined frame and identifies all of the fields in each protocol. It describes each field in the protocol layer and identifies all parameters with a textual description as well as the actual field values. This decode view is used to troubleshoot specific problems within a protocol or in a transaction between devices on a network.
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