Abstract:
An exciter ( 10 ) is located along an information stream path of a transmission system ( 12 ). The exciter ( 10 ) supplies an information signal as a drive to an amplifying arrangement ( 14 ). A coder ( 28 ), programmable to be operative in any of several I/O formats, outputs the information signal that conveys data in a desired code arrangement. A filter ( 30 ), programmable to be operative in any of several I/O formats, confines the information signal energy to a predetermined channel bandwidth. A modulator ( 32 ), programmable to be operative in any of several I/O formats, modulating the information signal. A corrector/equalizer ( 34 ), programmable to be operative in any of several I/O formats, pre-corrects the modulated signal for errors induced in the transmission system. A controller ( 38 ) provides program control of the coder ( 28 ), the filter ( 30 ), the modulator ( 32 ), and the corrector/equalizer ( 34 ). Thus, the exciter ( 10 ) is configurable to handle several formats, such as MPEG2, DVIDEO, and AES3.

Description:
TECHNICAL FIELD 
     The present invention relates to communication systems, and is particularly directed to an exciter useable for a plurality of communication formats. 
     BACKGROUND OF THE INVENTION 
     With the advent of digital television (“DTV”) broadcasting, it is apparent that there will be at least two format standards utilized. Within the United States, the Federal Communication Commission (“FCC”) has adopted an eight vestigial sideband (“8VSB”) format. Elsewhere within the world, a coded orthogonal frequency division and multiplexing (“COFDM”) format has been adopted. 
     Also, current analog television systems exist under either the National Television System Committee (“NTSC”, U.S. and Japan) format or the Phase Alternation by Line (“PAL”, elsewhere) format. Further, various other transmission formats exist. 
     Examples of such transmission formats include Frequency Modulation (“FM”), Amplitude Modulation (“AM”), Digital Audio Broadcast (“DAB”), Quadrature Amplitude Modulation (“QAM”), Code Division Multiple Access (“CDMA”), and Time Division Multiple Access (“TDMA”). 
     Each of these different types of transmission use various types of modulation, occupy different bandwidths, and/or operate on different frequencies (channels). Digital systems that would be used within each of these types of transmission systems differ in their implementation details. For example, a comparison of the 8VSB and COFDM digital television formats indicate that there are differences relating to data rates, parity bits, block size and other parameters. 
     However, despite the differences, transmission systems of the various formats have certain characteristics that are common. From the standpoint of a manufacturer of broadcast transmission equipment, it would be beneficial to capitalize on the common aspects of the various types of transmission formats. This would allow a manufacturer to capitalize on economies of scale regarding manufacture of various transmission format systems. 
     SUMMARY OF THE INVENTION 
     In accordance with one aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Coder means outputs the information signal that conveys data and a desired code arrangement. Filter means restricts the energy of the signal to a predetermined channel bandwidth. Modulator means modulates the baseband information signal. Corrector/equalizer means pre-corrects the modulated signal for errors induced in the transmission system. At least two of the coder means, the filter means, the modulator means, and the corrector/equalizer means are programmable to be operative in any of several I/O formats. Controller means provides program control of at least two of the coder means, the filter means, the modulator means, and the corrector/equalizer means. 
     In accordance with another aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Filter means, programmable to be operative in any of several I/O formats, confines the signal energy to a predetermined channel bandwidth. Modulator means, programmable to be operative in any of several I/O formats, modulates the baseband signal. Corrector/equalizer means, programmable to be operative in any of several I/O formats, pre-corrects the modulated signal for errors induced in the transmission system. Controller means provides program control of the filter means, the modulator means, and the corrector/equalizer means. 
     In accordance with another aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Coder means, programmable to be operative in any of several I/O formats, outputs the information signal that conveys data and a desired code arrangement. Modulator means, programmable to be operative in any of several I/O formats, modulates the baseband signal. Corrector/equalizer means, programmable to be operative in any of several I/O formats, pre-corrects the modulated signal for errors induced in the transmission system. Controller means provides program control of the coder means, the modulator means, and the corrector/equalizer means. 
     In accordance with yet another aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Coder means, programmable to be operative in any of several I/O formats, outputs the information signal that conveys data and a desired code arrangement. Filter means, programmable to be operative in any of several I/O formats, confines the signal energy to a predetermined channel bandwidth. Corrector/equalizer means, programmable to be operative in any of several I/O formats, pre-corrects the modulated signal for errors induced in the transmission system. Controller means provides program control of the coder means, the filter means, and the corrector/equalizer means. 
     In accordance with still another aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Coder means, programmable to be operative in any of several I/O formats, outputs the information signal that conveys data and a desired code arrangement. Filter means, programmable to be operative in any of several I/O formats, confines the signal energy to a predetermined channel bandwidth. Modulator means, programmable to be operative in any of several I/O formats, modulates the baseband signal. Controller means provides program control of the coder means, the filter means, and the modulator means. 
     In accordance with still another aspect, the present invention provides an exciter, located along an information stream path of a transmission system, for supplying an information signal as a drive to an amplifying arrangement. Coder means, programmable to be operative in any of several I/O formats, outputs the information signal that conveys data and a desired code arrangement. Filter means, programmable to be operative in any of several I/O formats, confines the signal energy to a predetermined channel bandwidth. Modulator means, programmable to be operative in any of several I/O formats, modulates the baseband signal. Corrector/equalizer means, programmable to be operative in any of several I/O formats, pre-corrects the modulated signal for errors induced in the transmission system. Controller means provides program control of the coder means, the filter means, the modulator means, and the corrector/equalizer means. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The foregoing and other features of the present invention will become apparent to those skilled in the art to which the present invention relates upon reading the following description with reference to the accompanying drawings, wherein: 
     FIG. 1 is a schematic illustration of a first embodiment of a system having an exciter in accordance with the present invention; 
     FIG. 2 is a chart illustrating several example types of transmission format with associated programming specifics; and 
     FIG. 3 is a schematic illustration of a second embodiment in accordance with the present invention. 
    
    
     DESCRIPTION OF PREFERRED EMBODIMENTS 
     One representation of an exciter  10  in accordance with the present invention is schematically shown in FIG. 1 within a broadcast transmission system  12 . The system  12  includes a power amplifier arrangement  14  and a broadcast transmission antenna  16 . The power amplifier  14  amplifies an analog input  18  and outputs a stimulus signal  20  to the antenna  16 , such that the antenna broadcasts a signal  22  having the desired strength characteristics. Located upstream of the power amplifier  14  is a digital-to-analog (“D/A”) converter  24 . The exciter  10  is located upstream of the D/A converter  24  and operates in the digital domain. 
     The exciter  10  includes a coder component  28  for processing data. The processing may include randomizing, interleaving, block coding (e.g., Reed Solomon encoding), and convolutional coding (e.g., Trellis encoding). Also, the processing may include symbol formatting, or other types of data encoding. 
     Located downstream of the coder  28  is a filter component  30  that confines the signal energy to a predetermined channel bandwidth. The filtering may include low-pass filtering, bandpass filtering, vestigial sideband filtering, and may be performed in the time domain or in the frequency domain. If frequency domain processing is used, a discrete Fourier transform is required. 
     A modulator component  32 , located downstream of the filter  30 , modulates the information signal onto a carrier frequency. This may include complex up-conversion or other processing (e.g., Fast Fourier Transform). 
     A corrector/equalizer component  34  is located downstream of the modulator  32  and upstream of the D/A converter  24 . The corrector/equalizer  34  compensates for distortion of the information signal that occurs elsewhere in the system  12 . For example the power amplifier  14  can distort the information signal. The compensation that occurs within the corrector/equalizer  34  may include correction of non-linear distortion, or equalization of linear distortion. 
     Each of the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34  is comprised of a Digital Signal Processor (“DSP”) component or a programmable logic device(“PLD”, e.g., FPGA or EPLD) that is programmed to accomplish the associated function. Programming for each of the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34  is provided from a controller  38 . Specifically, the controller  38  accesses  40  a memory  42  to receive stored program information. The controller  38  is operatively connected  46 - 52  to the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34 , respectively, to provide program information to these four components. 
     It is to be appreciated that the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34  each have a certain degree of generic attributes. Specifically, the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34  are not predisposed (e.g., configured) or “ear-marked” for a particular transmission (broadcast) format. The transmission format that is utilized within the four components of the exciter  10  is dependent upon the format for which the system  12  that includes the exciter will be utilized. 
     A plurality of input/output (I/O) boards  56 - 62  is connected to provide respective inputs  64 - 70  into the coder  28 . I/O boards within the disclosed embodiment are hardwire boards that are provided for a DTV MPEG2 format, a DVIDEO format, a DVD MPEG2 format, an AES3 format. It is to be appreciated that different and/or additional I/O boards may be provided for different formats. Thus, it is to appreciated that the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34  are programmable by the controller  38  to process the information signal coming from any of the several different format inputs. The programming is initiated via a select input  74  provided by an operator (not shown) of the system  12 . 
     FIG. 2 is a chart illustrating example types of transmission systems and the associated different programming characteristics. For example, within a DTV transmission system, the I/O format is typically MPEG2. MPEG2 (Motion Picture Experts Group) is a variant of the MPEG video and audio compression algorithm and file format, optimized for broadcast quality video. MPEG-2 was designed to transmit interlaced images at 4 Mbps or higher for use in broadcast digital TV and DVD. MPEG-2 has been approved as International Standard IS-13818. Within the configurable exciter  10 , the coder  28  is programmed for transport/transmission formatting, the filter  30  is programmed to perform a Nyquist filter function (e.g., a root-raised-cosine function). The modulator  32  is programmed to provide complex up-conversion, and the corrector/equalizer  34  is programmed to provide linear and non-linear correction. 
     To provide a transmission system for NTSC, the I/O format is DVIDEO. DVIDEO is simply the digital incarnation of the NTSC (National Television Systems Committee) format for video broadcast. In the NTSC format, a signal carries a 3.58 MHz signal with a phase that varies with the instantaneous hue of the transmitted color and an amplitude varying with the instantaneous saturation of the color. A signal in this format carries a 3.58 MHz signal with a phase that varies with the instantaneous hue of the transmitted color and an amplitude varying with the instantaneous saturation of the color. Within the configurable exciter  10 , the coder  28  is programmed to provide NTSC/PAL video formatting. The filter  30  is programmed to provide Vestigial Sideband Filtering (VSBF). The modulator  32  is programmed to provide complex up-conversion, and the corrector/equalizer  34  is programmed to provide linear and non-linear correction. 
     To provide a transmission system for COFDM, the I/O format is MPEG2. The coder  28  is programmed to provide transport/transmission formatting. The filter  30  is programmed to provide a filtering function based upon the Fast Fourier Transformation that is programmed to occur within the modulator  32 . The corrector/equalizer  34  is programmed to provide linear and non-linear correction, but within the frequency domain. 
     To provide a transmission system for FM, the I/O format is digital audio in the AES3 standard format. The AES3 (Audio Engineering Society) format is a well-accepted standard for the transmission of two channels of linearly represented digital audio data over a distance of 100 m in a professional audio environment. Equipment such as recorders, mixers, and signal processors in many installations worldwide conform to the AES3 standard. The coder  28  is programmed to perform a stereo generator function with FM stereo output. The filter  30  is programmed to provide a low-pass filtering. The modulator  32  is programmed for direct digital FM conversion using direct digital synthesis (“DDS”). 
     FIG. 3 illustrates an embodiment that has a modification to permit automatic control. In other words, an operator need not select the type of system that the exciter is programmed to handle. In FIG. 3, the system is designated  12 ′ and the exciter is designated  10 ′ to indicate the modification from the embodiment of FIG.  1 . Components of the embodiment of FIG. 3 that are identical to the corresponding components of the embodiment of FIG. 1 are identified by identical reference numbers. 
     In the embodiment of FIG. 3, an auto-select function portion  78  receives the inputs  64 - 70  from the various I/O boards  56 - 62 . Dependent upon which I/O board (e.g.,  56 ) is actively outputting its signal (e.g.,  64 ), the auto-select function  78  provides a signal  80  to the controller  38 . In response to the signal  80 , the controller  38  accesses the memory  42  and provides programming to the coder  28 , the filter  30 , the modulator  32 , and the corrector/equalizer  34 , similar to the embodiment shown in FIG.  1 . 
     Thus, it should be appreciated that a system in accordance with the present invention has a great deal of flexibility for its application use. The hardware specifics that are provided within a particular embodiment in accordance with the present invention are of course dictated by the various types of formats that are to be accommodated by the system. 
     Specifically, if the system is to be capable of handling DTV format signals, the digital signal processors must have sufficient capability to handle such high speed, high rate signals. For example, processing within a DTV modulator requires thousands of megaflops of processing power. 
     If the system is not intended to handle DTV signals, lesser processing capability would suffice. It should be noted that formats that require lesser processing capability could still be handled within such high-capacity arrangement, albeit it might appear to be “over-kill”. 
     In addition, the input rates could be dictated by the types of format that requires the greatest amount. DTV and COFDM systems require approximately 20 Mb/s input rate. Thus, if the system is to be able to handle DTV and COFDM systems, the input rates of approximately Mb/s would be an upper range. 
     From a manufacturing standpoint, a single fixed platform could be manufactured, and then programmed for the desired application. From a customer&#39;s standpoint, modifications to the system can be accomplished merely upon a change of the programming that would be provided by the controller. Further, it should be appreciated that even within a single type of format (e.g., DTV), changes to the system can be accomplished merely by reprogramming. Thus, the present invention has several advantages over “hardwired” systems. 
     Although the preferred embodiments are described as having exciters with four programmable components, it is to be appreciated that different arrangements are possible. For example, it is contemplated that an exciter in accordance with the present invention would have a different number of components. It is also contemplated that an exciter in accordance with the present invention would have a number of programmable components that is less than the total number of components within the exciter. 
     From the above description of the invention, those skilled in the art will perceive improvements, changes and modifications. Such improvements, changes and modifications within the skill of the art are intended to be covered by the appended claims.