CN101017383A - High speed arbitrary waveform generator based on FPGA - Google Patents
High speed arbitrary waveform generator based on FPGA Download PDFInfo
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Abstract
This invention relates to one high speed random wave generator based on FPGA, which adopts DDS technique with data sample rate more than 1GHz and comprises CPU, parallel data phase generation part, wave shape memory part, plug and filter part, parallel and series conversion circuit and DAC, wherein, the parallel data phase generation adopts parallel process to generate multiple data phase In one time clock to get multiple data; then it uses FPGA series and parallel conversion circuit to output the data to DAC into virtual volume.
Description
Technical field
The present invention relates to a kind of waveform generator, refering in particular to is a kind of high speed arbitrary waveform generator based on FPGA.
Background technology
Use high-speed memory as look-up table based on the AWG (Arbitrary Waveform Generator) of DDS (Direct Digital Synthesis) technology, synthesize the waveform that is stored in the storer by high-speed DAC.So it can not only produce common waveforms such as sine, cosine, square wave, triangular wave and sawtooth wave, but also can utilize various editor's means, produce traditional function generator the random waveform truly that can not produce.
Though it is a variety of that the structure of DDS system has, its basic circuit theory can be represented with Fig. 1.
The DDS technology is to be based upon on the basis of sampling thheorem, it is at first sampled to the waveform that needs produce, and will deposit storer in as look-up table after the sampled value digitizing, and then by tabling look-up data is read, convert analog quantity to through the DAC converter, the waveform that deposits in is synthesized again.
Frequency word among Fig. 1 (FSW-Frequency Setting Word) is actual to be exactly phase increment value (binary coding), as the accumulated value of phase accumulator.Phase accumulator adds up frequency word once when each pulse reference clock input, and its output correspondingly increases the phase increment of a step-length.Because the output of phase accumulator is connected on the address wire of wave memorizer, so the change of its output just is equivalent to table look-up.So just can find the waveform sample value that is stored in the wave memorizer through look-up table.The DAC converter is delivered in the output of wave memorizer, exports after the DAC converter converts analog quantity to.
Under the effect of system clock pulse, phase accumulator ceaselessly adds up, and also promptly ceaselessly tables look-up, and Wave data is delivered to the DAC converter convert analog quantity output to, thereby waveform is synthesized again.Generally also can add analog filter behind DAC, by the analog filter sawtooth staircase waveform of the near sinusoidal ripple of further level and smooth DAC converter output then, unnecessary spurious signal simultaneously decays.
Because the restriction of phase accumulator word length, after phase accumulator was added to certain value, its output will be overflowed, and the address of wave memorizer will circulation primary like this, means that promptly output waveform circulates a week.So changing frequency word is phase increment, just can change overflowing the time of phase accumulator, under the constant condition of clock frequency, just can change output frequency.
Example 1 has been supposed in the wave memorizer stored 1024 Wave datas, and the clock frequency of system is 1.024MHz, and the bit wide N of phase accumulator is 10, and the value D of frequency word (FSW) is 1.Under the effect of time clock, phase accumulator adds up and overflows after 1024 clock period, and promptly through 1024 system clock cycles, output waveform circulates a week, the output frequency of system
Example 2, if the D value is changed into 2, then phase accumulator overflows behind 512 system clock cycles, the output frequency of system just will become
Thus, we can release the output frequency f of DDS system
0With system clock frequency f
sBetween the pass be:
As can be seen from the above equation, in order to improve the output frequency f of system
0Just need to improve system clock frequency f
sAlong with development of science and technology, the frequency of operation of DAC can surpass 1GHz.But the frequency of operation of digital circuit but still can only reach hundreds of MHz, that is to say that the frequency of operation of data phase generative circuit and wave memorizer does not reach the frequency of operation of DAC far away.How for providing data, DAC then to become the key that improves the total system clock frequency faster.
Summary of the invention
The invention provides a kind of high speed arbitrary waveform generator based on FPGA, the whole system operation clock can reach more than the 1GHz.
In order to realize improving the whole system operation frequency, just need to improve the frequency of operation of digital circuit.Utilize FPGA to realize the DDS system of digital circuit for great majority, the frequency of operation of FPGA at most also can only reach hundreds of MHz, and this can not meet the demands well below the frequency of operation of DAC.
Key of the present invention is exactly to adopt distinctive and the line phase generative circuit, can generate the phase place of a plurality of data in a clock period simultaneously, and a plurality of wave memorizers of tabling look-up simultaneously then obtain a plurality of data.In traditional DDS system, the phase bit generating circuit generates first data phase at first clock, generates second data phase place at second clock.And of the present invention and line phase generative circuit not only can generate first data phase in first clock, can also be in advance second, the 3rd even N data phase place be generated simultaneously.The data phase that these generate in a clock simultaneously, N the wave memorizer of tabling look-up simultaneously then can obtain N data simultaneously.Owing to can obtain the data that original N clock obtains in a clock, so the frequency of operation of data phase generative circuit and wave memorizer can be reduced to original N/one, promptly the frequency of operation of FPGA can reduce N doubly.That is to say that by parallel generation data phase under identical FPAG frequency of operation, its data N that provides is its frequency of operation doubly, thereby can satisfy the frequency of operation of DAC.
After obtaining N data simultaneously, utilize the parallel-to-serial converter of FPGA, then N data obtaining serial successively can be outputed to DAC.For instance, if obtain 4 data simultaneously, then parallel-to-serial converter just outputs to DAC with the speed of 4 frequencys multiplication with data serial successively.Because the parallel-to-serial converter of FPGA can be operated in more than the 1GHz now, even higher, so can satisfy the frequency of operation of DAC fully.
And data phase number N and the frequency of operation of FPGA, the frequency of operation of DAC that the line phase generative circuit produces concern as follows:
The frequency of operation of frequency of operation/FPGA of data phase number N=DAC
Wherein the frequency of operation of FPGA is meant the frequency of operation of FPGA inside, the i.e. frequency of operation of parallel data phase bit generating circuit and wave memorizer in the following formula.The frequency of operation of the parallel-to-serial converter of the FPGA then frequency of operation with DAC is consistent.
In sum, utilize of the present invention and the line phase generative circuit, the internal circuit of FPGA is operated in below the 200MHz, in addition lower.Parallel-to-serial converter and the DAC of FPGA then are operated in more than the 1GHz simultaneously.So just DAC and the unmatched problem of FPGA frequency of operation have been solved fully.
The present invention simultaneously also has interpolation circuit, also can further reduce the work clock of FPGA by interpolation.Behind interpolation circuit, the present invention also includes digital filter circuit, by by the relevant coefficient register of CPU configuration, can change the cutoff frequency of filtering circuit flexibly, further improves the purity of frequency spectrum of output signal.
Description of drawings
Fig. 1 is the synoptic diagram of existing DDS signal source structure and output waveform.
Fig. 2 is a structured flowchart of the present invention.
Fig. 3 is the structural representation of parallel data phase bit generating circuit and respective waveforms storer.
Embodiment
The present invention is not limited to following described or illustrated structure and implementation detail, and the present invention can also have other specific embodiment.
Fig. 2 has given out structured flowchart of the present invention, comprises CPU, FPGA and DAC etc.Wherein CPU can be the AT91RM9200 of atmel corp or other.And FPGA can be the FPGA of the stratixII series of altera company, also can be the FPGA of xilinx company, below described EP2S30 with altera company be example.DAC among Fig. 2 can be the high-speed DAC of U.S. letter company, can be the DAC of AD company also, as AD9736.
CPU among Fig. 2 mainly is parameter that is used for disposing frequency word, the data in the wave memorizer and digital filter circuit among the FPGA etc.By revising the frequency word register among the FPGA, system can obtain the output of optional frequency, and by revising the data in the wave memorizer, system then can obtain the output of random waveform.
FPGA among Fig. 2 mainly is made up of five parts such as parallel data phase bit generating circuit, wave memorizer, interpolation circuit, filtering circuit and parallel-to-serial converters.Bing Hang data phase generative circuit how many roads that need walk abreast wherein are by the frequency of operation of DAC and the frequency of operation decision of FPGA.Generally speaking, can be operated in below the 200MHz in order to make FPGA, parallel way N can get 4~8 the tunnel mostly.
Wherein Bing Hang data phase generative circuit structure as shown in Figure 3.The value of first via frequency word register is D, and the value of the second road frequency word register is that 2 times of first via value are 2D, and the value of Third Road frequency word register is that 3 times of the first via are 3D, and then the value of n road frequency word register is that the n of the first via doubly is nD.The output of first via phase bit generating circuit, the value that is phase register is the value of last road phase register and the additive value of first via frequency word register D, the second tunnel phase bit generating circuit is output as the value of last road phase register and the additive value of the second road frequency word register 2D, and the rest may be inferred.In the end one the tunnel, it is output as the accumulated value of this road frequency word register.
Promptly as the address of waveform data memory, when the output of register changed, wave memorizer will be exported corresponding data in the output of the phase register among Fig. 3.
The embedded RAM piece that includes 144 4Kbit in EP2S30 can be combined into it 4~8 wave memorizers fully as required.Then the data of random waveform can be write these wave memorizers by CPU, and then table look-up data are wherein read.
It can be designed to dual port RAM for the wave memorizer among the FPGA.For a wave memorizer, just have the output of two-way address and data like this, thus can be simultaneously with the two paths of data phase register as the address, be connected on same wave memorizer, reduce used RAM piece.
The parallel data that obtains can be admitted to interpolation circuit according to the configuration of CPU by tabling look-up.Then can further reduce the frequency of operation of FPGA by interpolation.Data after the interpolation can be admitted to filtering circuit according to the configuration of CPU, data are carried out filtering, thereby can obtain the higher purity of frequency spectrum.
For interpolation and filtering circuit, can be as required by selector switch with its bypass, thereby directly parallel data is sent to parallel-to-serial converter, with the output of data serial successively, send into DAC by parallel-to-serial converter.
For EP2S30, utilize the ALTLVDS of megafunction function in the QUARTUS design software to generate corresponding parallel-to-serial converter, it can become serial data with 10 channel parallel datas at most exports successively, and maximum frequency of operation then can reach 1.3GHz.
High speed arbitrary waveform generator of the present invention, frequency of operation through its FPGA internal circuit of actual measurement is 150MHz, parallel phase bit generating circuit is parallel 8 the tunnel, and the frequency of operation of DAC is 1.2GHz, thereby and changes by CPU that data can produce random waveform in the wave memorizer.
Claims (4)
1, a kind of high speed arbitrary waveform generator based on FPGA is characterized in that: comprise CPU, parallel data phase generative circuit, parts such as waveform storage area, interpolation and filtering circuit, parallel-to-serial converter and DAC.Bing Hang data phase generative circuit wherein can generate the phase place of a plurality of data simultaneously; By the wave memorizer of tabling look-up, can obtain a plurality of data by a plurality of data phases simultaneously; Interpolation and filtering circuit can carry out interpolation and digital filtering to the data of output; Parallel-to-serial converter can output to DAC successively with a plurality of data serials that walk abreast; DAC then becomes simulating signal with transformation of data.
2, the high speed arbitrary waveform generator based on FPGA according to claim 1 is characterized in that the data phase generative circuit that walks abreast; Described and line phase generative circuit includes multichannel phase bit generating circuit, and every road phase bit generating circuit comprises a totalizer and a frequency word register.Wherein the value of first via frequency word register is D, and the value of the second road frequency word register is 2D, and the value of Third Road frequency word register is 3D, and then the value of n road frequency word register is nD.First via phase bit generating circuit is output as the additive value of last road phase place and first via frequency word register D, and the second the tunnel is output as the additive value of last road phase place and the second road frequency word register 2D, and the rest may be inferred.In the end one the tunnel, it is output as the accumulated value of this road frequency word register.
3, the high speed arbitrary waveform generator based on FPGA according to claim 1 is characterized in that having a plurality of waveform data memories corresponding to a plurality of parallel data phase generative circuits.Every circuit-switched data phase place that parallel data phase generative circuit is generated can obtain data by the waveform data memory of tabling look-up, thereby system can obtain a plurality of data simultaneously in a clock.
4, the high speed arbitrary waveform generator based on FPGA according to claim 1, what it is characterized in that utilizing multichannel data serial that parallel-to-serial converter that FPGA has generates system outputs to DAC successively.
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