lecroy LW400A-OM3 电路图.pdf

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1、Appendix C C-1 LW400-09A Digital Output Option IntroductionThe LW400-09A Digital Output option provides 8-bit TTL and ECL, digital outputs corresponding to the current value of the channel 1 analog output. The latched digital data, which is held for the duration of the sample clock, is available via

2、 two rear panel mounted connectors. Digital data is available whenever the channel 1 output is enabled. LW400s, with the digital output option, include a special digital editing mode for the creation of user specified data patterns. Byte wide data patterns or selected bits within the 8-bit wide digi

3、tal word may be programmed. Digital data patterns created using this editor are identified as “Digital” waveforms. Digital waveforms can be edited using the same “cut and paste” tools available for analog waveforms. The major difference between the two waveform types is that digital waveforms are no

4、t processed to remove discontinuities at transitions. This also means that Time editing functions, such as sub-sample Move, are not useable with digital waveforms and are limited to analog waveforms only. Specifications Digital outputs:8 bits corresponding to the channel 1 analog output plus CLOCK a

5、nd CLOCK* (TTL only). Digital output modes:ECL, TTL all available on output connectors simultaneously. Mating output connector:SMB for ECL output 20 pin P/N 3M-3421-7020 for TTL output. Maximum data output clock rate: ECL, 400 MBytes/sec; TTL 100 MBytes/sec. RadioFans.CN 收音机爱 好者资料库 Appendix C C-2 EC

6、L outputs:Levels: ParameterMinTypMax VOH-0.98 V-0.8 V-0.71V VOL-1.95 V-1.8 V-1.58 V Note: output load is 50 to -2 Volts. Timing: ParameterMinTypMax Clock to Analog Output 7 ns8 ns9.8 ns Setup Time *T-660 psT-485 psT-310 ps Hold Time310 ps485 ps660 ps Data skew-80 ps250 ps * T is clock period (i.e. 2

7、.5 ns for 400 MHz clock) TTL : Levels: ParameterMinTypMax VOH2.00 V2.60 V- VOL-0.35 V0.80 V Timing: ParameterMinTypMax Clock to Analog Output 10 ns- Setup Time *T -5.7 nsT -0.5 nsT+3.9 ns Hold Time-3.9 ns0.5 ns5.7 ns Data skew-1 ns * T is clock period (i.e. 10 ns for 100 MHz clock) RadioFans.CN 收音机爱

8、 好者资料库 Appendix C C-3 CONNECTOR PINOUTS Note1:D7 signifies the bit which corresponds to analog signal most significant bit (MSB), and D0 signifies the bit which corresponds to the least significant bit (LSB). Note2: TTL outputs back terminated in 75 ohms TTL Port1 - TCLK2Ground 3- TCLK*4Ground 5- D0

9、 (LSB)6 Ground 7- D18Ground 9- D210Ground 11- D312Ground 13- D414Ground 15- D516Ground 17- D618Ground 19- D7 (MSB)20Ground ECL PortJ800- D0 (LSB) J700- D1 J600- D2 J500D3 J400- D4 J300- D5 J200- D6 J100- D7 (MSB) J900- ECLOCK RadioFans.CN 收音机爱 好者资料库 Appendix C C-4 Interconnection Information: TTL:Th

10、e LW400-09A includes 75 back terminations on all the TTL output lines. These resistors are used to match the transmission line impedance taking into account the additional source impedance of the TTL driver. The 75 resistors match the 80 impedance of the flat cable fairly well. In this fashion, no t

11、ermination resistor is required or desired. The most important consideration in this scheme is that the load should be as close to an open circuit as possible. One, or at most, two TTL loads should be placed at the termination of the line. Capacitance at the termination will have a detrimental effec

12、t on the rise time of the received signal. Every effort should be made to limit parasitic capacitance at the termination of the cable to under 10 pF. All grounds should be tied together at the load side of the cable. ECL:The LW400-09A provides 464 internal pulldown resistors at the ECL output driver

13、s. The ECL outputs need to be terminated at the load side of the cable. The most optimum interconnection would utilize ECL line receivers at the receiver end of the cable, with termination resistors of 50 tied to -2 Volts. Cable Selection:For TTL output: Spectra Strip 843-132 - 280-020. Appendix C C

14、-5 Appendix C C-6 Creating A Digital WaveformA new digital waveform, as in the case of a new analog waveform, is created by pressing the Select Wave button on the front panel and choosing the New menu item. Select New CH1 Wave from the New menu and then enter the waveform name in the Waveform menu f

15、ield. Press the Accept softkey to create the new waveform. Press the EDIT button on the front panel of the WaveStation to display the Edit menu. The presence of the LW400-09A Digital Output option is indicated by the Digital Edit softkey shown in Figure C3.1 above. Select Digital Edit to display the

16、 Digital Edit menu, shown in figure C3.2 below. Note that waveforms created in this editor are tagged as “digital”. Digital waveforms are not subject to signal processing functions to remove discontinuities. They are also allowed to use a wider range of sample clock rates. Figure C3.1 Appendix C C-7

17、 Digital waveforms are created and edited by specifying the digital value of the waveform, in hexadecimal, in the Value field. This value is entered, starting at the location specified in the Left Cursor field, with a length set in the Duration field whenever the Set Value softkey is pressed. The Du

18、ration and Left Cursor fields will read out in units of time or sample points as selected by the user using the Format softkey switch. A user message, ”Use the m-M keys for entering A-F” appears on the display while the Digital Edit or Bit Edit menus are displayed. Note that the units multiplier but

19、tons, m, , n, p, k, and M in the numeric keypad, are redefined during digital editing as hexadecimal characters A-F, respectively. The Editor Options menu is used to select one of two editing modesInsert (Ins) or Overwrite (Ovr). In insert mode the new digital waveform is inserted, starting at the l

20、eft cursor location while any existing waveform elements are displaced to the right (later in time) by the duration of the new waveform. In overwrite mode the enabled bits of the new digital waveform replace the corresponding bits in any existing waveform, starting at the left cursor location for th

21、e preset duration. The Bit Edit menu is used to edit selected bits specified using a bit mask in conjunction with the Value fieldsee figure C3.4 on page C-9. Figure C3.2 Appendix C C-8 Digital waveforms are displayed on the LW400 as “Bus Level” diagrams which show the time interval of each part of t

22、he waveform having a given digital value. Individual bit waveforms are not displayed. Digital waveform amplitude values can be read, as hexadecimal numbers, from the time cursor amplitude annotation fields, in the lower left corner of the LW400 display. Note that the Volt Cursors must be turned off

23、by pressing the VOLT CURSOR button on the front panel and then selecting Volt Cursors off as indicated by the displayed menu. See figure C3.2 above and the following figure C3.3 which shows an example of the relationship between the cursor readout fields and the actual bit patterns. Appendix C C-9 E

24、diting A Digital Waveform The Bit Edit menu is used to edit selected bits within a digital word. The 8 bit wide Field Mask is used to enable the desired bits. Setting a Field Mask bit to one (1), enables the corresponding bit in the digital waveform. The actual value of the enabled bit is determined

25、 by the user entered Masked Value. A zero (0) in the field mask means that the corresponding bit will be unchanged. Logically, the complement of the field mask is ANDd with the existing data value and the result is ORd with the expanded version of the masked value. Symbolically, this is expressed as

26、: Edited Value = (Value existing Field Mask) + (Masked Value) The most significant bit (MSB) of the field mask, corresponding to the MSB in the digital waveform(D7) is shown on the left. Similarly, the least significant bit (LSB), corresponding the LSB (D0) of the digital waveform is shown at the ri

27、ght. Figure C3.4 Appendix C C-10 Consider the Bit Edit menu values shown in figure C3.4 . The field mask is set to 00001011 enabling 3 bits(D3, D1, and D0). The Masked Value, entered as a hexadecimal number, is set to 5(101 in binary). The 3 enabled bits are set to this value, D3=1, D1=0 and D0=1. T

28、he digital waveform Value is hexadecimal 41. And the expanded mask value is 1. Note that the Value is read out at the left cursor position and displayed in the Left Cursor menu field. In the overwrite mode, only the enabled bits are replaced in an existing waveform. This is a simple way to edit sele

29、cted bits in an existing digital waveform. For example, by setting the Field Mask to 10000000, in overwrite mode, the MSB (D7) can be edited starting at the left cursor location for the length set by the duration field. In Insert mode, since the existing data is displaced, the expanded mask value is

30、 inserted into the waveform. The following figure (figure C3.5) illustrates the relationship between the Field Mask, Masked Value, Value, and the resulting digital waveform bit pattern. Figure C3.5 Appendix C C-11 Setting Clock Rates For Digital WaveformsThe clock rate associated with a digital wave

31、form has a much greater range of values than is available with analog waveforms. The clock on the LW400 and the LW400A can be set, by entering the frequency in the Clock Rate field on the CLOCK CONTROL menu. The clock ranges are described below: Lower Limit MHzUpper Limit MHz 355.000000400.000000 17

32、7.500000200.000000 118.333333133.333333 88.750000100.000000 71.000000 80.000000 59.166667 66.666667 50.714286 57.142857 0.006000 50.000000 In addition the LW400A has a continuous clock that can be set over a range of 6 kHz to 400 MHz, with 1 Hz resolution. Refer to section 13 for addtional informati

33、on related to setting the clock on the LW400 and LW400A. Appendix C C-12 Importing Digital WaveformsDigital waveforms can be imported directly into AWGs with the LW400-09A Digital Output option. Any Easywave .WAV file as well as ASCII Hex and ASCII Binary files can be imported as digital waveforms.

34、Figure C3.6 The Easywave .WAV file contains a single channel waveform created using LeCroys Easywave waveform creation software. ASCII Hex files contain groups of 2 digit hexadecimal numbers (0-F) separated by spaces. For example: 13 F0 03 8D C6 . ASCII BINARY files consist of groups of eight binary

35、 numbers (0s or 1s) separated by spaces. For Example: 10101010 00001011 01101111 . Waveforms are imported by pressing the PROJECT button then selecting the Import menusee figure C3.6 above. Choose Digital Esywv, ASCII HEX, or ASCII BINARY in the What field. Select the desired Source File and press t

36、he Import soft key. The selected file will be imported into the current project as a digital waveform. Use the Select Wave button to select the waveform for editing. Appendix C C-13 Analog Output for Digital WaveformsWhen a digital waveform is created the amplitude for the analog output is limited t

37、o the range of ( 500 mV, with -500 mV corresponding to the digital hex code 00 and +500 mV corresponding to the digital hex code FF . After a digital waveform is created, changing the amplitude or offset affects the output amplifiers only and not the DAC. As a result there will be no change to the d

38、igital codes when the amplitude or offset is changed, however the analog output amplitude and offset will change based on the modified settings. If it is desirable to produce an analog output with other than the (500 mV output the amplitude and offset need to be changed to the desired settings each

39、time the waveform is loaded. If an analog waveform is inserted into a digital waveform care must be taken to restrict its maximum voltage to 500 mV and the minimum voltage -500 mV, otherwise the output will be incorrect. Waveform Sequences Using Digital WaveformsDigital waveforms can be combined in

40、waveform sequences using the sequence editor in the normal manner. There is one key thing to keep in mind when creating sequences with digital waveforms. The signal processing functions used in generating sequences of analog waveforms are not used. Waveforms cannot be resampled to correct errors in

41、timing caused by using segments created using different sampling rates. Therefore, if digital waveform segments are created at different clock rates, the highest clock rate is used when the sequence is compiled. Essentially, digital sequences always preserve points and timing errors can occur if you

42、 are not careful. To avoid timing errors it is a good practice to create sequences from digital waveform segments which use the same clock rate. If you create a sequence using both analog and digital waveforms, then the sequence will be compiled as an analog waveform and the digital segments may be resampled, causing errors. It is advisable not to mix analog and digital segments within the same sequence.