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80MHz 12 bit ADC processor LPC4370.
LPCxpresso do a LPC LINK2 and LABTOOLS open source oscilloscope demo set. (£84 from Mouser, seems quite well liked.)
The LPC LINK2 is £14 + VAT from Mouser, it has the ADC on board. The Lab tools board has signal conditioning, BNC, protection etc.
Using just the LPCLINK2 board:
Remove C14. Add a 27K resistor between the old C14 input pin and pin 2 of J4 (VDDA +3.3V). Replace R3 with a range set resistor, for example 100k for about +-10V input. (gives 5mV resolution.) The open circuit input will float up slightly. The input impedance of the ADC is specified as 5k in parallel with 4.5pF. Bandwidth will be around 10MHz.
Connect input to J4 pin 6 and a GND to pin 1.
There are a number of possible variants which may perform better or be easier to do or provide additional channels.
The open source software would have to be hacked as various peripherals on the lab tools board are missing.
I have not tried this proposed mod.
Review
http://www.drdobbs.com/embedded-systems/embedded-tools/240168337
Datasheet
http://www.nxp.com/documents/data_sheet/LPC4370.pdf
http://www.lpcware.com/lpclink2
http://www.embeddedartists.com/products/app/labtool.php
Source firmware and app:
https://github.com/embeddedartists/labtool
Relevant links
https://groups.google.com/forum/#!topic/labtool/Rtp3ZCPygfU
It is an add-on board to LPC-Link 2 (which is based on the LPC4370 - a 204 MHz Cortex-M4 with an 80 MHz ADC and two extra Cortex-M0 cores).
LabTool make use of all features on the LPC4370, creating a powerful development tool.
The feature rich Windows software interface supports:
Digital inputs | • 11 channel logic analyzer • without trigger: 100 Msps (1-4 ch), 50 Msps (5-8 ch), 20 Msps (9-11 ch) • with trigger: 100 Msps (1-2 ch), 80 Msps (3-4 ch), 40 Msps (5-8 ch), 20 Msps (9-11 ch) • Falling/rising edge triggers with logical OR between channels • 3.3V logic level as default but 2.4-5.5V supported via DIO_VCC |
Analog inputs | • 2 channel oscilloscope • 60 Msps (1 ch) and 30 Msps (2 ch) sampling (can be increased to 80/40 Msps if no hardware trigger is enabled) • +-25V input range, 1 Mohm input impedance, TBD pF input capacitance • AC/DC control • BNC connector and flexible cables via 26-pos IDC connector • 6 MHz BW (3 MHz for 20mV/div range and up to 12 MHz on 0.2V/div and 5V/div range) |
Digital outputs | • 11 channel digital signal generator • 80 Msps • 3.3V logic level |
Analog outputs | • 2 channel analog signal generator • +-5V, 40 kHz BW • Sine, square and triangle waveforms |
Dimensions | 83 x 90 mm |
Power | 5.0V via mini-B USB connector |
Connectors |
• 26-pos IDC connector for digial and analog I/O |
Other | • 12 channel demo signal generator (UART, I2C, SPI, counter, PWM) from on-board LPC812. • HW provision for I2C logging (sw not implemented) • Analog calibration, can be done by user • Open source software |
Documents
Installer
Instructions for using the Raspberry Pi archive can be found here
Software
The software is open source and is available on github
Discussions
There is a mailing list available for discussions about problems or improvements.
I mentioned last time that programmers and electrical engineers have it rough because you can‘t really see what‘s going on in your design. That‘s probably why most of us love tools like oscilloscopes and logic analyzers.
Being a ham radio operator, I‘ve had a scope since I was a kid. But buying a scope for personal use used to mean buying something old or something with very little capability, or both. Now you can get a scope that would have broke the bank a few years ago for about what a low-end PC would cost.
Still, even that‘s a bit much if you are just a casual user. There are a lot of inexpensive alternatives that connect to a PC or have a little screen but they aren‘t usually very good. They can still be better than nothing.
I did run into a sort of "in between" board the other day when I was writing about the LPC-Link debugger for the LPC-series ARM chips. I bought an LPC-Link 2 board for about $20 and then found that there was another product from Embedded Artists that included an LPC-Link 2 board. It was called LabTool.
It is a little hard to characterize exactly what it is. At the core, it is an ARM-based development board. The board contains an LPC4370, which is a 204 MHz Cortex M4 processor. There are also two extra Cortex M0 processors onboard and an 80MHz analog to digital converter. That‘s a lot of horsepower. The board mates with an LPC Link 2 board and you can detach the link board and use it for other things if you want.
Of course, that‘s only useful if you want to write some software. The selling point is the open source LabTool software that provides an 11-channel logic analyzer (up to 100 million samples per second), a 2-channel analog oscilloscope that can achieve up to 80 million samples per second, an 11-channel signal generator that can hit 80 million samples per second, and a 2-channel analog signal generate (up to 40 kHz). You can see an example run of the digital and analog sampling in the figure below.
Dirceu Rodrigues, Jr. - Oct. 2013
Dirceu Rodrigues, Jr. is a computer engineer with a master‘s degree in electrical engineering. As an independent consultant, he tests new products with particular interest in the areas of wireless sensor networks, ARM processors, DSP, motor control, and medical applications.
When I got involved with this campaign, my initial idea was to use the NXP LPC4370 microcontroller available on the LPC-Link 2 to implement a multicore FIR filter.Combined with the analog processing capabilities present on LabTool add-on board, would be ideal to put in place a structure which I discussed on ESC Brazil 2013 (MulticoreMicrocontrollers in Instrumentation and Control). But after a time studying the schematics of these boards, I realized that understanding the signal conditioning circuits, gain settings, input calibration and the correct use of ADCHS (12 bit High Speed ??ADC) peripheral and external DAC, deserve a whole article. For me, the most important feature of the board LPC-Link 2 (in addition to being a programmer/debugger for the target) is able to program a generic application on LPC4370 memory, since there are several analog/digital pins availableon expansion connectors.
Firstly, I downloaded the latest version of the ARM Keil µVision (V4.72.10.0). At time, I had not experienced the new LPCOpen library, so I changed the LPC43xx.h provided by the compiler to add a raw support for ADCHS peripheral - renaming it to LPC43xx_new.h. The change consists primarily in define register addresses, enabling references such as “LPC_ADCHS->xxx”. Before attach LPC-Link 2 on top of LabTool board, I connected the 10 pin SWD cable on J2 of LPC-Link 2, according Figure 1. Will look like the cable issqueezed between the boards, but that is quite normal. Also, the user must to ensure the other connectors are not slightly misaligned.
Next I tried to unveil the structure around the high speed analog to digital converter. The reason for the presence of the BNC connectors on LabTool is to implement a complete two channel oscilloscope, whose features are far from modest, since the LPC4370 includes a 12 bit ADC, and can operate up to 80 MHz. Note that the two 10 bit ADC modules are absent on LPC4370 TFBGA100 package used in LabTool. A very simplified schematic of input conditioning circuit for each channel is shown on Figure 2. The complete design, provided by Embedded Artists[1], includes several other components, including capacitors for shaping the frequency response.
All settings are controlled via the SPI interface, including the DC/AC coupling. The input (0.5 V) is provided by a proper MCU pin related to ADCHS, as I will explainlater. Two analog multiplexers allow set the gain when changing the operational amplifier feedback resistor. From the nominal values of components on figure, we can write some equations for the DC model:
The LPC4370 ADC is a flash type with differential input - Figure 3.
The value converted to digital domain, as presented on page 1287 of LPC43xx User Manual (2013 draft version), is:
Through the DCINNEG and DCINPOS bits on ADCHS POWER_CONTROL register, the user can add a 0.5 V DC offset to the differential inputs. In the case of Labtool board, is convenient make DCINNEG = 1 and DCINPOS = 0, considering the presence of amp op with the non-inverting input voltage
according Figure 2. With these settings:
Also, note that
Substituting these results on Eq. 4:
and:
The value of GA depends on position of two multiplexers (feedback resistor selection 1 out 8)
and SPDT switch (divided input voltage selection VU or VD).
So, I can create the Table 1, which allow me to calculate the analog input value or VCH1, for each selection.
In order to obtain a value of acceptable precision it‘s required to compensate the ADC readings (NADC) for component tolerances and other deviations associated with the inputconditioning circuit. This is done in software. An affine function (gain and offset) makes the correction based on the current reading and previous calibration data – Listing 1.
Remember that a measuring instrument is not only as good as its components, but also as the calibration method used.
The Digital to Analog section is more straightforward.
Since the 10 bit DAC module is absent on LPC4370 TFBGA100 package, the LabTool board relies
on external DAC102S085 from National to output two analog voltages.
As before, the simpler schematic on Figure 4 shows the essential components for the DC model.
On LabTool board, the LPC4370 SSP1 peripheral has three usages:
The sharing is carried out through appropriate slave selection signals (SSEL and GPIOs) from MCU.
The DAC has two channels with internal data register including controls for update/refresh timing.
In order to test the ADCHS and related equations obtained from the LabTool manufacturer schematics, I decided to program the ARM Cortex-M4 on LPC4370 to implement a stop-band FIR (Finite Impulse Response) filter with 127 taps. The idea is to filter an ECG signal corrupted by 60 Hz hum. To avoid building a circuit around an instrumentation amplifier(something I‘ve done a few times) and waste some skin electrodes; I thought using the computer sound card to generate the desired signal. So, the following tasks were performed:
This will allow some experimentation, as repeat intervals, invert polarity, attenuate and many other useful transformations - Figure 6.
For this application, I used DC coupling on input (capacitor short-circuited on Figure 2). Also, the ADCHS was configured to present the result in two’s complement format (other option is offset binary) . Figure 7 shows a diagram for the FIR filter - coefficients and output labeled as c and NFILT, respectively.
To check the result, the filtered signal is sent to the analog output in real time. For this it’s necessary to perform a conversion between the ADCHS and DAC102S085 ranges using appropriate equations. Here I have at least two options:
1. Taking advantage of maximum available resolution (not used):
In this case, the conversion is performed through the Equation 10 and Figure 8.
2. Equal amplitudes (input/output):
In the ECG filtering applicatioon it is desirable that the original and filtered signals had the same amplitude, or a 1:1 relationship. Therefore, I‘ve carried a different conversion in order to meet VEXT_AOUT1 = VCH1. Still maintaining the gain 10 between VCH1 and NFILT and equating Eq. 12 and Eq. 9:
The sampling and output rates both are equal to 1k/s. Note an approximate delay of 64 ms between input and output (representing taps/2 samples). This powerfulmicrocontroller and its high speed ADC are able to handle sample rates much higher than the one I used here, including multichannel audio. As I mentioned earlier,the purpose of this simple application is just to introduce the analog resources available on LabTool board.
The ADCHS has many other configuration options. It works through a state machine with a dedicated timer and a set of eight descriptors, for which it is possible to establish how andwhen a conversion occurs, generating interrupts, filling a 16 position FIFO or transferring data through DMA
The clock for this application was adjusted to 180 MHz, a value more than sufficient. In a next installment, I intend to wake-up the other two Cortex-M0 cores on the LPC4370, implementing a truly multicore filter through IPC (Inter-process Communication), running at a lower clock; something like 60 MHz and compare the results with the single core solution– for example, analyzing the power consumption. Stay tuned [3].
[1] http://www.embeddedartists.com
[2] http://courses.engr.illinois.edu/bioe415/labs/ecgwav.html
[3] http://www.youtube.com/DirceuRodriguesJr
LabTool : LPC LINK2, LPC4370 cheap scope: 80Ms/s 12 bit
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原文地址:http://www.cnblogs.com/shangdawei/p/4775260.html