467 lines
19 KiB
C
467 lines
19 KiB
C
#ifndef __usbledfader_h_included__
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#define __usbledfader_h_included__
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/**
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* \file usbledfader.h
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* \brief Global definitions and datatypes, used by the firmware and the commandline-client. Also contains the main doxygen-documentation.
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* \author Ronald Schaten & Thomas Stegemann
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* \version $Id: usbledfader.h,v 1.2 2006/10/01 16:28:01 rschaten Exp $
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*
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* License: See documentation.
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*/
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/**
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* \mainpage USB-LED-Fader
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*
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* \section sec_intro Introduction
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*
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* The USB-LED-Fader is a device to control a number of LEDs via USB. I built
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* it to display the online-status of my internet-connection, the
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* recording-status of my videorecorder, and warnings if the available
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* disc-space is low. You can imagine an endless number of applications for
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* this.
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*
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* The LEDs are controlled with pulse width modulation (PWM). That way, they
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* are not only on or off, it is possible to control the brightness. Included
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* in the device is a number of 'waveforms' that can be displayed on the LEDs.
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* That way, one LED can display some kind of a sinus- or triangular wave
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* without any interaction with the controlling host.
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*
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* Every LED can be controlled individually, each one can display it's own
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* waveforms.
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*
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* You can assign three different waves to every LED: two 'eternal' waves (0 &
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* 1). They are displayed alternating until anything different is required. The
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* third wave (2) is only displayed once, afterwards the device will switch
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* back to alternating between the first two waves.
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*
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* One wave is described by three parameters: the waveform, the duration for
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* one repetition of the wave and the number of repetitions before switching to
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* the next wave.
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*
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* This version supports four LEDs, it should be quite easy to change that
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* number between one and eight. I have not tested any number greater than
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* four, but I can imagine that the load on the controller can be too high to
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* reliably communicate via USB.
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*
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* There are three parts included in the distribution: The firmware for an
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* ATmega8 microcontroller, a commandline-client that can be run under Linux,
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* and the circuits needed to build the device.
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*
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* This project is based on the PowerSwitch example application by Objective
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* Development. Like that, it uses Objective Development's firmware-only USB
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* driver for Atmel's AVR microcontrollers.
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*
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* Objective Development's USB driver is a firmware-only implementation of the
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* USB 1.1 standard (low speed device) on cheap single chip microcomputers of
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* Atmel's AVR series, such as the ATtiny2313 or even some of the small 8 pin
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* devices. It implements the standard to the point where useful applications
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* can be implemented. See the file "firmware/usbdrv/usbdrv.h" for features and
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* limitations.
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*
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* \section sec_install Building and installing
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*
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* Both, the firmware and Unix command line tool are built with "make". You may
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* need to customize both makefiles.
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*
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* \subsection sec_fw Firmware
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*
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* The firmware for this project requires avr-gcc and avr-libc (a C-library for
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* the AVR controller). Please read the instructions at
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* http://www.nongnu.org/avr-libc/user-manual/install_tools.html for how to
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* install the GNU toolchain (avr-gcc, assembler, linker etc.) and avr-libc.
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*
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* Once you have the GNU toolchain for AVR microcontrollers installed, you can
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* run "make" in the subdirectory "firmware". You may have to edit the Makefile
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* to use your preferred downloader with "make program". The current version is
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* built for avrdude with a parallel connection to an stk200-compatible
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* programmer.
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*
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* If working with a brand-new controller, you may have to set the fuse-bits to
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* use the external crystal:
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*
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* \code
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* avrdude -p atmega8 -P /dev/parport0 -c stk200 -U hfuse:w:0xC9:m -U lfuse:w:0x9F:m
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* \endcode
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*
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* Afterwards, you can compile and flash to the device:
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*
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* \code
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* make program
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* \endcode
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*
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* \subsection sec_client Commandline client
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*
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* The command line tool requires libusb. Please take the packages from your
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* system's distribution or download libusb from http://libusb.sourceforge.net/
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* and install it before you compile. Change to directory "commandline", check
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* the Makefile and edit the settings if required and type
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*
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* \code
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* make
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* \endcode
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*
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* This will build the unix executable "usb-led-fader" which can be used to
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* control the device.
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*
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* \section sec_usage Usage
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*
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* Connect the device to the USB-port. All LED should flash up to indicate that
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* the device is initialized.
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*
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* Then use the commandline-client as follows:
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*
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* \code
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* usb-led-fader status
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* usb-led-fader set <ledId> <waveId> <waveformId> <periodDuration> <repetitionCount>
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* usb-led-fader clear <ledId>
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* usb-led-fader reset
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* usb-led-fader show <waveformId>
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* usb-led-fader test
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* \endcode
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*
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* When using the set-function, it is possible to define several waves at once.
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* You simply have to give the parameters for all waves. See examples below.
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*
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* \subsection sec_params Parameters
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*
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* - \e ledId: ID of the LED (0-n, depending on the number of LEDs in your
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* circuit).
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* - \e waveId: ID of the wave (0-1: constant waves, 2: override).
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* - \e waveformId: ID of the waveform (0-31: brightness, 32-37: patterns). For
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* a reference to the patterns, consult the function fade_calculateWaveform()
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* in the file "firmware/main.c".
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* - \e periodDuration: Time in sec/10 for one repetition of the waveform. A
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* value of 0 can be used to reset the wave.
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* - \e repetitionCount: Number of repetitions before switching to the next
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* wave. A value of 0 can be used to repeat this forever.
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*
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* \subsection sec_examples Examples
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*
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* <b>Get the status of all LEDs:</b>
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* \code
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* usb-led-fader status
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* \endcode
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* This will result in an output similar to this:
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* \code
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* LED 0 curid curvalue curpos currep nextupd
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* 0 2 26 0 23
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* wave waveform length repeat duration updtime
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* 0 38 32 1 20 45
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* 1 0 1 1 0 1
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* 2 0 1 1 0 1
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* LED 1 curid curvalue curpos currep nextupd
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* 0 14 19 0 19
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* wave waveform length repeat duration updtime
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* 0 38 32 1 20 45
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* 1 0 1 1 0 1
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* 2 0 1 1 0 1
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* LED 2 curid curvalue curpos currep nextupd
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* 0 31 16 0 43
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* wave waveform length repeat duration updtime
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* 0 38 32 1 20 45
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* 1 0 1 1 0 1
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* 2 0 1 1 0 1
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* LED 3 curid curvalue curpos currep nextupd
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* 0 6 9 0 39
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* wave waveform length repeat duration updtime
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* 0 38 32 1 20 45
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* 1 0 1 1 0 1
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* 2 0 1 1 0 1
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* \endcode
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* In this output, the values curvalue, curpos, nextupd and updtime are for
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* debugging purposes only. They shouldn't be of interest to the common user.
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* The meaning of the other values should be clear.
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*
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* <b>Set the first LED to keep a middle brightness:</b>
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* \code
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* usb-led-fader set 0 0 15 10 1
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* \endcode
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* So, on LED 0 the wave 0 is set to waveform 15. It will stay there for one
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* second and will be repeated once before switching to the next wave. There is
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* no next wave because we didn't define one, so this waveform will stay
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* forever.
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*
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* <b>Now set a second wave on the first LED, a little brighter than the one
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* before:</b>
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* \code
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* usb-led-fader set 0 1 25 10 1
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* \endcode
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* This is wave 1 on LED 0, waveform 25 indicates a constant level of
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* brightness. After setting the second wave, it will alternate with the first
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* one after every second, because both waves have the same duration and the
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* same number of repetitions.
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*
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* <b>Set a third wave on the first LED:</b>
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* \code
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* usb-led-fader set 0 2 36 20 5
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* \endcode
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* This sets the third wave (wave 2) on the first LED. Waveform 36 is a nice
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* sinus-like wave, so the LED starts to fade. One period of the fading takes 2
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* seconds, it is repeated for 5 times. Since this is the third wave, after the
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* repetitions the LED returns to alternating between wave 0 and wave 1, this
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* wave is discarded.
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*
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* <b>Set multiple waves at once:</b>
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* \code
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* usb-led-fader set 0 0 15 10 1 0 1 25 10 1 0 2 36 20 5
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* \endcode
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* This will set all of the above waves at once. Thus, the first LED will first
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* fade the sinus-wave five times, then start alternating between the two
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* brightnesses in one-second-rhythm.
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*
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* <b>Clear the first LED:</b>
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* \code
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* usb-led-fader clear 0
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* \endcode
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* This will clear all three waves on the first LED.
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*
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* <b>Reset the device:</b>
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* \code
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* usb-led-fader reset
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* \endcode
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* All LEDs will flash once, to indicate that the device is reset and the LEDs
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* are working.
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*
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* <b>Show a waveform on the screen:</b>
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* \code
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* usb-led-fader show 36
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* \endcode
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* This will lead to an output like the following:
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* \code
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* wave 36 - length 64
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* 31: *****
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* 30: *********
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* 29: ***********
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* 28: ***************
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* 27: *****************
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* 26: *******************
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* 25: *******************
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* 24: *********************
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* 23: ***********************
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* 22: *************************
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* 21: *************************
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* 20: ***************************
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* 19: *****************************
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* 18: *****************************
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* 17: *******************************
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* 16: *********************************
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* 15: ***********************************
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* 14: ***********************************
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* 13: *************************************
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* 12: ***************************************
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* 11: ***************************************
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* 10: *****************************************
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* 9: *******************************************
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* 8: *********************************************
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* 7: *********************************************
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* 6: ***********************************************
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* 5: *************************************************
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* 4: *****************************************************
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* 3: *******************************************************
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* 2: ***********************************************************
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* 1: ****************************************************************
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* ================================================================
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* \endcode
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* Keep in mind that the width of the displayed wave corresponds to the length
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* of the waveform. If you display a very simple one like the constant
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* brightness levels (0-31), the length is 1. Therefore only one column is
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* displayed.
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*
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* <b>Test the device:</b>
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* \code
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* usb-led-fader test
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* \endcode
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* This function sends many random numbers to the device. The device returns
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* the packages, and the client looks for differences in the sent and the
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* received numbers.
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*
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* \section sec_drawbacks Drawbacks
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*
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* As mentioned above, controlling the PWM for several LEDs is a lot of work
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* for one small microcontroller. Speaking the USB protocol is so, either. Both
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* combined result in a lot of load on the device, so the communication with
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* the device is not 100% reliable. More than 99% though, at least in our
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* tests.
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*
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* <b>SO BE WARNED:</b> You should not use this device to control the state of
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* your nuclear reactor. If you intend to use it in that way despite of this
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* warning, please let me know... ;-)
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*
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*
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* \section sec_files Files in the distribution
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*
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* - \e Readme.txt: The file you are currently reading.
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* - \e firmware: Source code of the controller firmware.
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* - \e firmware/usbdrv: USB driver -- See Readme.txt in this directory for
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* info
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* - \e commandline: Source code of the host software (needs libusb).
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* - \e common: Files needed by the firmware and the commandline-client.
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* - \e circuit: Circuit diagrams in PDF and EAGLE 4 format. A free version of
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* EAGLE is available for Linux, Mac OS X and Windows from
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* http://www.cadsoft.de/.
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* - \e License.txt: Public license for all contents of this project, except
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* for the USB driver. Look in firmware/usbdrv/License.txt for further info.
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* - \e Changelog.txt: Logfile documenting changes in soft-, firm- and
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* hardware.
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*
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* \section sec_thanks Thanks!
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*
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* I'd like to thank <b>Objective Development</b> for the possibility to use
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* their driver for my project. In fact, this project wouldn't exist without
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* the driver.
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*
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* And I'd like to give special credits to <b>Thomas Stegemann</b>. He wrote
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* the PWM-stuff, and I guess it would have been nearly to impossible to me to
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* write the rest of the project without his help since C isn't my natural
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* language.
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*
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* \section sec_license About the license
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*
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* Our work - all contents except for the USB driver - are licensed under the
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* GNU General Public License (GPL). A copy of the GPL is included in
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* License.txt. The driver itself is licensed under a special license by
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* Objective Development. See firmware/usbdrv/License.txt for further info.
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*
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* <b>(c) 2006 by Ronald Schaten - http://www.schatenseite.de</b>
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*/
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#include <stdint.h>
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/* return codes for USB-communication */
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#define msgOK 0 /**< Return code for OK. */
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#define msgErr 1 /**< Return code for Error. */
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/* These are the vendor specific SETUP commands implemented by our USB device */
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#define CMD_ECHO 0 /**< Command to echo the sent data */
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#define CMD_GET 1 /**< Command to fetch values */
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#define CMD_SET 2 /**< Command to send values */
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#define CMD_CLEAR 3 /**< Command to switch off a certain LED */
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#define CMD_RESET 4 /**< Command to reset the whole device */
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/** Description of one waveform. */
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typedef struct S_fade_Waveform {
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uint8_t waveformId; /**< ID of this waveform. */
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uint8_t waveformLength; /**< Length of this waveform. */
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uint8_t waveformRepetition; /**< How often is this waveform to be repeated? */
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uint8_t waveformDuration; /**< Duration for one cycle of this waveform, stored for status-output. */
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uint32_t waveformUpdateTime; /**< Time between two waveform-samples in calls of timerInterrupt(), calculated from waveformDuration. */
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} fade_Waveform;
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/** The state of one LED. */
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typedef struct S_fade_LedState {
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fade_Waveform wave[3]; /**< Three waveforms: base-function1, base-function2 and override-function. */
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uint8_t waveCurrentId; /**< Which of the three waveforms is currently displayed? */
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uint8_t waveCurrentValue; /**< The current brightness. */
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uint8_t waveCurrentPosition; /**< Our position in the current waveform. */
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uint8_t waveCurrentRepetition; /**< We are in the n-th repetition. */
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int32_t waveNextUpdate; /**< Number of cycles till next update. */
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} fade_LedState;
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/** Contains the state of all four LEDs. */
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typedef struct S_fade_GlobalData {
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fade_LedState led[4]; /**< Data for four LEDs. */
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} fade_GlobalData;
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uint8_t fade_calculateWaveform(uint8_t waveformId, uint8_t waveformPosition);
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/**
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* Calculate a waveform. Returns either the length of a given waveform or the
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* output-level at a certain position in the wave.
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* \param waveformId ID of the waveform in question.
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* \param waveformPosition 0 or position in the given waveform.
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* \return If the waveformPosition is 0, the number of steps in this waveform is returned. Otherwise the resulting output-level, an integer between 0 and 31.
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*/
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uint8_t fade_calculateWaveform(uint8_t waveformId, uint8_t waveformPosition) {
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/*
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* values for sinus-wave, amplitude 31, 64 steps:
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* awk 'BEGIN{ pi=3.1415927; for(i=1; i<=64; i++) { printf("%.0f, ", sin(i*pi/32)*31) } printf("\n"); }'
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* 3, 6, 9, 12, 15, 17, 20, 22, 24, 26, 27, 29, 30, 30, 31, 31, 31, 30,
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* 30, 29, 27, 26, 24, 22, 20, 17, 15, 12, 9, 6, 3, -0, -3, -6, -9,
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* -12, -15, -17, -20, -22, -24, -26, -27, -29, -30, -30, -31, -31, -31,
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* -30, -30, -29, -27, -26, -24, -22, -20, -17, -15, -12, -9, -6, -3, 0
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*/
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/* sinus-wave:
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* awk 'BEGIN{ pi=3.1415927; for(i=1; i<=64; i++) { printf("%.0f, ", sin((i+48)*pi/32)*15+16) } printf("\n"); }'
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*/
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uint8_t sinus[] = { 1, 1, 2, 2, 3, 4, 4, 5, 6, 8, 9, 10, 12, 13, 15, 16,
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17, 19, 20, 22, 23, 24, 26, 27, 28, 28, 29, 30, 30, 31, 31, 31, 31, 31,
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30, 30, 29, 28, 28, 27, 26, 24, 23, 22, 20, 19, 17, 16, 15, 13, 12, 10,
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9, 8, 6, 5, 4, 4, 3, 2, 2, 1, 1, 1 };
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/*
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* another nice wave, wider than the original sinus:
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* awk 'BEGIN{ pi=3.1415927; for(i=1; i<=32; i++) { printf("%.0f, ", sqrt(sin(i*pi/32)*31+.00001)*sqrt(32)) } printf("\n"); }'
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*/
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uint8_t widecurve[] = { 10, 14, 17, 19, 22, 23, 25, 26, 28, 29, 30, 30, 31,
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31, 31, 31, 31, 31, 31, 30, 30, 29, 28, 26, 25, 23, 22, 19, 17, 14, 10,
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0 };
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if (waveformId <= 31) {
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/* No fading, just a constant level */
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if (waveformPosition == 0) {
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return 1;
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} else {
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return waveformId;
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}
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} else {
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switch (waveformId) {
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case 32: /* blink */
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if (waveformPosition == 0) {
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return 2;
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} else {
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if (waveformPosition == 1) {
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return 31;
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} else {
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return 0;
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}
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}
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case 33: /* triangular */
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if (waveformPosition == 0) {
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return 62;
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} else {
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if (waveformPosition <= 32) {
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return waveformPosition - 1;
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} else {
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return 63 - waveformPosition;
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}
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}
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case 34: /* sawtooth rising */
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if (waveformPosition == 0) {
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return 32;
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} else {
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return waveformPosition - 1;
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}
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case 35: /* sawtooth falling */
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if (waveformPosition == 0) {
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return 32;
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} else {
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return 31 - (waveformPosition - 1);
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}
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case 36: /* sinus */
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if (waveformPosition == 0) {
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return 64;
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} else {
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return sinus[waveformPosition - 1];
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}
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case 37: /* wide curve */
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if (waveformPosition == 0) {
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return 32;
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} else {
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return widecurve[waveformPosition - 1];
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}
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case 38: /* wide curve - inverted */
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if (waveformPosition == 0) {
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return 32;
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} else {
|
|
return 31 - widecurve[(waveformPosition + 15) % 32];
|
|
}
|
|
}
|
|
}
|
|
return 0;
|
|
}
|
|
|
|
#endif
|
|
|