temp-fan-control/gertboard_sw/gb_pwm.c

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//=============================================================================
//
//
// Gertboard Demo
//
// This code is part of the Gertboard test suite
// Pulse-Width-Modulation part
//
// Copyright (C) Gert Jan van Loo & Myra VanIwengen2012
// No rights reserved
// You may treat this program as if it was in the public domain
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
//
// Try to strike a balance between keep code simple for
// novice programmers but still have reasonable quality code
//
// ______ ____ __
// | _ \ \ / / \/ |
// | |_) \ \ /\ / /| |\/| |
// | __/ \ V V / | | | |
// |_| \_/\_/ |_| |_|
//
// Beware of the following:
// 1/ Every write to a PWM register needs to be passed to the PWM clock
// This may take a while and takes longer if the PWM clock is slow.
// 2/ On top of that the PWM does NOT pick up any new values unless the counter
// reaches its end. So to quickly pick up a new value you have to disable it
// and then enable it again.
// 3/ The output polarity and reverse polarity bits are effective also if
// the PWM is disabled but not of there is no clock
// This is how we control a motor with a single PWM channel:
//
// |\ /|
// | \ / |
// | \ / |
// | >--A-(Motor)-B--< |
// | / \ |
// | / \ |
// |/ \|
//
//
// One direction:
// +---+ +---+ +---+ +---+
// A | | | | | | | |
// ==+ +======+ +======+ +======+ +=======
//
// B
// =============================================== (B is always low)
// The motor is driven (gets power) when A is high, so a PWM signal with
// A high for most of the time will make the motor go fast, and a PWM
// signal with A low for most for the time will make the mnotor turn
// slowly.
//
//
// Other direction:
// --+ +------+ +------+ +------+ +------
// A | | | | | | | |
// +===+ +===+ +===+ +===+
//
// ---------------------------------------------- (B is always high)
// B
//
// Here the situation is reversed: the motor is driven (but in the
// opposite direction) when A is low. So a PWM signal with
// A low for most of the time will make the motor go fast, and a PWM
// signal with A high for most for the time will make the mnotor turn
// slowly.
//
// Off is both A and B low (or high, but I use low)
//
//
#include "gb_common.h"
#include "gb_pwm.h"
//
// Setup the Pulse Width Modulator
// It needs a clock and needs to be off
//
void setup_pwm()
{
// Derive PWM clock direct from X-tal
// thus any system auto-slow-down-clock-to-save-power does not effect it
// The values below depends on the X-tal frequency!
PWMCLK_DIV = 0x5A000000 | (1920<<12); // set pwm div to 32 (19.2/3 = 600KHz)
PWMCLK_CNTL = 0x5A000011; // Source=osc and enable
// Make sure PWM is off
PWM_CONTROL = 0; short_wait();
// I use 1024 steps for the PWM
// (Just a nice value which I happen to like)
PWM0_RANGE = 400; //0x400;
short_wait();
} // setup_pwm
//
// Set PWM value
// This routine does not wait for the value to arrive
// If a new value comes in before it is picked up by the chip
// it will definitely be too fast for the motor to respond to it
//
void set_pwm0(int v)
{ // make sure value is in safe range
if (v<0) v=0;
if (v>0x400) v=0x400;
PWM0_DATA = v;
} // set_pwm0
//
// Force PWM value update
// This routine makes sure the new value goes in.
// This is done by dis-abling the PWM, write the value
// and enable it again. This routine is weak as it
// uses a delay which is tested (but not guaranteed)
// Controls channel 0 only.
//
void force_pwm0(int v,int mode)
{ int w;
// disable
PWM_CONTROL = 0;
// wait for this command to get to the PWM clock domain
// that depends on PWN clock speed
// unfortunately there is no way to know when this has happened :-(
short_wait();
// make sure value is in safe range
if (v<0) v=0;
if (v>0x400) v=0x400;
PWM0_DATA = v;
short_wait();
PWM_CONTROL = mode;
short_wait();
} // force_pwm0
void pwm_off()
{
force_pwm0(0,0);
}