/**
* Get a scaled sample from the output of the oversample and average engine for the channel.
*
* The value is scaled to units of Volts using the calibrated scaling data from GetLSBWeight() and GetOffset().
* Using oversampling will cause this value to be higher resolution, but it will update more slowly.
* Using averaging will cause this value to be more stable, but it will update more slowly.
*
* @param channel The channel to read.
* @return A scaled sample from the output of the oversample and average engine for the channel.
*/
float AnalogModule::GetAverageVoltage(UINT32 channel)
{
INT32 value = GetAverageValue(channel);
UINT32 LSBWeight = GetLSBWeight(channel);
INT32 offset = GetOffset(channel);
UINT32 oversampleBits = GetOversampleBits(channel);
float voltage = ((LSBWeight * 1.0e-9 * value) / (float)(1 << oversampleBits)) - offset * 1.0e-9;
return voltage;
}
/**
* Get a scaled sample from the output of the oversample and average engine for the channel.
*
* The value is scaled to units of Volts using the calibrated scaling data from GetLSBWeight() and GetOffset().
* Using oversampling will cause this value to be higher resolution, but it will update more slowly.
* Using averaging will cause this value to be more stable, but it will update more slowly.
*
* @param channel The channel to read.
* @return A scaled sample from the output of the oversample and average engine for the channel.
*/
float AnalogModule::GetAverageVoltage(uint32_t channel)
{
int32_t value = GetAverageValue(channel);
uint32_t LSBWeight = GetLSBWeight(channel);
int32_t offset = GetOffset(channel);
uint32_t oversampleBits = GetOversampleBits(channel);
float voltage = ((LSBWeight * 1.0e-9 * value) / (float)(1 << oversampleBits)) - offset * 1.0e-9;
return voltage;
}
/**
* Get a scaled sample from the output of the oversample and average engine for the channel.
*
* The value is scaled to units of Volts using the calibrated scaling data from GetLSBWeight() and GetOffset().
* Using oversampling will cause this value to be higher resolution, but it will update more slowly.
* Using averaging will cause this value to be more stable, but it will update more slowly.
*
* @param channel The channel to read.
* @return A scaled sample from the output of the oversample and average engine for the channel.
*/
float AnalogModule::GetAverageVoltage(UINT32 channel)
{
INT32 value = GetAverageValue(channel);
UINT32 LSBWeight = m_module->readLSBWeight(channel - 1, &status);
INT32 offset = m_module->readOffset(channel - 1, &status);
UINT32 oversampleBits = GetOversampleBits(channel);
float voltage = ((LSBWeight * 1.0e-9 * value) / (float)(1 << oversampleBits)) - offset * 1.0e-9;
wpi_assertCleanStatus(status);
return voltage;
}
bool CItemTable::FindDataField (const CString &sField, CString *retsValue)
// FindDataField
//
// Returns meta-data
{
// Deal with the meta-data that we know about
if (strEquals(sField, FIELD_TREASURE_VALUE))
*retsValue = strFromInt((int)GetAverageValue(1));
else
return CDesignType::FindDataField(sField, retsValue);
return true;
}
/**
* Get the Average voltage for the PID Source base object.
*
* @return The average voltage.
*/
double AnalogChannel::PIDGet()
{
return GetAverageValue();
}
/**
* Get the Average voltage for the PID Source base object.
*
* @return The average voltage.
*/
double AnalogChannel::PIDGet()
{
if (StatusIsFatal()) return 0.0;
return GetAverageValue();
}
