Workdocumentation 2018-08-18: Difference between revisions
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return float32(value) * float32(math.Pow10(c.precision)) | return float32(value) * float32(math.Pow10(c.precision)) | ||
} | } | ||
</source> | |||
<source lang='java'> | |||
// rvp6LittleEndian converts the raw two byte tuple of little endian encoded | |||
// composite products | |||
// to radar video processor values (rvp-6). NaN may be returned when the | |||
// no-data flag is set. | |||
public static float rvp6LittleEndian(Composite c, byte... tuple) { | |||
int value = 0x0F & tuple[1]; | |||
value = (value << 8) | (tuple[0]&0x0f); | |||
if ((tuple[1] & (1 << 5)) != 0) { // error code: no-data | |||
return Float.NaN; | |||
} | |||
if ((tuple[1] & (1 << 6)) != 0) { // flag: negative value | |||
value *= -1; | |||
} | |||
float conv = (float) c.rvp6Raw(value); // set decimal point | |||
// little endian encoded formats are also used for mm/h | |||
if (c.getDataUnit() != Unit.Unit_dBZ) { | |||
return conv; | |||
} | |||
// Even though this format supports negative values and custom | |||
// precision they do not make use of this and we still have to subtract | |||
// the bias and scale it (RADVOR FX, dBZ) | |||
return Conversion.toDBZ(conv); | |||
} | |||
// rvp6Raw converts the raw value to radar video processor values (rvp-6) by applying the | |||
// products precision field. | |||
public static double rvp6Raw(Composite c, int value) { | |||
double rvalue=value * c.getPrecisionFactor(); | |||
return rvalue; | |||
} | |||
</source> | </source> | ||
Revision as of 16:37, 18 August 2018
go:
java:
// rvp6LittleEndian converts the raw two byte tuple of little endian encoded composite products
// to radar video processor values (rvp-6). NaN may be returned when the no-data flag is set.
func (c *Composite) rvp6LittleEndian(tuple [2]byte) float32 {
var value int = 0x0F & int(tuple[1])
value = (value << 8) + int(tuple[0])
if tuple[1]&(1<<5) != 0 { // error code: no-data
return NaN
}
if tuple[1]&(1<<6) != 0 { // flag: negative value
value *= -1
}
conv := c.rvp6Raw(value) // set decimal point
// little endian encoded formats are also used for mm/h
if c.DataUnit != Unit_dBZ {
return conv
}
// Even though this format supports negative values and custom
// precision they do not make use of this and we still have to subtract
// the bias and scale it (RADVOR FX, dBZ)
return toDBZ(conv)
}
// rvp6Raw converts the raw value to radar video processor values (rvp-6) by applying the
// products precision field.
func (c *Composite) rvp6Raw(value int) float32 {
return float32(value) * float32(math.Pow10(c.precision))
}
// rvp6LittleEndian converts the raw two byte tuple of little endian encoded
// composite products
// to radar video processor values (rvp-6). NaN may be returned when the
// no-data flag is set.
public static float rvp6LittleEndian(Composite c, byte... tuple) {
int value = 0x0F & tuple[1];
value = (value << 8) | (tuple[0]&0x0f);
if ((tuple[1] & (1 << 5)) != 0) { // error code: no-data
return Float.NaN;
}
if ((tuple[1] & (1 << 6)) != 0) { // flag: negative value
value *= -1;
}
float conv = (float) c.rvp6Raw(value); // set decimal point
// little endian encoded formats are also used for mm/h
if (c.getDataUnit() != Unit.Unit_dBZ) {
return conv;
}
// Even though this format supports negative values and custom
// precision they do not make use of this and we still have to subtract
// the bias and scale it (RADVOR FX, dBZ)
return Conversion.toDBZ(conv);
}
// rvp6Raw converts the raw value to radar video processor values (rvp-6) by applying the
// products precision field.
public static double rvp6Raw(Composite c, int value) {
double rvalue=value * c.getPrecisionFactor();
return rvalue;
}