71M6521DE Datasheet, PDF(61/101 Page) Teridian Semiconductor Corporation

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71M6521DE Datasheet, PDF (61/101 Pages) Teridian Semiconductor Corporation – Energy Meter IC

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71M6521DE/71M6521FE

Energy Meter IC

DATASHEET

JANUARY 2008

Temperature Compensation and Mains Frequency Stabilization for the RTC

The flexibility provided by the MPU allows for compensation of the RTC using the substrate temperature. To achieve this, the

crystal has to be characterized over temperature and the three coefficients Y_CAL, Y_CALC, and Y_CAL_C2 have to be

calculated. Provided the IC substrate temperatures tracks the crystal temperature the coefficients can be used in the MPU

firmware to trigger occasional corrections of the RTC seconds count, using the RTC_DEC_SEC or RTC_INC_SEC registers in

I/O RAM.

Example: Let us assume a crystal characterized by the measurements shown in Table 61:

Deviation from

Nominal

Temperature [Â°C]

Measured

Frequency [Hz]

Deviation from

Nominal

Frequency [PPM]

+50

32767.98

-0.61

+25

32768.28

8.545

32768.38

11.597

-25

32768.08

2.441

-50

32767.58

-12.817

Table 61: Frequency over Temperature

The values show that even at nominal temperature (the temperature at which the chip was calibrated for energy), the deviation

from the ideal crystal frequency is 11.6 PPM, resulting in about one second inaccuracy per day, i.e. more than some standards

allow. As Figure 30 shows, even a constant compensation would not bring much improvement, since the temperature

characteristics of the crystal are a mix of constant, linear, and quadratic effects.

32768.5

32768.4

32768.3

32768.2

32768.1

32768

32767.9

32767.8

32767.7

32767.6

32767.5

-50

-25

Figure 30: Crystal Frequency over Temperature

One method to correct the temperature characteristics of the crystal is to obtain coefficients from the curve in Figure 30 by

curve-fitting the PPM deviations. A fairly close curve fit is achieved with the coefficients a = 10.89, b = 0.122, and c = â0.00714

(see Figure 31).

nom

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106

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When applying the inverted coefficients, a curve (see Figure 31) will result that effectively neutralizes the original crystal

characteristics. The frequencies were calculated using the fit coefficients as follows:

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