51.16 External 32.768 kHz Oscillator (XOSC32) Electrical Specifications

Table 51-20. XOSC32K AC Electrical Specifications
AC CHARACTERISTICS			Standard Operating Conditions: VDDREG=VDDIO=AVDD 1.71V to 3.63V (unless otherwise stated) Operating temperature: -40°C ≤ TA ≤ +85°C for Industrial
Param. No.	Symbol	Characteristics	Min.	Typ.	Max.	Units	Conditions ⁽¹⁾
XOSC32_1	FOSC_XOSC32	XOSC32 Oscillator Crystal Frequency	—	32.768	—	kHz	XIN32, XOUT32 Secondary Osc
XOSC32_3	CXIN32	XOSC32 XIN32 parasitic pin capacitance	—	8	—	pF	—
XOSC32_5	CXOUT32	XOSC32 XOUT32 parasitic pin capacitance	—	8.5	—	pF	—
XOSC32_11	CLOAD_X32 ⁽³⁾	32.768kz Crystal Load Capacitance	—	—	12.5	pF	XOSC32K.CGM = 15 XOSC32K.XTALEN = 1 XOSC32K.ENABLE = 1
XOSC32_13	ESR_X32	32.768kz Crystal ESR	—	—	70	KΩ	XOSC32K.CGM = 15 XOSC32K.XTALEN = 1 XOSC32K.ENABLE = 1 Cload = 12.5 pF
XOSC32_15	TOSC32	TOSC32 = 1/FOSC_XOSC32	—	30.5176	—	µs	See parameter XOSC32_1 for FOSC_XOSC32 value
XOSC32_17	XOSC32_ST ⁽²⁾	XOSC32 Crystal Start-up Time	—	—	^{14000 (4)}	TOSC	XOSC32K.CGM = 15 XOSC32K.XTALEN = 1 XOSC32K.ENABLE = 1 Crystal ESR = 70 KΩ Cload = 12.5 pF ⁽²⁾ Crystal stabilization time only not Oscillator Ready
XOSC32_19	FOSC_XCLK32	Ext Clock Oscillator Input Freq (XIN32 pin)	31.13	32.768	34.406	kHz	XOSC32K.XTALEN = 0 XOSC32K.ENABLE = 1
XOSC32_21	XCLK32_DC	Ext Clock Oscillator Duty Cycle	25	50	75	%	XOSC32K.XTALEN = 0 XOSC32K.ENABLE = 1
XOSC32_23	XCLK32_FST	XIN32 Clock Fail Safe Time-out Period	—	4*1/(LP32K_1/2^CFDCTRL.CFDPRESC)	—	µs	—
Note: This is for guidance only. A major component of crystal start-up time is based on the 2nd party crystal MFG parasitics that are outside the scope of this specification. If this is a major concern the customer would need to characterize this based on their design choices. CRYSTAL LOAD CAPACITOR CALCULATION GIVEN: Standard PCB trace capacitance = 1.5 pF per 12.5 mm(0.5 inches) (i.e. PCB STD TRACE W=0.175 mm, H=36 μm, T=113 μm) X_TAL PCB capacitance typical therefore ~= 2.5pF for a tight PCB X_TAL layout For C_XIN and C_XOUT within 4pF of each other, Assume C_{XTAL_EFF} = ((C_XIN+C_XOUT) / 2) Note: Averaging C_XIN and C_XOUT will effect final calculated CLOAD value by less than the tolerance of the capacitor selection. EQUATION 1: MFG CLOAD Spec = {( [C_XIN + C1] * [C_XOUT + C2] ) / [C_XIN + C1 + C2 + C_XOUT] } + estimated oscillator PCB stray capacitance Assuming C1 = C2 and C_XIN ~= C_XOUT, the formula can be further simplified and restated to solve for C1 and C2 by: EQUATION 2: (i.e. Simplified Equation #1) C1 = C2 = ((2 * MFG CLOAD spec) - C_{XTAL_EFF} - (2 * PCB capacitance)) EXAMPLE ONLY: X_TAL Mfg CLOAD Data Sheet Spec = 12 pF PCB X_TAL trace Capacitance = 2.5 pF C_XIN pin = 6.5 pF, C_XOUT pin = 4.5 pF therefore C_{XTAL_EFF} = ((C_XIN+C_XOUT) / 2) C_{XTAL_EFF} = ((6.5 + 4.5)/2) = 5.5 pF C1 = C2 = ((2 * MFG CLOAD spec) - C_{XTAL_EFF} - (2 * PCB capacitance)) C1 = C2 = (24 - 5.5 - (2 * 2.5)) C1 = C2 = (24 - 5.5 - 5) C1 = C2 = 13.5 pF (Always rounded down) C1 = C2 = 13 pF (i.e., for hypothetical example crystal external load capacitors) User C1=C2=13pF ≤ C_{LOAD_X32}(max) spec User Selectable in XOSC32K.STARTUP. Figure 51-12. X_TAL