TMS320C6713B_10 Datasheet, PDF(78/154 Page) Texas Instruments – FLOATING-POINT DIGITAL SIGNAL PROCESSOR

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TMS320C6713B_10 Datasheet, PDF (78/154 Pages) Texas Instruments – FLOATING-POINT DIGITAL SIGNAL PROCESSOR

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TMS320C6713B

FLOATINGÄPOINT DIGITAL SIGNAL PROCESSOR

SPRS294B â OCTOBER 2005 â REVISED JUNE 2006

PLL and PLL controller (continued)

The PLL Reset Time is the amount of wait time needed when resetting the PLL (writing PLLRST=1), in order

for the PLL to properly reset, before bringing the PLL out of reset (writing PLLRST = 0). For the PLL Reset Time

value, see Table 33. The PLL Lock Time is the amount of time from when PLLRST = 0 with PLLEN = 0 (PLL

out of reset, but still bypassed) to when the PLLEN bit can be safely changed to â1â (switching from bypass to

the PLL path), see Table 33 and Figure 15.

Under some operating conditions, the maximum PLL Lock Time may vary from the specified typical value. For

the PLL Lock Time values, see Table 33.

Table 33. PLL Lock and Reset Times

PLL Lock Time

PLL Reset Time

MIN TYP MAX UNIT

75 187.5 Âµs

125

Table 34 shows the deviceâs CLKOUT signals, how they are derived and by what register control bits, and what

is the default settings. For more details on the PLL, see the PLL and Clock Generator Logic diagram (Figure 15).

Table 34. CLKOUT Signals, Default Settings, and Control

CLOCK OUTPUT

SIGNAL NAME

CLKOUT2

CLKOUT3

DEFAULT SETTING

(ENABLED or DISABLED)

ON (ENABLED)

ECLKOUT

ON (ENABLED);

derived from SYSCLK3

CONTROL

BIT(s) (Register)

D2EN = 1 (PLLDIV2.[15])

CK2EN = 1 (EMIF GBLCTL.[3])

OD1EN = 1 (OSCDIV1.[15])

EKSRC = 0 (DEVCFG.[4])

EKEN = 1 (EMIF GBLCTL.[5])

DESCRIPTION

SYSCLK2 selected [default]

Derived from CLKIN

SYSCLK3 selected [default].

To select ECLKIN source:

EKSRC = 1 (DEVCFG.[4]) and

EKEN = 1 (EMIF GBLCTL.[5])

The input clock (CLKIN) is directly available to the McASP modules as AUXCLK for use as an internal

high-frequency clock source. The input clock (CLKIN) may also be divided down by a programmable divider

OSCDIV1 (/1, /2, /3, ..., /32) and output on the CLKOUT3 pin for other use in the system.

Figure 15 shows that the input clock source may be divided down by divider PLLDIV0 (/1, /2, ..., /32) and then

multiplied up by a factor of x4, x5, x6, and so on, up to x25.

Either the input clock (PLLEN = 0) or the PLL output (PLLEN = 1) then serves as the high-frequency reference

clock for the rest of the DSP system. The DSP core clock, the peripheral bus clock, and the EMIF clock may

be divided down from this high-frequency clock (each with a unique divider) . For example, with a 30 MHz input

if the PLL output is configured for 450 MHz, the DSP core may be operated at 225 MHz (/2) while the EMIF may

be configured to operate at a rate of 75 MHz (/6). Note that there is a specific minimum and maximum reference

clock (PLLREF) and output clock (PLLOUT) for the block labeled PLL in Figure 15, as well as for the DSP core,

peripheral bus, and EMIF. The clock generator must not be configured to exceed any of these constraints

(certain combinations of external clock input, internal dividers, and PLL multiply ratios might not be supported).

See Table 35 for the PLL clocks input and output frequency ranges.

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