CY22150 データシートの表示（PDF） - Cypress Semiconductor

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CY22150

One-PLL General-Purpose Flash-Programmable and 2-Wire Serially Programmable Clock Generator

Cypress Semiconductor 

CY22150

Input Load Capacitors

Input load capacitors allow the user to set the load capacitance

of the CY22150 to match the input load capacitance from a

crystal. The value of the input load capacitors is determined by

8 bits in a programmable register [13H]. Total load capacitance

is determined by the formula:

CapLoad = (CL– CBRD – CCHIP)/0.09375 pF

where:

• CL = specified load capacitance of your crystal.

• CBRD = the total board capacitance, due to external capac-

itors and board trace capacitance. In CyClocksRT, this value

defaults to 2 pF.

• CCHIP = 6 pF.

• 0.09375 pF = the step resolution available due to the 8-bit

register.

In CyclocksRT, only the crystal capacitance (CL) is specified.

CCHIP is set to 6 pF, and CBRD defaults to 2 pF. If your board

capacitance is higher or lower than 2 pF, the formula above

can be used to calculate a new CapLoad value and

programmed into register 13H.

In CyClocksRT, enter the crystal capacitance (CL). The value

of CapLoad will be determined automatically and programmed

into the CY22150. Through the SDAT and SCLK pins, the

value can be adjusted up or down if your board capacitance is

greater or less than 2 pF. For an external clock source,

CapLoad defaults to 0. See Table 5 for CapLoad bit locations

and values.

The input load capacitors are placed on the CY22150 die to

reduce external component cost. These capacitors are true

parallel-plate capacitors, designed to reduce the frequency

shift that occurs when non-linear load capacitance is affected

by load, bias, supply and temperature changes.

PLL Frequency, Q Counter [42H(6..0)]

The first counter is known as the Q counter. The Q counter

divides REF by its calculated value. Q is a 7 bit divider with a

maximum value of 127 and minimum value of 0. The primary

value of Q is determined by 7 bits in register 42H (6..0), but 2

is added to this register value to achieve the total Q, or Qtotal.

Qtotal is defined by the formula:

Qtotal = Q + 2

The minimum value of Qtotal is 2. The maximum value of Qtotal

is 129. Register 42H is defined in the table.

Stable operation of the CY22150 cannot be guaranteed if

REF/Qtotal falls below 250 kHz. Qtotal bit locations and values

are defined in Table 6.

PLL Frequency, P Counter [40H(1..0)],

[41H(7..0)], [42H(7)

The next counter definition is the P (product) counter. The P

counter is multiplied with the (REF/Qtotal) value to achieve the

VCO frequency. The product counter, defined as Ptotal, is

made up of two internal variables, PB and PO. The formula for

calculating Ptotal is:

Ptotal = (2(PB + 4) + PO).

PB is a 10-bit variable, defined by registers 40H(1:0) and

41H(7:0). The 2 LSBs of register 40H are the two MSBs of

variable PB. Bits 4..2 of register 40H are used to determine the

charge pump settings (see Section 5). The 3 MSBs of register

40H are preset and reserved and cannot be changed. PO is a

single bit variable, defined in register 42H(7). This allows for

odd numbers in Ptotal.

The remaining seven bits of 42H are used to define the Q

counter, as shown in Table 6.

The minimum value of Ptotal is 8. The maximum value of Ptotal

is 2055. To achieve the minimum value of Ptotal, PB and PO

should both be programmed to 0. To achieve the maximum

value of Ptotal, PB should be programmed to 1023, and PO

should be programmed to 1.

Stable operation of the CY22150 cannot be guaranteed if the

value of (Ptotal*(REF/Qtotal)) is above 400 MHz or below

100 MHz. Registers 40H, 41H and 42H are defined in Table 7.

PLL Post Divider Options [OCH(7..0)], [47H(7..0)]

The output of the VCO is routed through two independent

muxes, then to two divider banks to determine the final clock

output frequency. The mux determines if the clock signal

feeding into the divider banks is the calculated VCO frequency

or REF. There are two select muxes (DIV1SRC and DIV2SRC)

and two divider banks (Divider Bank 1 and Divider Bank 2)

used to determine this clock signal. The clock signal passing

through DIV1SRC and DIV2SRC is referred to as DIV1CLK

and DIV2CLK, respectively.

The divider banks have 4 unique divider options available: /2,

/3, /4, and /DIVxN. DIVxN is a variable that can be indepen-

dently programmed (DIV1N and DIV2N) for each of the two

divider banks. The minimum value of DIVxN is 4. The

maximum value of DIVxN is 127. A value of DIVxN below 4 is

not guaranteed to work properly.

DIV1SRC is a single bit variable, controlled by register OCH.

The remaining seven bits of register OCH determine the value

of post divider DIV1N.

DIV2SRC is a single bit variable, controlled by register 47H.

The remaining seven bits of register 47H determine the value

of post divider DIV2N.

Register OCH and 47H are defined in Table 8.

Charge Pump Settings [40H(2..0)]

The correct pump setting is important for PLL stability. Charge

pump settings are controlled by bits (4..2) of register 40H, and

are dependent on internal variable PB (see “PLL Frequency,

P Counter[40H(1..0)], [41H(7..0)], [42H(7)]”). Table 9 summa-

rizes the proper charge pump settings, based on Ptotal.

See Table 10 for register 40H bit locations and values.

Table 5. Input Load Capacitor Register Bit Settings

Address

D7

D6

D5

D4

D3

D2

D1

D0

13H

CapLoad(7) CapLoad(6) CapLoad(5) CapLoad(4) CapLoad(3) CapLoad(2) CapLoad(1) CapLoad(0)

Document #: 38-07104 Rev. *F

Page 5 of 13

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