CY7B994V-5AC Cypress Semiconductor Corp, CY7B994V-5AC Datasheet - Page 7

CY7B994V-5AC

Manufacturer Part Number

CY7B994V-5AC

Description

Manufacturer

Cypress Semiconductor Corp

Type

Zero Delay PLL Clock Bufferr

Datasheet

1.CY7B994V-5AC.pdf (15 pages)

Specifications of CY7B994V-5AC

Number Of Elements

Supply Current

250mA

Pll Input Freq (min)

24MHz

Pll Input Freq (max)

200MHz

Operating Supply Voltage (typ)

3.3V

Operating Temp Range

0C to 70C

Package Type

TQFP

Output Frequency Range

24 to 200MHz

Operating Supply Voltage (min)

2.97V

Operating Supply Voltage (max)

3.63V

Operating Temperature Classification

Commercial

Pin Count

100

Lead Free Status / Rohs Status

Not Compliant

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Document #: 38-07127 Rev. *F

INV3 Pin Function

Bank3 has signal invert capability. The four outputs of Bank3

will act as two pairs of complementary outputs when the INV3

pin is driven LOW. In complementary output mode, 3QA0 and

3QB0 are non-inverting; 3QA1and 3QB1 are inverting outputs.

All four outputs will be inverted when the INV3 pin is driven

HIGH. When the INV3 pin is left in MID, the outputs will not

invert. Inversion of the outputs are independent of the skew

and divide functions. Therefore, clock outputs of Bank3 can be

inverted, divided, and skewed at the same time.

Lock Detect Output Description

The LOCK detect output indicates the lock condition of the

integrated PLL. Lock detection is accomplished by comparing

the phase difference between the reference and feedback

inputs. Phase error is declared when the phase difference

between the two inputs is greater than the specified device

propagation delay limit (t

When in the locked state, after four or more consecutive

feedback clock cycles with phase-errors, the LOCK output will

be forced LOW to indicate out-of-lock state.

When in the out-of-lock state, 32 consecutive phase-errorless

feedback clock cycles are required to allow the LOCK output

to indicate lock condition (LOCK = HIGH).

If the feedback clock is removed after LOCK has gone HIGH,

a “Watchdog” circuit is implemented to indicate the out-of-lock

condition after a time-out period by deasserting LOCK LOW.

This time out period is based upon a divided down reference

clock.

This assumes that there is activity on the selected REF input.

If there is no activity on the selected REF input then the LOCK

detect pin may not accurately reflect the state of the internal

PLL.

Factory Test Mode Description

The device will enter factory test mode when the

OUTPUT_MODE is driven to MID. In factory test mode, the

device will operate with its internal PLL disconnected; input

level supplied to the reference input will be used in place of the

PLL output. In TEST mode the selected FB input(s) must be

tied LOW. All functions of the device are still operational in

factory test mode except the internal PLL and output bank

disables. The OUTPUT_MODE input is designed to be a static

input. Dynamically toggling this input from LOW to HIGH may

temporarily cause the device to go into factory test mode

(when passing through the MID state).

Factory Test Reset

When in factory test mode (OUTPUT_MODE = MID), the

device can be reset to a deterministic state by driving the DIS4

input HIGH. When the DIS4 input is driven HIGH in factory test

mode, all clock outputs will go to HI-Z; after the selected

reference clock pin has five positive transitions, all the internal

finite state machines (FSM) will be set to a deterministic state.

The deterministic state of the state machines will depend on

the configurations of the divide selects, skew selects, and

frequency select input. All clock outputs will stay in

high-impedance mode and all FSMs will stay in the determin-

istic state until DIS4 is deasserted. When DIS4 is deasserted

(with OUTPUT_MODE still at MID), the device will re-enter

factory test mode.

Safe Operating Zone

Figure 2 illustrates the operating condition at which the device

does not exceed its allowable maximum junction temperature

of 150°C. Figure 2 shows the maximum number of outputs that

can operate at 185 MHz (with 25-pF load and no air flow) or

200 MHz (with 10-pF load and no air flow) at various ambient

temperatures. At the limit line, all other outputs are configured

to divide-by-two (i.e., operating at 92.5 MHz) or lower

frequencies. The device will operate below maximum

allowable junction temperature of 150°C when its configu-

ration (with the specified constraints) falls within the shaded

region (safe operating zone). Figure 2 shows that at 85°C, the

maximum number of outputs that can operate at 200 MHz is

6; and at 70°C, the maximum number of outputs that can

operate at 185 MHz is 16 (with 25-pF load and 0-m/s air flow).

100

Figure 2. Typical Safe Operating Zone

Num ber of Outputs at 185 MHz

Typical Safe Operating Zone

(25-pF Load, 0-m /s air flow )

Safe Operating Zone

RoboClock

CY7B993V

CY7B994V

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CY7B994V-5AC Cypress Semiconductor Corp, CY7B994V-5AC Datasheet - Page 7

CY7B994V-5AC

Specifications of CY7B994V-5AC

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