CY39200V388-83MGC Cypress Semiconductor Corp, CY39200V388-83MGC Datasheet - Page 8

CY39200V388-83MGC

Manufacturer Part Number

CY39200V388-83MGC

Description

Manufacturer

Cypress Semiconductor Corp

Datasheet

1.CY39200V388-83MGC.pdf (86 pages)

Specifications of CY39200V388-83MGC

Family Name

Delta39K

Memory Type

SRAM

# Macrocells

3072

Number Of Usable Gates

200000

Propagation Delay Time

15ns

# I/os (max)

294

Operating Supply Voltage (typ)

2.5/3.3V

Ram Bits

491520

In System Programmable

Yes

Operating Supply Voltage (min)

2.3V

Operating Supply Voltage (max)

3.6V

Operating Temp Range

0C to 70C

Operating Temperature Classification

Commercial

Mounting

Surface Mount

Pin Count

388

Package Type

BGA

Lead Free Status / Rohs Status

Not Compliant

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Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

CY39200V388-83MGC

Manufacturer:

IDT

Quantity:

698

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The clocks for each port of the Dual-Port configuration are

selected from four global clocks and two local clocks. One

local clock is sourced from the horizontal channel and the

other from the vertical channel. The data outputs of the dual-

port memory can also be registered. Clocks for the output

registers are also selected from four global clocks and two

local clocks. One clock polarity mux per port allows the use of

true or complement polarity for input and output clocking

purposes.

Arbitration

The Dual-Port configuration of the Channel Memory Block

provides arbitration when both ports access the same address

at the same time. Depending on the memory operation being

attempted, one port always gets priority. See Table 2 for

details on which port gets priority for Read and Write opera-

tions. An active-LOW “Address Match” signal is generated

when an address collision occurs.

Table 2. Arbitration Result: Address Match Signal

Becomes Active

FIFO (Channel Memory) Configuration

The channel memory blocks are also configurable as

synchronous FIFO RAM. In the FIFO mode of operation, the

channel memory block supports all normal FIFO operations

without the use of any general-purpose logic resources in the

device.

Document #: 38-03039 Rev. *I

Port A Port B

Read

Write

Read

Write

Read No arbitration

Read Port A gets

Write

required

priority

Port B gets

priority

Port A gets

priority

Arbitration

Result of

Both ports read at the

same time

If Port B requests first then

it will read the current

data. The output will then

change to the newly

written data by Port A

If Port A requests first then

it will read the current

data. The output will then

change to the newly

written data by Port B

Port B is blocked until Port

A is finished writing

Comment

The FIFO block contains all of the necessary FIFO flag logic,

including the Read and Write address pointers. The FIFO flags

include an empty/full flag (EF), half-full flag (HF), and program-

mable almost-empty/full (PAEF) flag output. The FIFO config-

uration has the ability to perform simultaneous Read and Write

operations using two separate clocks. These clocks may be

tied together for a single operation or may run independently

for asynchronous Read/Write (with regard to each other) appli-

cations. The data and control inputs to the FIFO block are

driven from the horizontal or vertical routing channels. The

data and flag outputs are driven onto dedicated routing tracks

in both the horizontal and vertical routing channels. This allows

the FIFO blocks to be expanded by using multiple FIFO blocks

on the same horizontal or vertical routing channel without any

speed penalty.

In FIFO mode, the Write and Read ports are controlled by

separate clock and enable signals. The clocks for each port

are selected from four global clocks and two local clocks.

One local clock is sourced from the horizontal channel and the

other from the vertical channel. The data outputs from the

Read port of the FIFO can also be registered. One clock

polarity mux per port allows using true or complement polarity

for Read and Write operations. The Write operation is

controlled by the clock and the Write enable pin. The Read

operation is controlled by the clock and the Read enable pin.

The enable pins can be sourced from horizontal or vertical

channels.

Channel Memory Initialization

The channel memory powers up in an undefined state, but is

set to a user-defined known state during configuration. To facil-

itate the use of look-up-table (LUT) logic and ROM applica-

tions, the channel memory blocks can be initialized with a

given set of data when the device is configured at power up.

For LUT and ROM applications, the user cannot write to

memory blocks.

Channel Memory Routing Interface

Similar to LBC outputs, the channel memory blocks feature

dedicated tracks in the horizontal and vertical routing channels

for the data outputs and the flag outputs, as shown in

Figure 6. This allows the channel memory blocks to be

expanded easily. These dedicated lines can be routed to I/O

pins as chip outputs or to other logic block clusters to be used

in logic equations.

Delta39K™ ISR™

CPLD Family

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CY39200V388-83MGC Cypress Semiconductor Corp, CY39200V388-83MGC Datasheet - Page 8

CY39200V388-83MGC

Specifications of CY39200V388-83MGC

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