Renesas Electronics Field Programmable Gate Arrays (FPGA) 281

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Part	Manufacturer	Programmable IC Type	Grading Of Temperature	Form Of Terminal	No. of Terminals	Package Code	Package Shape	Package Body Material	No. of Logic Cells	Surface Mount	Technology Used	No. of Inputs	Nominal Supply Voltage (V)	Power Supplies (V)	Package Style (Meter)	Package Equivalence Code	Sub-Category	Pitch Of Terminal	Maximum Operating Temperature	Minimum Operating Temperature	Finishing Of Terminal Used	Position Of Terminal	JESD-30 Code	Qualification	JESD-609 Code	No. of Outputs
UPD66206(144LQFP)	Renesas Electronics
MG73NB20(QFP)	Renesas Electronics
UPD66204(208QFP)	Renesas Electronics
MG74NB42(QFP)	Renesas Electronics
UPD66206(160FPBGA)	Renesas Electronics
MG73NB42(QFP)	Renesas Electronics
UPD66202(208QFP)	Renesas Electronics
UPD66202(256PBGA)	Renesas Electronics
UPD66201(144LQFP)	Renesas Electronics
CX3072	Renesas Electronics
UPD66204(352ABGA)	Renesas Electronics
MG73NB22(QFP)	Renesas Electronics
MG74NB14(QFP)	Renesas Electronics
UPD66208(676PBGA)	Renesas Electronics
UPD66210(208FPBGA)	Renesas Electronics
MG73NB24(BGA)	Renesas Electronics
MG75NB08(QFP)	Renesas Electronics
CP20420CPGA155A-0M	Renesas Electronics	FPGA	Military	Pin/Peg	155	PGA	Square	Ceramic	3584	No	CMOS	122	5	5 V	Grid Array	PGA155,15X15	Field Programmable Gate Arrays	2.54 mm	125 °C (257 °F)	-55 °C (-67 °F)	Tin/Lead	Perpendicular	S-XPGA-P155	No	e0	122
MG74NB28(BGA)	Renesas Electronics
UPD66210(576ABGA)	Renesas Electronics
CP20420CQFP160A-0I	Renesas Electronics	FPGA	Industrial	Gull Wing	160	QFP	Square	Ceramic	3584	Yes	CMOS	130	5	5 V	Flatpack	QFP160,1.2SQ	Field Programmable Gate Arrays	.635 mm	85 °C (185 °F)	-40 °C (-40 °F)	Tin/Lead	Quad	S-XQFP-G160	No	e0	130
MG74NB18(QFP)	Renesas Electronics
UPD66210(256PBGA)	Renesas Electronics
CP21200CPGA299A-0I	Renesas Electronics	FPGA	Industrial	Pin/Peg	299	PGA		Ceramic	8960	No	CMOS	203	5	5 V	Grid Array	PGA299(UNSPEC)	Field Programmable Gate Arrays		85 °C (185 °F)	-40 °C (-40 °F)	Tin/Lead	Perpendicular		No	e0	203
MG74NB10(QFP)	Renesas Electronics
MG75NB20(BGA)	Renesas Electronics
MG74NB42(BGA)	Renesas Electronics
UPD66209(352ABGA)	Renesas Electronics
MG74NB16(BGA)	Renesas Electronics
MG74NB36(QFP)	Renesas Electronics
UPD66210(144LQFP)	Renesas Electronics
5962-96A0101V9X	Renesas Electronics																							Yes
MG73NB24(QFP)	Renesas Electronics
MG73NB40(QFP)	Renesas Electronics
MG75NB02(QFP)	Renesas Electronics
UPD66208(144LQFP)	Renesas Electronics
MG75NB30(QFP)	Renesas Electronics
MG75NB42(QFP)	Renesas Electronics
CP22000CPGA383A-0M	Renesas Electronics	FPGA	Military	Pin/Peg	383	PGA		Ceramic	14736	No	CMOS	270	5	5 V	Grid Array	PGA383(UNSPEC)	Field Programmable Gate Arrays		125 °C (257 °F)	-55 °C (-67 °F)	Tin/Lead	Perpendicular		No	e0	270
UPD65676GN	Renesas Electronics	FPGA	Industrial	Gull Wing	184	QFP	Square	Plastic/Epoxy		Yes	CMOS	448	5	5 V	Flatpack	QFP184,1.4SQ	Field Programmable Gate Arrays	.635 mm	85 °C (185 °F)	-40 °C (-40 °F)		Quad	S-PQFP-G184	No		448
MG74NB06(BGA)	Renesas Electronics
CX3141	Renesas Electronics
MG75NB28(QFP)	Renesas Electronics
MG73NB34(BGA)	Renesas Electronics
CP20220PLCC84A-0I	Renesas Electronics	FPGA	Industrial	J Bend	84	QCCJ	Square	Plastic/Epoxy	1896	Yes	CMOS	91	5	5 V	Chip Carrier	LDCC84,1.2SQ	Field Programmable Gate Arrays	1.27 mm	85 °C (185 °F)	-40 °C (-40 °F)	Tin/Lead	Quad	S-PQCC-J84	No	e0	91
MG73NB38(QFP)	Renesas Electronics
CX3303	Renesas Electronics
MG75NB40(QFP)	Renesas Electronics

Field Programmable Gate Arrays (FPGA)

Field Programmable Gate Arrays (FPGAs) are digital integrated circuits that are programmable by the user to perform specific logic functions. They consist of a matrix of configurable logic blocks (CLBs) that can be programmed to perform any digital function, as well as programmable interconnects that allow these blocks to be connected in any way the designer wishes. This makes FPGAs highly versatile and customizable, and they are often used in applications where a high degree of flexibility and performance is required.

FPGAs are programmed using specialized software tools that allow the designer to specify the logic functions and interconnects that are required for a particular application. This process is known as synthesis and involves translating the high-level design into a format that can be implemented on the FPGA hardware. The resulting configuration data is then loaded onto the FPGA, allowing it to perform the desired logic functions.

FPGAs are used in a wide range of applications, including digital signal processing, computer networking, and high-performance computing. They offer a number of advantages over traditional fixed-function digital circuits, including the ability to be reprogrammed in the field, lower development costs, and faster time-to-market. However, they also have some disadvantages, including higher power consumption and lower performance compared to custom-designed digital circuits.