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CRC16 Datasheet

Part Manufacturer Description PDF Type
CRC160J Cornell Dubilier Capacitor: 16PF: 2K: C0G: Original
CRC-16 and CRC-32 Cypress Semiconductor Parallel Cyclic Redundancy Check (CRC) for HOTLink Original

CRC16

Catalog Datasheet MFG & Type PDF Document Tags

CRC-CCITT 0xFFFF

Abstract: CRC-16-CCIT CRC16_WritePolynomial the CRC16 seed A, CRC_CCITT_SEED CRC16_WriteSeed ;LSB ;MSB ;LSB ;MSB , (void) { // stop the CRC16 user module CRC16_Stop(); // load the CCITT polynomial CRC16_WriteSeed(CRC_CCITT_SEED); // start the CRC16 CRC16_Start , the CRC16 API. CRC16_MSB: Control Register CR0 Bit Value 7 0 6 0 5 0 4 0 3 0 2 0 1 0 0 0 CRC16_LSB , two consecutive digital blocks named CRC16_LSB and CRC16_MSB. The Polynomial, Shift, Seed, and Control
Cypress Semiconductor
Original
CRC-CCITT 0xFFFF CRC-16-CCIT crc generator CY8C29/27/24/22 CY8C26/25 CRC-16

CRC-16

Abstract: CRC16 DATA_TEMP1 CRC16_HI,W DATAJTEMP1 DATA_TEMP1,7 No Xorwf '00000010 'b CRC16_LO '01000000 'b CRC16_HI DATA_TEMP0 DATA_TEMP1 CRC16_LO CRC16_HI NUMBER_BITS More Rotates Store data in temporary register Set counter for 8 , follows the CRC16J-II register. If the receiving system computes a CRC-16 value from all the data bytes and the attached shift register (CRC16_HI and CRC16 LO), then the resulting CRC-16 code is OOOOh. Any , position Rotate XOR of input into CRC16_L0 Shift CRC16 register Shift CRC16 register Count out 8 data bits
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OCR Scan
crc-16 implementation PIC16C63

CRC16

Abstract: CRC-16 pin PROTOCOL 7.1 Error check (CRC-16) 7.2 Master to one slave communication frame 7.3 Broadcast , 1 Data n Error check (CRC-16) (low byte) 1 Error check (CRC-16) (high byte) 1 , greater than 3,5 T.U. (Time Unit = time necessary to transmit one character). 7.1 ERROR CHECK (CRC-16) The CRC-16 value is calculated by the transmitting device, this value is appended to the message. The receiving device recalculates a CRC-16 and compares the calculated value to the received value
-
Original
CRC-16 pin modbus RS485 A001 ST01 ST57-01C-

mmc EXT_CSD

Abstract: EXT_CSD . CRC16 checksum is also ignored by the card and host. Table : 1-bit Bus Testing Pattern Data line Data pattern sent by the host Reserved pattern sent by the card 0,10xxxxxxxxxxxx,[CRC16],1 0,01000000,[CRC16],1 Start bit defines beginning of pattern 0,00000000,[CRC16],1 No data pattern sent 0,00000000,[CRC16],1 No data pattern sent DATA3 0,00000000,[CRC16],1 No data pattern sent DATA4 0,00000000,[CRC16],1 No data pattern sent DATA5 0,00000000,[CRC16],1
Samsung Electronics
Original
ACMD41 CMD06 CMD19 CMD14 CMD08 mmc EXT_CSD EXT_CSD S_CMD_SET cmd6 sd card CMD01 CMD02 CMD03 CMD07

codes for -16 bits crc implementation

Abstract: CRC-16 Algorithm for Packetized WLAN Protocols on the HFA3824 Application Note October 1998 AN9701.1 Authors: Al Petrick, John Fakatselis Introduction [ /Title (an970 1) /Subject (CRC16 Algorithm for , commonly the CRC. The fixed binary number is the divisor commonly called the polynomial. The CRC-16 , Convergence Protocol). The CCITT CRC-16 is a standardized algorithm with origins to the CCITT standards body , zeros. This initial condition needs to be avoided. CRC16 Protected Fields in the PLCP Header The
Intersil
Original
codes for -16 bits crc implementation HFA38 IEEE802

CRC8 and crc16

Abstract: schema eeprom {CRC16,start,seed} Start CRC16 calculation by first setting the CRC16 to the provided 'seed' , 'check' command is found. {CRC16,check,value} Check the CRC16 calculated value to make sure it equals the provided hex 'value'. If it is not then this is a failure. The CRC16 calculation can be , calculation until the 'check' command is found. {CRC16,check,value} Check the CRC8 calculated value to , > {M} {CRC16,start,0} 0F {A0} {A1} {D0} {D1} {D2} {D3} {D4} {D5} {D6} {D7
Dallas Semiconductor
Original
DS2430A CRC8 and crc16 schema eeprom CRC8 IEEE 1451.4 DS18B20 SCHEMA

CRC-16-CCIT

Abstract: CRC16_LSB and CRC16_MSB. The Polynomial, Shift, Seed, and Control registers of each CRC16 block correspond , register is composed of the CRC16_MSB Polynomial register and the CRC16_LSB Polynomial register. The CRC16 , CRC16_WritePolynomial the CRC16 seed A, CRC_CCITT_SEED CRC16_WriteSeed ;LSB ;MSB ;LSB ;MSB , (void) { // stop the CRC16 user module CRC16_Stop(); // load the CCITT polynomial CRC16_WriteSeed(CRC_CCITT_SEED); // start the CRC16 CRC16_Start
Cypress Semiconductor
Original
CY8C29/27/24/22/21 CY8C23 CY8CLED02/04/08/16 CYWUSB6953

CRC-16 ccitt

Abstract: CRC-16 CRC-16 Algorithm for Packetized WLAN Protocols on the HFA3824 TM Application Note October , divisor commonly called the polynomial. The CRC-16 algorithm is specified by the IEEE802.11 for use in the direct sequence physical layer PLCP (Physical Layer Convergence Protocol). The CCITT CRC-16 is a , calculating the CRC is binary modulo 2 arithmetic, and typically implemented with an XOR function. CRC16 , seeded with a value of all zeros. This initial condition needs to be avoided. CRC16 Protected Fields
Intersil
Original
CRC-16 ccitt crc-calculator XOR Gates 1-888-INTERSIL

RX-UHF-00C01-03

Abstract: 60H-6FH 70h-7Fh 60h-6Fh 40h-4Fh EPC[79:64] EPC[95:80] 10h-1Fh PROTOCOL CONTROL BITS 00h-0Fh CRC-16 , > 44 Yes CRC-16 Reserved for future use 1011 - - NAK 11000000 8 Yes Unique command length Req_RN 11000001 40 Yes CRC-16 Read 11000010 > 57 Yes CRC-16 Write Kill 11000011 11000100 > 58 59 Yes Yes CRC-16 CRC-16 Protection - Lock 11000101 60 Yes CRC-16 Access 11000110 56 Yes CRC-16
Texas Instruments
Original
RX-UHF-00C01-03 60H-6FH 40H-4FH 00c01 EPC-31 50H-5FH

CRC-16 ccitt

Abstract: CRC-16 Harris Semiconductor No. AN9701 Harris Wireless Products February 1997 CRC-16 Algorithm , divisor commonly called the polynomial. The CRC-16 algorithm is specified by the IEEE802.11 for use in the direct sequence physical layer PLCP (Physical Layer Convergence Protocol). The CCITT CRC-16 is a , the CRC is binary modulo 2 arithmetic, and typically implemented with an XOR function. CRC16 Protected Fields in the PLCP Header The CCITT CRC-16 is calculated bit serially in the HSP3824 protecting
Harris Semiconductor
Original
CRC calculator crc 16 CCITT ISO9000 1-800-4-HARRIS

mitsubishi receiver

Abstract: Handshake Packet EOP DATA CRC16 EOP ACK Busy NAK STALL EOP D1 , ENDP CRC5 EOP DATA CRC16 EOP Handshake D0:B0,B7 D0:B0, ,B7 D1 , Data Packet SYNC DATA ( 0 64 bytes ) 0 PID:Data0/1 ACK NAK STALL CRC16 ACK , STALL ACK CRC16 NAK EOP STALL Handshake Packet SYNC PID: PID: EOP DATA , bytes ) 0 CRC16 EOP Handshake Packet Idle Code: USB Ver: A5 Page: 10 of 22
Mitsubishi
Original
mitsubishi receiver

DS2433

Abstract: schema eeprom reading all 0's such as 0x00 {FF} Success is reading all 1's such as 0xFF {CRC16,start,seed} Start CRC16 calculation by first setting the CRC16 to the provided 'seed' represented in hex notation , . {CRC16,check,value} Check the CRC16 calculated value to make sure it equals the provided hex 'value'. If it is not then this is a failure. The CRC16 calculation can be stopped after the check. {CRC8 , command is found. {CRC16,check,value} Check the CRC8 calculated value to make sure it equals the
Maxim Integrated Products
Original
DS2409 DS1920 DS2406 DS2433 ds2433 a3 DS18S20 T DS18B20 application note DS18S20 DS2506 DS2431

AN9616

Abstract: CR10 DESCRIPTION 0 0 0 Preamble with SFD Field. 1 0 1 Preamble with SFD, and CRC16. 2 1 0 Preamble with SFD, Length, and CRC16. 3 1 1 Full preamble and header. Bit 2 , /disable the CRC16 check on the received Header. This control bit is used to select the origination of , SFD, field 01 SFD and CRC16, fields 10 SFD, Length and CRC16, fields 11 SFD, Signal, Length and CRC16, fields Rate Divisor CR3 These control bits are used to select the divide ratio
Harris Semiconductor
Original
AN9616 CR10 CR14 CR16 RSSI energy RXCRC16

XOR Gates

Abstract: codes for -16 bits crc implementation Sem iconductor CRC-16 Algorithm for Packetized WLAN Protocols on the HFA3824 A p p lic a t io n , binary number is the divisor commonly called the polynomial. The CRC-16 algorithm is specified by the , CCITT CRC-16 is a standardized algorithm with origins to the CCITT standards body. The polynomial for , condition needs to be avoided. CRC16 Protected Fields in the PLCP Header T^e CCITT CRC-16 is calculated , header is transmitted a CRC-16 checksum calculated and appended to the length field. The Signal, Service
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OCR Scan
crc16 ccitt CRC-16POLYNOMIAL CCITTCRC-16

12TH

Abstract: DS1990A byte and Current _CRC16_Lo for the current New_CRC16_Hi = CRC16_Tabhi[I] for I=0 to 255; where I = , locating the new low order byte CRC value (New_CRC16_Lo) is given as: New_CRC16_Lo = (CRC16_Tablo[I , ; ; all done with calculation crc16_tablo: 030698 11/15 APPLICATION NOTE 27 db db db db , , 085h, 045h, 087h, 047h, 046h, 086h 082h, 042h, 043h, 083h, 041h, 081h, 080h, 040h crc16_tabhi , include the CRC­16 and the CRC­CCITT, each of which computes a 16­bit CRC value. The Dallas
Dallas Semiconductor
Original
DS1990A DS1991 12TH ABCDEFGH01234567 ABCDEFG0123456 AB01X ABCDEFGH0123456

CRC-16 ccitt

Abstract: CRC-16 CRC-16 Algorithm for Packetized WLAN Protocols on the HFA3824 Application Note October 1998 , divisor commonly called the polynomial. The CRC-16 algorithm is specified by the IEEE802.11 for use in the direct sequence physical layer PLCP (Physical Layer Convergence Protocol). The CCITT CRC-16 is a , the CRC is binary modulo 2 arithmetic, and typically implemented with an XOR function. TM CRC16 , seeded with a value of all zeros. This initial condition needs to be avoided. CRC16 Protected Fields
Intersil
Original
polynomial calculation

CRC-32 LFSR

Abstract: CRC-16 and CRC-32 most common CRC CRC-16 and CRC-32 codes (CRC-16 and CRC-32) used in highspeed com In , algorithm for cal culating CRC-16 one byte at a time and for calcu lating CRC-32 two bytes at a time is , Some systems go to great lengths to detect data cor CRC-16 ruption. Parity is sometimes used to provide a small CRC-16 is 16 bits long and CRC-32 is 32 bits long. measure of robustness by , ap 16 CRC-16 has a generator polynomial G(x) = x x x 15 23 + x + x 2 32 + 1
Cypress Semiconductor
Original
CY7B923 CY7B933 CY7C384A-1JC CY7C384 COM0009-0394 CRC-32 LFSR CRC 32 cyclic redundancy check crc32 shift register 4050
Abstract: (New_CRC16_Lo) is given as: New_CRC16_Lo = (CRC16_Tablo[I]) EXOR (Current. CRC16_Hi) for I = 0 to 255; where I = , : New_CRC16_Hi = CRC16_Tabhi[I] for I = 0 to 255; where I = (Current_CRC16_Lo) EXOR (Input byte) The equation to , Keywords: 1-wire devices, DOW CRC, CRC-16, 16-bit 8-bit CRC, ¡Button CRC, cyclic redundancy check, ROM ID , ory o f the devices. Both the DOW CRC and the CRC-16 are also generated in hardware o f select 1 , computed. CRC codes that are commonly used in digital data communications include the CRC-16 and the -
OCR Scan
DS1904 DS1963L DS1963S DS1971 DS1973 DS1982

CRC-16

Abstract: CRC16 :80] 10h-1Fh PROTOCOL CONTROL BITS CRC-16 00h-0Fh LOCK_BITS[9:0] 40h-4Fh KILL , -5 QueryAdjust 1001 9 Yes Unique command length Select 1010 > 44 Yes CRC-16 , 11000001 40 Yes CRC-16 Read 11000010 > 57 Yes CRC-16 Write Kill 11000011 11000100 > 58 59 Yes Yes CRC-16 CRC-16 Lock 11000101 60 Yes CRC-16 Protection - Access 11000110 56 Yes CRC-16 BlockWrite 11000111 > 57 No CRC-16
Texas Instruments
Original
20H-2FH RI-UHF-00C02-04

001H

Abstract: CRC-16 (New_CRC16_Hi) is given as: New_CRC16_Hi = CRC16_Tabhi[I] for I = 0 to 255; where I = (Current_CRC16_Lo) EXOR , order byte CRC value (New_CRC16_Lo) is given as: New_CRC16_Lo = (CRC16_Tablo[I]) EXOR (Current_ CRC16_Hi) for I = 0 to 255; where I = (Current_CRC16_Lo) EXOR (Input byte) An example of how this method , pop dph ; ret ; all done with calculation crc16_tablo: db 000h, 0c1h, 081h, 040h, 001h, 0c0h, 080h , 001h, db 000h, db 000h, db 001h, crc16_tabhi: db 000h, db 0c6h, db 0cch, db 00ah, db 0d8h, db
Maxim Integrated Products
Original
001H volume 36 Appnote27 DS1992 DS1993 DS1995 DS1996 DS2401 DS2405
Abstract: PROTOCOL 7.1 Error check (CRC-16) 7.2 Master to one slave communication frame 7.3 Broadcast , 1 Data n Error check (CRC-16) (low byte) 1 Error check (CRC-16) (high byte) 1 , greater than 3,5 T.U. (Time Unit = time necessary to transmit one character). 7.1 ERROR CHECK (CRC-16) The CRC-16 value is calculated by the transmitting device, this value is appended to the message. The receiving device recalculates a CRC-16 and compares the calculated value to the received value Fujitsu
Original
DS411-00001-2 MB89R118C

TAG 8434

Abstract: transistor tag 8422 13. 16-Bit CRC Generator 16-Bit CRC Generator CRC16 v3.1 Copyright © 2002-2003. Cypress , The CRC16 User Module computes a 2- to 16-bit cyclical redundancy check (CRC) algorithm on an input serial data stream. The polynomial can be defined to implement CRC functions, such as the CRC-16 or CCITT , Seed Register 15 14 2 1 0 CRC16 Block Diagram September 7, 2004 1 User Module Data Sheet Functional Description The CRC16 User Module computes a 16-bit CRC algorithm with
NXP Semiconductors
Original
TAG 8434 transistor tag 8422 ICODE SLI-S ICS5401 ICODE SLI ICS53 ICS53/SL2 ICS54
Abstract: 13. 16-Bit CRC Generator 16-Bit CRC Generator Data Sheet CRC16 vX.Y Copyright © 2002-2008 , out The CRC16 User Module computes a 2- to 16-bit cyclical redundancy check (CRC) algorithm on an input serial data stream. The polynomial can be defined to implement CRC functions, such as the CRC-16 , Input Data Seed Register 15 14 2 1 0 CRC16 Block Diagram Functional Description The CRC16 User Module computes a 16-bit CRC algorithm with two consecutive digital blocks named Fujitsu
Original
DS04-33102-1E MB89R119 F0507

puls p-f2

Abstract: scada intouch reading all 0's such as 0x00 {FF} Success is reading all 1's such as 0xFF {CRC16,start,seed} Start CRC16 calculation by first setting the CRC16 to the provided 'seed' represented in hex notation , . {CRC16,check,value} Check the CRC16 calculated value to make sure it equals the provided hex 'value'. If it is not then this is a failure. The CRC16 calculation can be stopped after the check. {CRC8 , command is found. {CRC16,check,value} Check the CRC8 calculated value to make sure it equals the
Greegoo Electric
Original
EN9620 puls p-f2 scada intouch RVVP wire 100v40 220-6v three phase kilowatt-hour meter RS-485 AWG18
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