TL39X-018-0833中文资料

W39V080A Data Sheet1M × 8 CMOS FLASH MEMORYWITH LPC INTERFACE Table of Contents-1.GENERAL DESCRIPTION (3)2.FEATURES (3)3.PIN CONFIGURATIONS (4)4.BLOCK DIAGRAM (4)5.PIN DESCRIPTION (4)6.FUNCTIONAL DESCRIPTION (5)6.1Interface Mode Selection and Description (5)6.2Read (Write) Mode (5)6.3Reset Operation (5)6.4Boot Block Operation and Hardware Protection at Initial- #TBL & #WP (5)6.5Sector Erase Command (6)6.6Program Operation (6)6.7Dual BIOS (6)6.8Hardware Data Protection (6)6.9Write Operation Status (7)7.TABLE OF OPERATING MODES (10)7.1Operating Mode Selection - Programmer Mode (10)7.2Operating Mode Selection - LPC Mode (10)7.3Standard LPC Memory Cycle Definition (10)8.TABLE OF COMMAND DEFINITION (11)8.1Embedded Programming Algorithm (12)8.2Embedded Erase Algorithm (13)8.3Embedded #Data Polling Algorithm (14)8.4Embedded Toggle Bit Algorithm (15)8.5Software Product Identification and Boot Block Lockout Detection Acquisition Flow..169.DC CHARACTERISTICS (17)9.1Absolute Maximum Ratings (17)9.2Programmer interface Mode DC Operating Characteristics (17)9.3LPC interface Mode DC Operating Characteristics (18)9.4Power-up Timing (18)10.CAPACITANCE (18)11.PROGRAMMER INTERFACE MODE AC CHARACTERISTICS (19)Publication Release Date: Dec. 28, 2005W39V080A11.1AC Test Conditions (19)11.2AC Test Load and Waveform (19)11.3Read Cycle Timing Parameters (20)11.4Write Cycle Timing Parameters (20)11.5Data Polling and Toggle Bit Timing Parameters (20)12.TIMING WAVEFORMS FOR PROGRAMMER INTERFACE MODE (21)12.1Read Cycle Timing Diagram (21)12.2Write Cycle Timing Diagram (21)12.3Program Cycle Timing Diagram (22)12.4#DATA Polling Timing Diagram (22)12.5Toggle Bit Timing Diagram (23)12.6Sector Erase Timing Diagram (23)13.LPC INTERFACE MODE AC CHARACTERISTICS (24)13.1AC Test Conditions (24)13.2Read/Write Cycle Timing Parameters (24)13.3Reset Timing Parameters (24)14.TIMING WAVEFORMS FOR LPC INTERFACE MODE (25)14.1Read Cycle Timing Diagram (25)14.2Write Cycle Timing Diagram (25)14.3Program Cycle Timing Diagram (26)14.4#DATA Polling Timing Diagram (27)14.5Toggle Bit Timing Diagram (28)14.6Sector Erase Timing Diagram (29)14.7GPI Register/Product ID Readout Timing Diagram (30)14.8Reset Timing Diagram (30)15.ORDERING INFORMATION (31)16.HOW TO READ THE TOP MARKING (31)17.PACKAGE DIMENSIONS (32)17.132L PLCC (32)17.232L STSOP (8x14mm) (32)17.340L TSOP (10 mm x 20 mm) (33)18.VERSION HISTORY (34)W39V080APublication Release Date: Dec. 28, 20051. GENERAL DESCRIPTIONThe W39V080A is an 8-megabit, 3.3-volt only CMOS flash memory organized as 1M × 8 bits. For flexible erase capability, the 8Mbits of data are divided into 16 uniform sectors of 64 Kbytes. The device can be programmed and erased in-system with a standard 3.3V power supply. A 12-volt VPP is required for accelerated program. The unique cell architecture of the W39V080A results in fast program/erase operations with extremely low current consumption. This device can operate at two modes, Programmer bus interface mode and LPC bus interface mode. As in the Programmer interface mode, it acts like the traditional flash but with a multiplexed address inputs. But in the LPC interface mode, this device complies with the Intel LPC specification. The device can also be programmed and erased using standard EPROM programmers.2. FEATURESy Single 3.3-volt operations: − 3.3-volt Read − 3.3-volt Erase − 3.3-volt Programy Fast Program operation:− VPP = 12V− Byte-by-Byte programming: 9 μS (typ.)y Fast Erase operation:− Sector erase 0.9 Sec. (tpy.) y Fast Read access time: Tkq 11 nS y Endurance: 30K cycles (typ.) y Twenty-year data retention y 16 Even sectors with 64K bytes y Any individual sector can be erased y Dual BIOS function− Full-chip Partition with 8M-bit or Dual-block Partition with 4M-bit y Hardware protection:− #TBL supports 64-Kbyte Boot Blockhardware protection− #WP supports the whole chip except Boot Block hardware protectiony Ready/#Busy output (RY/#BY)− Detect program or erase cycle completion y Hardware reset pin (#RESET)− Reset the internal state machine to the read mode y VPP input pin− Acceleration (ACC) function accelerates program timingy Low power consumption− Read Active current: 15 mA (typ. for LPC mode)y Automatic program and erase timing withinternal V PP generation y End of program or erase detection − Toggle bit − Data pollingy Latched address and data y TTL compatible I/Oy Available packages: 32L PLCC, 32L STSOP,40L TSOP(10 x 20 mm), 32L PLCC Lead free, 32L STSOP Lead free and 40L TSOP (10 x 20 mm) Lead freeW39V080A3. PIN CONFIGURATIONS4. BLOCK DIAGRAM5. PIN DESCRIPTIONINTERFACESYM.PGM LPCPIN NAMEMODE * *Interface Mode Selection #RESET * *Reset #INIT *Initialize#TBL *Top Boot Block Lock #WP *Write Protect CLK *CLK InputGPI[4:0] *General Purpose Inputs ID[3:0] *Identification InputsPull Down with Internal ResistorsLAD[3:0] *Address/Data Inputs #LFRAME *LPC Cycle InitialD/#F *Dual Bios/Full ChipPull Down with Internal Resistors U/#L *Upper 4M/Lower 4MPull Down with Internal ResistorsR/#C * Row/Column Select A[10:0]* Address Inputs DQ[7:0]* Data Inputs/Outputs #OE * Output Enable #WE * Write Enable RY/#BY * Ready/Busy VDD * *Power Supply VSS * *Ground RSV * *Reserve Pins NC * *No ConnectionW39V080A6. FUNCTIONAL DESCRIPTION6.1 Interface Mode Selection and DescriptionThis device can be operated in two interface modes, one is Programmer interface mode, and the other is LPC interface mode. The MODE pin of the device provides the control between these two interface modes. These interface modes need to be configured before power up or return from #RESET. When MODE pin is set to high position, the device is in the Programmer mode; while the MODE pin is set to low position, it is in the LPC mode. In Programmer mode, this device just behaves like traditional flash parts with 8 data lines. But the row and column address inputs are multiplexed. The row address is mapped to the higher internal address A[19:11]. And the column address is mapped to the lower internal address A[10:0]. For LPC mode, It complies with the LPC Interface Specification Revision 1.1 Through the LAD[3:0] and #LFRAME to communicate with the system chipset .6.2 Read (Write) ModeIn Programmer interface mode, the read(write) operation of the W39V080A is controlled by #OE (#WE). The #OE (#WE) is held low for the host to obtain (write) data from(to) the outputs(inputs). #OE is the output control and is used to gate data from the output pins. The data bus is in high impedance state when #OE is high. As in the LPC interface the “bit 1 of CYCLE TYPE+DIR” determines mode, the read or write. Refer to the timing waveforms for further details.6.3 Reset OperationThe #RESET input pin can be used in some application. When #RESET pin is at high state, the device is in normal operation mode. When #RESET pin is at low state, it will halt the device and all outputs will be at high impedance state. As the high state re-asserted to the #RESET pin, the device will return to read or standby mode, it depends on the control signals.6.4 Boot Block Operation and Hardware Protection at Initial- #TBL & #WPThere is a hardware method to protect the top boot block and other sectors. Before power on programmer, tie the #TBL pin to low state and then the top boot block will not be programmed/erased. If #WP pin is tied to low state before power on, the other sectors will not be programmed/erased.In order to detect whether the boot block feature is set on or not, users can perform software command sequence: enter the product identification mode (see Command Codes for Identification/Boot Block Lockout Detection for specific code), and then read from address FFFF2(hex). You can check the DQ2/DQ3 at the address FFFF2 to see whether the #TBL/#WP pin is in low or high state. If the DQ2 is “0”, it means the #TBL pin is tied to high state. In such condition, whether boot block can be programmed/erased or not will depend on software setting. On the other hand, if the DQ2 is “1”, it means the #TBL pin is tied to low state, then boot block is locked no matter how the software is set. Like the DQ2, the DQ3 inversely mirrors the #WP state. If the DQ3 is “0”, it means the #WP pin is in high state, then all the sectors except the boot block can be programmed/erased. On the other hand, if the DQ3 is “1”, then all the sectors except the boot block are programmed/erased inhibited.To return to normal operation, perform a three-byte command sequence (or an alternate single-byte command) to exit the identification mode. For the specific code, see Command Codes for Identification/Boot Block Lockout Detection.Publication Release Date: Dec. 28, 2005W39V080A6.5 Sector Erase CommandSector erase is a six-bus cycles operation. There are two "unlock" write cycles, followed by writing the "set-up" command. Two more "unlock" write cycles then follows by the Sector erase command. The Sector address (any address location within the desired Sector) is latched on the rising edge of R/#C in programmer mode, while the command (30H) is latched on the rising edge of #WE.Sector erase does not require the user to program the device prior to erase. When erasing a Sector, the remaining unselected sectors are not affected. The system is not required to provide any controls or timings during these operations.The automatic Sector erase begins after the erase command is completed, right from the rising edge of the #WE pulse for the last Sector erase command pulse and terminates when the data on DQ7, Data Polling, is "1" at which time the device returns to the read mode. Data Polling must be performed at an address within any of the sectors being erased.Refer to the Erase Command flow Chart using typical command strings and bus operations.6.6 Program OperationThe W39V080A is programmed on a byte-by-byte basis. Program operation can only change logical data "1" to logical data "0." The erase operation, which changed entire data in main memory and/or boot block from "0" to "1", is needed before programming.The program operation is initiated by a 4-byte command cycle (see Command Codes for Byte Programming). The device will internally enter the program operation immediately after the byte-program command is entered. The internal program timer will automatically time-out (9μS typ. - T BP) once it is completed and then return to normal read mode. Data polling and/or Toggle Bits can be used to detect end of program cycle.6.7 Dual BIOSThe W39V080A provides a solution for Dual-BIOS application. In LPC mode, when D/#F is low, the device functions as a full-chip partition of 8M-bit which address ranges from FFFFFh to 00000h with A[19:0]. If D/#F is driven high, the device functions as a dual-block partition that each block consists of 4M-bit. For dual-block partition, there is only one 4M-bit block, either upper or lower, can be accessed. The U/#L pin selects either upper or lower 4M-bit block and its address ranges from 7FFFFh to 00000h with A[19:0]. When U/#L is low, the lower 4M-bit block will be selected; while, U/#L is high, the upper 4M-bit block will be selected.6.8 Hardware Data ProtectionThe integrity of the data stored in the W39V080A is also hardware protected in the following ways:(1) Noise/Glitch Protection: A #WE pulse of less than 15 nS in duration will not initiate a write cycle.(2) V DD Power Up/Down Detection: The programming and read operation are inhibited when V DD isless than 2.0V typical.(3) Write Inhibit Mode: Forcing #OE low or #WE high will inhibit the write operation. This preventsinadvertent writes during power-up or power-down periods.W39V080APublication Release Date: Dec. 28, 20056.9 Write Operation StatusThe device provides several bits to determine the status of a program or erase operation: DQ5, DQ6, and DQ7. Each of DQ7 and DQ6 provides a method for determining whether a program or erase operation is complete or in progress. The device also offers a hardware-based output signal, RY/#BY in programmer mode, to determine whether an Embedded Program or Erase operation is in progress or has been completed.DQ7: #Data PollingThe #Data Polling bit, DQ7, indicates whether an Embedded Program or Erase algorithm is in progress or completed. Data Polling is valid after the rising edge of the final #WE pulse in the command sequence.During the Embedded Program algorithm, the device outputs on DQ7 and the complement of the data programmed to DQ7. Once the Embedded Program algorithm has completed, the device outputs the data programmed to DQ7. The system must provide the program address to read valid status information on DQ7. If a program address falls within a protected sector, #Data Polling on DQ7 is active for about 1 S, and then the device returns to the read mode.　During the Embedded Erase algorithm, #Data Polling produces “0” on DQ7. Once the Embedded Erase algorithm has completed, #Data Polling produces “1” on DQ7. An address within any of the sectors selected for erasure must be provided to read valid status information on DQ7.After an erase command sequence is written, if all sectors selected for erasing are protected, #Data Polling on DQ7 is active for about 100S, and then the device returns to the read mode. I f not all selected sectors are protected, the Embedded Erase algorithm erases the unprotected sectors, and ignores the selected sectors that are protected. However, if the system reads DQ7 at an address within a protected sector, the status may not be valid.Just before the completion of an Embedded Program or Erase operation, DQ7 may change asynchronously with DQ0-DQ6 while Output Enable (#OE) is set to low. That is, the device may change from providing status information to valid data on DQ7. Depending on when it samples the DQ7 output, the system may read the status or valid data. Even if the device has completed the program or erase operation and DQ7 has valid data, the data outputs on DQ0-DQ6 may be still invalid. Valid data on DQ7-DQ0 will appear on successive read cycles.RY/#BY: Ready/#BusyThe RY/#BY is a dedicated, open-drain output pin which indicates whether an Embedded Algorithm is in progress or complete. The RY/#BY status is valid after the rising edge of the final #WE pulse in the command sequence. Since RY/#BY is an open-drain output, several RY/#BY pins can be tied together in parallel with a pull-up resistor to VDD.When the output is low (Busy), the device is actively erasing or programming. When the output is high (Ready), the device is in the read mode or standby mode.DQ6: Toggle Bit IToggle Bit I on DQ6 indicates whether an Embedded Program or Erase algorithm is in progress or complete. Toggle Bit I may be read at any address, and is valid after the rising edge of the final #WE pulse in the command sequence (before the program or erase operation), and during the sector erase time-out.During an Embedded Program or Erase algorithm operation, successive read cycles to any address cause DQ6 to toggle. The system may use either #OE to control the read cycles. Once the operation has completed, DQ6 stops toggling.W39V080A After an erase command sequence is written, if all sectors selected for erasing are protected, DQ6 toggles for about 100 S, and then returns to reading array data. If not all selected sectors are protected, the Embedded Erase algorithm erases the unprotected sectors, and ignores the selected sectors which are protected.The system can use DQ6 to determine whether a sector is actively erasing. If the device is actively erasing (i.e., the Embedded Erase algorithm is in progress), DQ6 toggles. If a program address falls within a protected sector, DQ6 toggles for about 1 μS after the program command sequence is written, and then returns to reading array data.Reading Toggle Bits DQ6Whenever the system initially starts to read toggle bit status, it must read DQ7-DQ0 at least twice in a row to determine whether a toggle bit is toggling or not. Typically, the system would note and store the value of the toggle bit after the first read. While after the second read, the system would compare the new value of the toggle bit with the first one. If the toggle bit is not toggling, the device has completed the program or erase operation. The system can read array data on DQ7-DQ0 on the following read cycle.However, if after the initial two read cycles, the system finds that the toggle bit is still toggling, the system also should note whether the value of DQ5 is high or not(see the section on DQ5). If DQ5 is high, the system should then determine again whether the toggle bit is toggling or not, since the toggle bit may have stopped toggling just as DQ5 went high. If the toggle bit is no longer toggling, the device has successfully completed the program or erase operation. If it is still toggling, the device did not completed the operation, and the system must write the reset command to return to reading array data.Then the system initially determines that the toggle bit is toggling and DQ5 has not gone high. The system may continue to monitor the toggle bit and DQ5 through successive read cycles, and determines the status as described in the previous paragraph. Alternatively, the system may choose to perform other system tasks. In this case, the system must start at the beginning of the algorithm while it returns to determine the status of the operation.DQ5: Exceeded Timing LimitsDQ5 indicates whether the program or erase time has exceeded a specified internal pulse count limit. DQ5 produces “1” under these conditions which indicates that the program or erase cycle was not successfully completed.The device may output “1” on DQ5 if the system tries to program “1” to a location that was previously programmed to “0.” Only the erase operation can change “0” back to “1.” Under this condition, the device stops the operation, and while the timing limit has been exceeded, DQ5 produces “1.”Under both these conditions, the system must hardware reset to return to the read mode. REGISTERThere are two kinds of registers on this device, the General Purpose Input Registers and Product Identification Registers. Users can access these registers through respective address in the 4Gbytes memory map. There are detail descriptions in the sections below.General Purpose Inputs RegisterThis register reads the GPI[4:0] pins on the W39V080A.This is a pass-through register which can read via memory address FFBC0100(hex), or FFBxE100(hex). Since it is pass-through register, there is no default value.W39V080APublication Release Date: Dec. 28, 2005GPI Register TableBIT FUNCTION7 − 5 Reserved4 Read GPI4 pin status 3 Read GPI3 pin status 2 Read GPI2 pin status 1 Read GPI1 pin status 0Read GPI0 pin statusProduct Identification RegistersThere is a software method to read out the Product Identification in both the Programmer interface mode and the LPC interface mode. Thus, the programming equipment can automatically matches the device with its proper erase and programming algorithms.In the full-chip(8Mb) LPC interface mode, a read from FFBC, 0000(hex) can output the manufacturer code, DA(hex). A read from FFBC, 0001(hex) can output the device code D0(hex).For dual-BIOS(4Mbx2) LPC mode , a read from FFBC, 0000(hex) can output the manufacturer code, DA(hex). A read from FFBC,0001(hex) can output the device code 90(hex).In the software access mode, a JEDEC 3-byte command sequence can be used to access the product ID for programmer interface mode. A read from address 0000(hex) outputs the manufacturer code, DA(hex). A read from address 0001(hex) outputs sequence or an alternate one-byte command sequence (see Command Definition table for detail).the device code, D0(hex).” The product ID operation can be terminated by a three-byte command.Identification Input Pins ID[3:0]These pins are part of mechanism that allows multiple parts to be used on the same bus. The boot device should be 0000b. And all the subsequent parts should use the up-count strapping. Memory Address MapThere are 8M bytes space reserved for BIOS Addressing. The 8M bytes are mapped into a single 4M system address by dividing the ROMs into two 4M byte pages. For accessing the 4M byte BIOS storage space, the ID[2:1] pins are inverted in the ROM and are compared to address lines [21:20]. ID[3] can be used as like active low chip-select pin. The 32Mbit address space is as below:BLOCK LOCK ADDRESS RANGE4M Byte BIOS ROM None FFFF, FFFFh: FFC0, 0000hThe ROM responds to top 1M byte pages based on the ID pins strapping according to the followingtable:ID[2:1] PINSROM BASED ADDRESS RANGE00x FFFF, FFFFh: FFF0, 0000h 01x FFEF, FFFFh: FEF0, 0000h 10x FFDF, FFFFh: FFD0, 0000h 11xFFCF, FFFFh: FFC0, 0000hW39V080A7. TABLE OF OPERATING MODES7.1 Operating Mode Selection - Programmer ModeMODE PINS#OE#WE#RESETADDRESSDQ.Read V IL V IH V IH AIN Dout Write V IH V ILV IHAIN DinStandby X X V IL XHigh ZWrite Inhibit V IL X V IH X High Z/DOUT X V IH V IH X High Z/DOUTOutput DisableV IH X V IH XHigh Z7.2 Operating Mode Selection - LPC ModeOperation modes in LPC interface mode are determined by "cycle type" when it is selected. When itis not selected, its outputs (LAD[3:0]) will be disable. Please reference to the "Standard LPC Memory Cycle Definition".7.3 Standard LPC Memory Cycle DefinitionFIELDNO. OF CLOCKSDESCRIPTIONStart 1 "0000b" appears on LPC bus to indicate the initialCycle Type & Dir 1 "010Xb" indicates memory read cycle; while "011xb" indicates memory write cycle. "X" mean don't have to care. TAR2Turned Around TimeAddr. 8Address Phase for Memory Cycle. LPC supports the 32 bits address protocol. The addresses transfer most significant nibble first and leastsignificant nibble last. (i.e. Address[31:28] on LAD[3:0] first , and Address[3:0] on LAD[3:0] last.) Sync. N Synchronous to add wait state. "0000b" means Ready, "0101b" meansShort Wait, "0110b" means Long Wait, "1001b" for DMA only, "1010b"means error, other values are reserved. Data 2 Data Phase for Memory Cycle. The data transfer least significant nibblefirst and most significant nibble last. (i.e. DQ[3:0] on LAD[3:0] first ,then DQ[7:4] on LAD[3:0] last.)W39V080APublication Release Date: Dec. 28, 20058. TABLE OF COMMAND DEFINITIONCOMMAND NO. OF 1ST CYCLE 2ND CYCLE 3RD CYCLE 4TH CYCLE 5TH CYCLE 6TH CYCLE DESCRIPTION Cycles (1) Addr. Data Addr. DataAddr. DataAddr. DataAddr. DataAddr. DataRead 1 A IN D OUT Sector Erase 6 5555 AA 2AAA 555555 80 5555 AA 2AAA 55SA (5) 30Byte Program 4 5555 AA 2AAA 555555 A0 A IN D INProduct ID Entry 3 5555 AA 2AAA 555555 90 Product ID Exit (4) 3 5555 AA 2AAA 555555 F0Product ID Exit (4)1XXXX F0Notes: 1. The cycle means the write command cycle not the LPC clock cycle. 2. The Column Address / Row Address are mapped to the Low / High order Internal Address. i.e. Column Address A[10:0] are mapped to the internal A[10:0], Row Address A[7:0] are mapped to the internal A[19:11] 3. Address Format: A14−A0 (Hex); Data Format: DQ7-DQ0 (Hex) 4. Either one of the two Product ID Exit commands can be used. 5. SA: Sector AddressSA = FXXXXh for Unique Sector15 (Boot Sector) SA = 7XXXXh for Unique Sector7 SA = EXXXXh for Unique Sector14 SA = 6XXXXh for Unique Sector6 SA = DXXXXh for Unique Sector13 SA = 5XXXXh for Unique Sector5 SA = CXXXXh for Unique Sector12 SA = 4XXXXh for Unique Sector4 SA = BXXXXh for Unique Sector11 SA = 3XXXXh for Unique Sector3 SA = AXXXXh for Unique Sector10 SA = 2XXXXh for Unique Sector2 SA = 9XXXXh for Unique Sector9 SA = 1XXXXh for Unique Sector1 SA = 8XXXXh for Unique Sector8SA = 0XXXXh for Unique Sector0W39V080A 8.1 Embedded Programming AlgorithmW39V080A 8.2 Embedded Erase AlgorithmPublication Release Date: Dec. 28, 2005W39V080A 8.3 Embedded #Data Polling AlgorithmW39V080A 8.4 Embedded Toggle Bit AlgorithmPublication Release Date: Dec. 28, 2005W39V080A 8.5 Software Product Identification and Boot Block Lockout DetectionAcquisition FlowNotes for software product identification/boot block lockout detection:(1) Data Format: DQ7−DQ0 (Hex); Address Format: A14−A0 (Hex)(2) A1−A19 = V IL; manufacture code is read for A0 = V IL; device code is read for A0 = V IH.(3) The device does not remain in identification and boot block lockout detection mode if power down.(4) The DQ[3:2] to indicate the sectors protect status as below:DQ2 DQ30 64Kbytes Boot Block Unlocked by #TBL hardwaretrapping Whole Chip Unlocked by #WP hardware trapping Except Boot Block1 64Kbytes Boot Block Locked by #TBL hardwaretrapping Whole Chip Locked by #WP hardware trapping Except Boot Block(5) The device returns to standard operation mode.(6) Optional 1-write cycle (write F0 (hex.) at XXXX address) can be used to exit the product identification/boot block lockoutdetection.W39V080APublication Release Date: Dec. 28, 20059. DC CHARACTERISTICS9.1 Absolute Maximum RatingsPARAMETER RATING UNITPower Supply Voltage to V SS Potential -0.5 to +4.0 V Operating Temperature 0 to +70 °C Storage Temperature-65 to +150 °C D.C. Voltage on Any Pin to Ground Potential -0.5 to V DD +0.5 V V PP Voltage-0.5 to +13 V Transient Voltage (<20 nS) on Any Pin to Ground Potential-1.0 to V DD +0.5VNote: Exposure to conditions beyond those listed under Absolute Maximum Ratings May adversely affect the life and reliabilityof the device.9.2 Programmer interface Mode DC Operating Characteristics(V DD = 3.3V ± 0.3V, V SS = 0V, T A = 0 to 70° C)LIMITSPARAMETER SYM. TEST CONDITIONSMIN.TYP. MAX.UNITPower Supply Current (read)ICC1 In Read or Write mode, all DQs openAddress inputs = 3.0V/0V, at f = 3MHz- 15 20 mAPower Supply Current (erase/ write)ICC2 In Read or Write mode, all DQs openAddress inputs = 3.0V/0V, at f = 3MHz - 35 45mA Input Leakage Current ILIVIN = VSS to VDD- - 90 μA Output Leakage CurrentILO VOUT = VSS to VDD - - 90 μA Input Low Voltage VIL - -0.5- 0.8 V Input High Voltage VIH-2.0 - VDD +0.5 V Output Low Voltage VOL IOL = 2.1 mA - - 0.45 V Output High VoltageVOH IOH = -0.1mA2.4--VW39V080A9.3 LPC interface Mode DC Operating Characteristics(V DD = 3.3V ± 0.3V, V SS= 0V, T A = 0 to 70° C)LIMITS PARAMETER SYM. TESTCONDITIONSMIN. TYP. MAX.UNITPower Supply Current (read) I CC1All I out = 0A, CLK = 33 MHz,in LPC mode operation.- 15 20mAPower Supply Current (erase/write) I CC2All I out = 0A, CLK = 33 MHz,in LPC mode operation.- 35 45 mAStandby Current 1 Isb1 #LFRAME = 0.9 V DD, CLK = 33MHz,all inputs = 0.9 V DD / 0.1 V DDno internal operation- 20 50uAStandby Current 2 Isb2 #LFRAME = 0.1 V DD, CLK = 33MHz,all inputs = 0.9 V DD /0.1 V DDno internal operation.- 3 10mAInput Low Voltage V IL - -0.5-0.3V DD VInput Low Voltage of #INIT V ILI - -0.5-0.2V DD VInput High Voltage V IH - 0.5V DD- V DD +0.5VInput High Voltage of #INIT Pin V IHI - 1.35V-V DD +0.5VOutput Low Voltage V OL I OL = 1.5 mA - - 0.1 V DD VOutput High Voltage V OH I OH = -0.5 mA 0.9 V DD- - V9.4 Power-up TimingPARAMETER SYMBOLTYPICALUNIT Power-up to Read Operation T PU. READ 100 μSPower-up to Write Operation T PU. WRITE 5 mS10. CAPACITANCE(V DD = 3.3V, T A = 25° C, f = 1 MHz)PARAMETER SYMBOLCONDITIONS MAX. UNITI/O Pin Capacitance C I/O V I/O = 0V 12 pfInput Capacitance C IN V IN = 0V 6 pf。

Product data sheetCharacteristicsA9D93610A9 SLIM 4.5kA 10A TypeA主要信息断路器应用配电保护产品系列Acti 9产品类型剩余电流动作保护断路器产品短名iDPNa Vigi+极数1P + N 中性线位置左侧保护极数量1额定电流 [In]10 A 电网类型AC 脱扣曲线C 剩余电流灵敏度 [IΔn]30 MA 漏电流保护等级A类分断能力4500 A Icn 隔离功能适用补充信息配电系统位置下游配电出线电网频率50 Hz 额定工作电压 [Ue]230 V AC 50 Hz 磁脱扣限制5...10 x In 额定绝缘电压 [Ui]400 V 额定冲击耐受电压 [Uimp]4 KV 触点位置指示有控制类型手柄本地信号指示开/关指示安装方式DIN 导轨安装宽度 （9mm的倍数）2高度96.1 Mm 宽度18 Mm 深度65.8 Mm 净重136 Kg 机械寿命20000 次电气寿命10000 次接线能力隧道式端子 (上接线) - <= 16 mm² - 单股硬线 不带接线端子 隧道式端子 (下接线) - <= 10 mm² - 单股硬线 不带接线端子紧固扭矩电源回路: 2.5 N.m 上接线 电源回路: 2 N.m 下接线环境符合标准GB/T 16917.1 GB/T 16917.22 EN/IEC 61009-1产品认证CCCIP 保护等级IP20IP40抗湿热性2相对湿度95 % 在…上 55 °C运行温度-25…55 °C贮存环境温度-30…70 °CT h e i n f o r m a t i o n p r o v i d e d i n t h i s d o c u m e n t a t i o n c o n t a i n s g e n e r a l d e s c r i p t i o n s a n d /o r t e c h n i c a l c h a r a c t e r i s t i c s o f t h e p e r f o r m a n c e o f t h e p r o d u c t s c o n t a i n e d h e r e i n .T h i s d o c u m e n t a t i o n i s n o t i n t e n d e d a s a s u b s t i t u t e f o r a n d i s n o t t o b e u s e d f o r d e t e r m i n i n g s u i t a b i l i t y o r r e l i a b i l i t y o f t h e s e p r o d u c t s f o r s p e c i f i c u s e r a p p l i c a t i o n s .I t i s t h e d u t y o f a n y s u c h u s e r o r i n t e g r a t o r t o p e r f o r m t h e a p p r o p r i a t e a n d c o m p l e t e r i s k a n a l y s i s , e v a l u a t i o n a n d t e s t i n g o f t h e p r o d u c t s w i t h r e s p e c t t o t h e r e l e v a n t s p e c i f i c a p p l i c a t i o n o r u s e t h e r e o f .N e i t h e r S c h n e i d e r E l e c t r i c I n d u s t r i e s S A S n o r a n y o f i t s a f f i l i a t e s o r s u b s i d i a r i e s s h a l l b e r e s p o n s i b l e o r l i a b l e f o r m i s u s e o f t h e i n f o r m a t i o n c o n t a i n e d h e r e i n .包装单位Unit Type of Package 1PCENumber of Units in Package 11Package 1 Height9.61 CmPackage 1 Width 1.8 CmPackage 1 Length 6.58 CmPackage 1 Weight125 GUnit Type of Package 2BB1Number of Units in Package 212Package 2 Height7.8 CmPackage 2 Width9.5 CmPackage 2 Length21.8 CmPackage 2 Weight 1.548 KgUnit Type of Package 3CARNumber of Units in Package 372Package 3 Height20 CmPackage 3 Width27.8 CmPackage 3 Length37.6 CmPackage 3 Weight9.831 Kg可持续性产品类型Green Premium 产品REACh法规REACh 声明欧盟ROHS指令符合豁免条件Mercury free支持可持续的包装YesRoHS exemption information支持中国 ROHS 管理办法中国 ROHS 声明环境披露产品环境文件流通资料无需具体的回收操作合同保修保修单18 个月Product Life Status :Commercialised。

Although pleasantly simple and robust,a passive PFC rarely achieves low Total Harmonic Distortion (THD).Also,because the circuit operates at the low line power frequency of 50Hz or 60Hz,the passive elements are normally bulky and heavy.Active PFCActive PFC offers better THD and is significantly smaller and lighter than a passive PFC circuit.To reduce the size and cost of passive filter elements,an active PFC operates at a higher switching frequency than the 50Hz/60Hz line frequency.BackgroundMore than 90 million notebook computers,150 million LCD monitors and 50 million LCD televisions are expected to ship in 2008.With such a fast growing number of power electronics,actions must to be taken to ensure the functionality of the nationwide power grid.In 2001,the European Union put EN61000-3-2 into effect to set the harmonic regulation standard on any power grid supplied application with power consumption over 75 watts.This essentially requires power factor correction (PFC).Additionally,a standby power dissipation limit is set to conserve power when a load is OFF.“80 PLUS”is an initiative funded by electric utilities to integrate more energy efficient Power Supply Units (PSUs) - especially for desktop computers and servers.80 PLUS certifies to more than 80% energy efficiency at 20%,50% and 100% of rated load.To meet the 80PLUS certification,PSUs require a PFC of 0.9 or greater at 100%load.This means PSUs that waste 20% or less electric energy (as heat at the specified load levels) will lead to reduced electricity consumption and lower bills.Rebates are sometimes given to manufacturers who use 80 PLUS certified PSUs.Implementing power factor correction (PFC) into switch mode power supplies will maximize:•The power handling capability of the power supply •Current handling capacities of power distribution networksInput power factor (PF) is defined as:PF =Real Power (watts)Apparent Power (VA)PF is expressed as decimal number between zero and one (0 and 1).A non-corrected power supply with a typical PF equal to 0.65 will draw approximately 1.5 times greater input current than a PFC supply (PF = 0.99) for the same output loading.The non-corrected supply requires additional AC current to be generated which is not consumed by the load,creating I 2R losses in the power distribution network.There are two types of PFCs:1.Active2.PassivePassive PFCThe simplest form of PFC is passive (Passive PFC).A passive PFC uses a filter at the AC input to correct poor power factor.The passive PFC circuitry uses only passive components — an inductor and some capacitors (Figure.1).Power Factor Correction (PFC) Application NotesF i g u r e 1:A passive PFC circuit requires only a few components to increase efficiency,but they are large due to operating at the line power frequency.F i g u r e 2:An active PFC circuit produces low THD and uses relatively small passive components.Active PFC functions include:•Active wave shaping of the input current•Filtering of the high frequency switching•Feedback sensing of the source current for waveform control•Feedback control to regulate output voltageBuck,boost,flyback and other converter topologies are used in activePFC circuits.The DC-DC converter input capacitor also benefits from active PFC.The capacitor can be sized to filter the high frequency ripple of theactive PFC circuit instead of a much larger capacitor that would berequired to smooth the 50-60Hz input.The regulated input of the DC-DC converter also demands a lower range of duty cycle from the DC-DC converter.Other benefits of active PFC include increased “hold-over-time.”Hold over (brownout protection) benefits from alwaysstarting at the maximum voltage; and because energy in thecapacitor is related to 1/2CV2,the capacitor can be much smaller than acapacitor in a converter without active PFC.Boost InductorInductor SelectionCooper Bussmann Coiltronics®PFC inductors are available for use with awide variety of PFCs from 100W to 250W.They operate with controllersfrom several IC manufacturers to provide PFC supply solutions that utilizeeither passive or active PFC boost topology.Coiltronics PFC inductors range from 100μH to 6.2μH,100kHz.Thestandard input voltage range is 85V to 385V with different toroid materialssuch as ferrite,powder iron and Kool-Mu™ to provide significant low coreloss.The toroidal geometry allows using thicker wire to decrease DCresistance and yield higher current capacity.Many vertical or horizontalthrough-hole mounting options are available with an operating temperaturerange of –20°C to +105°C.The boost-circuit based PFC topology is the most popular.It is aneconomical solution for complying with regulations.The inductancevalue is selected based on the desired current ripple in the boostinductor.The inductance value is expressed as follows.L =V pK in(min) * d(max)fs * Δiwhere:•V pK in(min) is the peak minimum input voltage•fs is the switching frequency•Δi is the ripple current•d(max) is the maximum duty cycle expressed as:d(max) = 1- VpKin(min)V owhere V o is the output voltageThe rms boost inductor current is expressed as:IL (rms) =I in(pk)A2FusesAC Input Line FuseProduct safety standards written by Underwriters Laboratories (UL) and theInternational Electrotechnical Commission (IEC) require fuses for primary ACpower protection and secondary protection against any catastrophic failurewithin the input filter capacitors,PFC boost module,output electrolyticcapacitors (C out) or the DC-DC converters.The PFC boost module usuallydoes not contain overcurrent protection; if a short-circuit is applied acrossits output terminals,there is no internal circuit opening device to safelyinterrupt the power.Without fuse protection in the AC input line (seefuse F1 in Figrure 3),the boost converter is not protected.Fusing the DC-DC converter input lines is essential for protection against acatastrophic DC-DC converter failure (see fuses F2 and F3 in Figrure 3).Protecting the DC-DC ConverterAlthough the primary input line fuse will eventually activate,DC fusespositioned right at the input to the DC-DC converters will limit the energydelivered by the hold-up capacitors (C out) and will prevent failure to thePFC boost module.T a b l e1:Comparison of passive and active PFC versus no PFC.Fuse time current curves (I [amps] versus t [time]) should be consultedfor verification of the primary line fuse selection.The DC fuse should notopen as a result of normal inrush currents flowing at supply startup.Inrush current is limited within most PFC modules to 5A peak(3.54A rms) by an active inrush current-limiting circuit.Inrush currentduration (t) increases with increasing output capacitance (C out) and canbe approximated by t = (50)x(C out).Common Cooper Bussmann®fuses applied to the overcurrent protectionpoints in the circuit of Figure 3 are:•F1:RoHS compliant S501-2-R fast-acting 5 x 20mm ceramic tube fuserated for 2A @ 250VacF i g u r e4:S501-2-R and PC-Tron FusesCoiltronics Inductors for Power Factor CorrectionThe Cooper Bussmann Coiltronics®brand of magnetics specializes in standard and custom solutions,offering the latest in state-of-the-artlow-profile high power density magnetic components.We remain at the forefront of innovation and new technology to deliver the optimal mix of packaging,high efficiency and unbeatable reliability.Our designs utilize high frequency,low core loss materials,and new and custom core shapes in combination with innovative construction and packaging to provide designers with the highest performance parts available on the market.The Coiltronics Brand product line of power magnetics continually expands to satisfy shifts in technology and related market needs.Standard Product Categories include:• Shielded Drum Inductors• Unshielded Drum Inductors• High Current Inductors• Toroidal Inductors• Specialty Magnetics• Custom Magnetics Please visit /datasheets/elx to see data sheets on the wide variety of inductor solutions we have to offer.For techncial inquiries e-mail InductorTech@.Order samples online - •F2 & F3:RoHS compliant PC-Tron fast-acting PCB through-hole fuserated up to 250Vac/450Vdc.(Product codes PCB,PCC,PCD,PCE,PCF,PCH and PCI.)Other inductors available for prower factor correction.For other inductor values and technical application assistance contactCooper Bussmann at InductorTech@.。

单总线数字温度传感芯片 MY18E20/MY1605/MY605产 品 手 册（V3.5）©敏源传感科技有限公司2019/12概述敏源传感数字温度传感芯片系列为高集成度的数字模拟混合信号的智能传感芯片，感温原理基于半导体PN节温度与带隙电压的特性关系，经过小信号放大、模数转换、数字校准补偿、输出数字温度，具有精度高、一致性好、寿命长、功耗低、可编程配置灵活等优点。

每颗芯片都有唯一的64位ID序列号，并在出厂前根据温度误差特性进行校准系数的拟合，芯片内部自动进行补偿计算。

为了简化系统应用，芯片的ID搜索、测温数据内存访问、功能配置等均基于数字单总线协议指令，上位机微处理器只需要一个GPIO端口便可进行读写访问。

单总线通信接口通过共用一根数据总线来实现了多节点传感采集与组网的低成本方案，传输距离远、支持节点数多，便于空间分布式传感组网。

芯片内置非易失性EEPROM存储单元，用于保存芯片ID号、高低温报警阈值、温度校准修正值以及用户自定义信息，如传感器节点编号、位置信息等。

温度传感芯片具有-55°C到+125°C的工业级工作范围，内置14-bit ADC，最高分辨率0.015°C；针对不同行业应用，产品分为0.1~1.0°C等不同精度等级。

MY18E20、MY1605、MY1820、MY605为标准版系列，最高测温精度为0.5°C 。

另有高精度可编程数字温度芯片MY605+、MY1605+ 、MY18E20+，可编程高精度0.1~0.3°C 。

根据不同应用需求，封装形式分为TO-92直插型MY18E20、TO-92S小尺寸直插型MY1820、SOT23-3表贴型MY1605、DFN-8表贴型MY605等不同规格。

特点-10°C~+85°C 0.5°C精度-55°C~+125°C 1.0°C精度单总线接口，适用于分布式多节点测温转换温度时间可配置：15ms/114ms/514ms标准版默认12位输出，分辨率0.0625°C【另有高精度系列为14位可编程输出，最高分辨率0.015°C】宽供电电压范围1.8V-5.5V 每颗芯片有可编程的ID 序列号，便于组网寻址 用户可自行设置报警值80-bit 存储空间用于存放用户信息 典型待机功耗0.2µA@5V ，最大测温峰值功耗0.3mA@5V 应用简单，无需额外器件典型应用工业监控、智能家电、智能硬件、智慧农业、仪器仪表封装管脚描述及实物图TO-92直插型 MY18E20SOT 表贴型 MY1605(2.9mm×2.8mm)DFN 表贴型 MY605（2mm*2mm）TO-92S 小直插型MY1820【芯片内部系统构成以MY18E20为例，其他封装型号等同。

DESCRIPTION■Internal Thermal Protection■Internal Short Circuit Current Limit ■Replacement for LM3940■Standard SOT-223, TO-220and TO-263 packages The SPX3940 is a 1A, accurate voltage regulators with a low drop out voltage of 280mV(typical)at 1A. These regulators are specifically designed for low voltage applications that require a low dropout voltage and a fast transient response. They are fully fault protected against over-current,reverse battery, and positive and negative voltage transients.The SPX3940 is offered in 3-pin SOT-223, TO-220 & TO-263 packages. For a 3A version, refer to the SPX29300 data sheet.APPLICATIONS■Powering VGA & Sound Card ■Automotive Electronics ■LCD Monitors■Cordless Telephones ■Power PC TM SuppliesV OUTV FFigure 1. Fixed Output Linear Regulator.TYPICAL APPLICATIONS CIRCUIT■SMPS Post-Regulator ■Laptop, Palmtop, and Note-book Computer■High Efficiency Linear Power Supplies■Portable Instrumentation ■Constant Current RegulatorsNow Available in Lead Free PackagingABSOLUTE MAXIMUM RATINGSLead Temperature (soldering, 5 seconds).................................260°C Storage Temperature Range.....................................-65°C to +150°C Operating Junction Temperature Range ...................-40°C to +125°C Input Voltage (Note 5). (16V)NOTES:Note 1: Dropout voltage is defined as the input to output differential when the output voltage drops to 99% of its normal value.Note 2: V IN =V OUT (NOMINAL) + 1V. For example, use V IN =4.3V for a 3.3V regulator. Employ pulse-testing procedures to minimize temperature rise.Note 3: Ground pin current is the regulator quiescent current. The total current drawn from the source is the sum of the load current to the ground current.Note 4: Thermal regulation is defined as the change in the output voltage at a time T after a change in power dissipation is applied, excluding load or line regulation effects.Note 5: Maximum positive supply voltage of 20V must be of limited duration (<100ms) and duty cycle (<1%). The maximum continuous supply voltage is 16V.At V IN =V OUT + 1V and I OUT = 10 mA, C IN = 6.8 µF, C OUT = 10µF; T A = 25°C, unless otherwise specified.The Boldface applies over the junction temperature range. Adjustable versions are set at 5.0V.PARAMETER CONDITIONSTYPMIN MAX MIN MAX UNITSSPX3940A (1%)SP3940 (2%)1.8V Version Output Voltage I OUT = 10mA1.8 1.782 1.818 1.764 1.836V10mA ≤I OUT ≤1A, 6V ≤V IN ≤16V1.81.7551.8451.7371.8632.5V Version Output Voltage I OUT = 10mA2.5 2.475 2.525 2.450 2.550V10mA ≤I OUT ≤1A, 6V ≤V IN ≤16V2.52.4372.5632.4122.5883.3V Version Output Voltage I OUT = 10mA3.3 3.267 3.333 3.234 3.366V10mA ≤I OUT ≤1A, 6V ≤V IN ≤16V3.33.2173.3833.1843.4165.0V Version Output Voltage I OUT = 10mA5.0 4.950 5.050 4.900 5.100V10mA ≤I OUT ≤1A, 6V ≤V IN ≤16V5.04.8755.1254.8255.175All Voltage Options Line Regulation I O =10mA, (V OUT +1V)≤V IN ≤16V 0.2 1.0 1.0%Load Regulation V IN =V OUT +1V, 10mA ≤I OUT ≤1A 0.3 1.5 1.5%∆V Output Voltage 20100100ppm/°C ∆TTemperature Coef.Dropout Voltage (Note 1)I O =100mA 70200200mV(except 1.8V version)I O =1A280550550Ground Current (Note 3)I O =750mA, V IN =V OUT , + 1V 122525mA I O =1A18I GNDDO Ground Pin V IN =0.1V less than specified V OUT 1.2mA Current at Dropout I OUT = 10mA Current Limit V OUT =0V (Note 2) 2.2 1.51.5A Output Noise Voltage C L = 10µF 400µV RMS (10Hz to 100kHz)I L =100mA C L =33µF260Thermal ResistanceTO-220 Junction to Case, at Tab 3°C/W TO-220 Junction to Ambient 60TO-263 Junction to Case, at Tab 3°C/W TO-263 Junction to Ambient 60SOT-223 Junction to Case, at Tab 15°C/WSOT-223 Junction to Ambient150ELECTRICAL CHARACTERISTICSFigure 2. Line Regulation Figure 3. Load RegulationFigure 4. Ground Current vs Load Current Figure 5. Ground Current vs Input VoltageFigure 6. Ground Current vs Load Current in Dropout Figure 7. Dropout Voltage vs Load CurrentFigure 8. Ground Current vs Temperature at Figure 9. Output Voltage vs Temperature at I LOAD = 10mA I LOAD =10mAFigure 10. Ground Current vs Temperature at Figure 11. Ground Current vs Temperature in Dropout I LOAD =500mA at I LOAD =750mATYPICAL PERFORMANCE CHARACTERISTICSFigure 14. Dropout Voltage vs Temperature at I LOAD = 750mA Figure 15. Dropout Voltage vs Temperature at I LOAD = 1.5mAFigure 16. Enable Current vs Temperature for V EN = 16VFigure 17. Enable Threshold vs TemperatureTYPICAL PERFORMANCE CHARACTERISTICSAPPLICATION INFORMATIONThe SPX3940 incorporates protection against over-current faults, reversed load insertion, over temperature operation, and positive and nega-tive transient voltage.Thermal ConsiderationsAlthough the SPX3940 offers limiting circuitry for overload conditions, it is still necessary to insure that the maximum junction temperature is not exceeded in the application. Heat will flow through the lowest resistance path, the junction-to-case path. In order to insure the best thermal flow of the component, proper mount-ing is required. Consult heatsink manufacturer for thermal resistance and design of heatsink.For example, TO-220 design:Assume that VIN= 10V, VOUT= 5V, IOUT= 1.5A, TA= 50°C/W, θHA= 1°C/W, θCH= 2°C/W, and θJC= 3°C/W.Where TA = ambient temperatureθHA= heatsink to ambient thermal resistance θCH= case to heatsink thermal resistanceθJC= junction to case thermal resistanceThe power calculated under these conditions is: PD= (VIN- VOUT) * IOUT= 7.5W.And the junction temperature is calculated as TJ= TA+ PD* (θHA+ θCH+ θJC) orTJ= 50 + 7.5 * (1 + 2 + 3) = 95°CReliable operation is insured.Capacitor RequirementsThe output capacitor is needed to insure stability and minimize the output noise. The value of the capacitor varies with the load. However, a minimum value of 10µF aluminum capacitor will guarantee stability over all load conditions. A tantalum capacitor is recommended if a faster load transient response is needed.If the power source has a high AC impedance, a 0.1µF ceramic capacitor between input & ground is recommended.Minimum Load CurrentTo ensure a proper behavior of the regulator under light load, a minimum load of 5mA for SPX3940 is required.PACKAGE: TO-263View CSECTION B-B3 PIN TO-263PACKAGE: 3 PIN TO-220CONTACT AREA.140 - .190.020 - .055Dimensions in (mm)3 PIN TO-220JEDEC TO-220(AB) V ariation .080 - .115.015 .027 .040.045 - .070 .480 - .507A A1A2b b2D1D2 .380 - .420E MIN NOM MAXc .014 - .024D .560 - .650.330 - .355E1.270-.350E2 - - .030e .100 BSC e1.200 BSC H1.230 - .270L1- - .250L2- - -∆P .139 - .161Q.100 - .1353 PIN TO-220VIEW C0.89 - 1.120.01 - 0.10Dimensions in (mm)3 PIN SOT-23JEDEC TO-236(AB) V ariation0.88 0.95 1.020.30 - 0.500.08 - 0.200.40 0.50 0.600.54 REF 0º - 8ºA A1A2b c D E E1L L1ØMIN NOM MAX 2.80 2.90 3.042.10 - 2.641.20 1.30 1.40e e10.95 BSC 1.90 BSC VIEW A-A3 PIN SOT-23PACKAGE: 3 PIN SOT-23Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.Sipex Corporation Headquarters and Sales Office233 South Hillview Drive Milpitas, CA 95035TEL: (408) 934-7500FAX: (408) 935-7600PART NUMBERACC.OUTPUT VOLTAGEPACKAGESPX3940AU-1.81% 1.8V 3 lead TO-220SPX3940AU-2.51% 2.5V 3 lead TO-220SPX3940AU-3.31% 3.3V 3 lead TO-220SPX3940AU-5.01% 5.0V 3 lead TO-220SPX3940AT-1.81% 1.8V 3 lead TO-263SPX3940AT-1.8/TR 1% 1.8V 3 lead TO-263SPX3940AT-2.51% 2.5V 3 lead TO-263SPX3940AT-2.5/TR 1% 2.5V 3 lead TO-263SPX3940AT-3.31% 3.3V 3 lead TO-263SPX3940AT-3.3/TR 1% 3.3V 3 lead TO-263SPX3940AT-5.01% 5.0V 3 lead TO-263SPX3940AT-5.0/TR 1% 5.0V 3 lead TO-263SPX3940U-1.82% 1.8V 3 lead TO-220SPX3940U-2.52% 2.5V 3 lead TO-220SPX3940U-3.32% 3.3V 3 lead TO-220SPX3940U-5.02%5.0V3 lead TO-220PINOUTS/TR = Tape and ReelPack quantity is 500 for TO-263 and 2,500 for SOT-23.Available in lead free packaging. To order add "-L" suffix to part number.Example: SPX3940AT-3.3/TR = standard; SPX3940AT-L-3.3/TR = lead free11Date: 5/25/04 SPX3940 1A Low Dropout Voltage Regulator © Copyright 2004 Sipex CorporationPART NUMBERACC.OUTPUT VOLTAGEPACKAGESPX3940T-1.82% 1.8V 3 lead TO-263SPX3940T-1.8/TR 2% 1.8V 3 lead TO-263SPX3940T-2.52% 2.5V 3 lead TO-263SPX3940T-2.5/TR 2% 2.5V 3 lead TO-263SPX3940T-3.32% 3.3V 3 lead TO-263SPX3940T-3.3/TR 2% 3.3V 3 lead TO-263SPX3940T-5.02% 5.0V 3 lead TO-263SPX3940T-5.0/TR 2% 5.0V 3 lead TO-263SPX3940AM3-1.81% 1.8V 3 lead SOT-223SPX3940AM3-1.8/TR 1% 1.8V 3 lead SOT-223SPX3940AM3-2.51% 2.5V 3 lead SOT-223SPX3940AM3-2.5/TR 1% 2.5V 3 lead SOT-223SPX3940AM3-3.31% 3.3V 3 lead SOT-223SPX3940AM3-3.3/TR 1% 3.3V 3 lead SOT-223SPX3940AM3-5.01% 5.0V 3 lead SOT-223SPX3940AM3-5.0/TR 1% 5.0V 3 lead SOT-223SPX3940M3-1.82% 1.8V 3 lead SOT-223SPX3940M3-1.8/TR 2% 1.8V 3 lead SOT-223SPX3940M3-2.52% 2.5V 3 lead SOT-223SPX3940M3-2.5/TR 2% 2.5V 3 lead SOT-223SPX3940M3-3.32% 3.3V 3 lead SOT-223SPX3940M3-3.3/TR 2% 3.3V 3 lead SOT-223SPX3940M3-5.02% 5.0V 3 lead SOT-223SPX3940M3-5.0/TR2%5.0V3 lead SOT-223Available in lead free packaging. To order add "-L" suffix to part number.Example: SPX3940AM3-3.3/TR = standard; SPX3940AM3-L-3.3/TR = lead free /TR = Tape and ReelPack quantity is 500 for TO-263 and 2,500 for SOT-23.ORDERING INFORMATIONSipex Corporation Headquarters and Sales Office233 South Hillview Drive Milpitas, CA 95035TEL: (408) 934-7500FAX: (408) 935-7600元器件交易网。

Installation GuidePower MonitoringFor use in a Pollution Degree 2 or better environment only. A Pollution Degree 2 environment must control conductive pollution and the possibility of condensation or high humidity. Consider the enclosure, the correct use of ventilation, thermal properties of the equipment, and the relationship with the environment. Installation category: CAT II or CAT III. Provide a disconnect device to disconnect the meter from the supply source. Place this device in close proximity to the equipment and within easy reach of the operator, and mark it as the disconnecting device. The disconnecting device shall meet the relevant requirements of IEC 60947-1 and IEC 60947-3 and shall be suitable for the application. In the US and Canada, disconnecting fuse holders can be used. Provide overcurrent protection and disconecting device for supply conductors with approved current limiting devices suitable for protecting the wiring. If the equipment is used in a manner not specified by the manufacturer, the protection provided by the device may be impaired.FCC PART 15 INFORMATIONNOTE: This equipment has been tested by the manufacturer and found to comply with the limits for a class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in aresidential environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.Modifications to this product without the express authorization of themanufacturer nullify this statement.NEMA ICS 1.1 (latest edition). Safety Guidelins for the Application, Installation, and Maintenance of Solid-State Control or its equivalent in your speci c country, language, and/or location.Control system design must consider the potential failure modes of control paths and, for certain critical control functions, provide a means to acheive a safe state during and after a path failure. Examples of critical control functions are emergency stop and over-travel stop.A quali ed person is one who has skills and knowledge related to the construction and operation of this electrical equipment and the installation, and has received safety training to recognize and avoid the hazards involved. NEC2011 Article 100No responsibility is assumed by Leviton for any consequences arising out of the use of this material.Product OverviewThe Series 4000-R DIN rail meter provides a solution for measuring energy data with a single device. Inputs include control power, CT, and 3-phase voltage. The Series 4000-R supports multiple output options, including solid state relay contacts, Modbus, and pulse. The LCD screen on the faceplate allows instant output viewing. Series 4000-R meters include built-in CT integrators and CT power supplies. They work only with U018 Series rope style CTs.The meter is housed in a plastic enclosure suitable for installation on T35 DIN rail according to EN50022. The Series 4000-R can be mounted with any orientation over the entire ambient temperature range, either on a DIN rail or in a panel. The meter is not sensitive to CT orientation to reduce installation errors.Series 4000-RCompact Modbus Power and Energy Meter For Use Only With U018 Series Rope CTs SpecificationsProduct IdentificationSeries 4000-RUnidirectional metering, Modbus full data set, pulse and alarm outputs. For use only with U018 rope style CTs.* External DC current limiting is required, see fuse recommendations.T able of Contents Dimensions4Data Outputs4Product Diagram5Display Screen Diagram5Installation6Supported System Types7Wiring Symbols7Wiring8Control Power9Quick Setup Instructions10Solid State Output11User Interface Menu Abbreviations Defined11User Interface for Data Configuration12Alert/Reset Information13User Interface for Setup14RS-485 Communications16Standard Modbus Default Settings17Modbus Point Map Overview18Modbus Point Map19Troubleshooting24China RoHS Compliance Information (EFUP Table)24Dimensions0.2 “(4 mm)0.3 “(8 mm)0.4 “Bottom View (DIN Mount Option)Bottom View (Screw Mount Option)Full Data Set (FDS):Power (kW)Energy (kWh)Configurable for CT & PT ratios, system type, and passwordsDiagnostic alertsCurrent: 3-phase averageVolts: 3-phase averageCurrent: by phaseVolts: by phase Line-Line and Line-NeutralPower: Real, Reactive, and Apparent 3-phase total and per phasePower Factor: 3-phase average and per phaseFrequencyPower Demand: Most Recent and PeakDemand Configuration: Fixed, Rolling Block, and External Sync Data OutputsProduct DiagramDisplay Screen DiagramBottom row numeric onlyNeutEaControPowerA B CseLossrmOutputseOutputbusAlertDataLCD Screen:Buttons:(Up)(Right)Next(Down)Select(Left)BackInstallationWARNING: TO AVOID FIRE, SHOCK, OR DEATH, disconnect power prior to installation.Reinstall any covers that are displaced during the installation before powering the unit.Mount the meter in an appropriate electrical enclosure near equipment to be monitored.Do not install on the load side of a Variable Frequency Drive (VFD), aka Variable Speed Drive (VSD) or Adjustable Frequency Drive (AFD).The meter can be mounted in two ways: on standard 35 mm DIN rail or screw-mounted to the interior surface of the enclosure.A. DIN Rail Mounting1. Attach the mounting clips to the underside of the housing by sliding them into the slots from the inside. The stopping pegs must face the housing, and the outside edge of the clip must be flush with the outside edge of the housing.2. Snap the clips onto the DIN rail. See the diagram of the underside of the housing (below).3. To reduce horizontal shifting across the DIN rail, use two end stop clips.B. Screw Mounting1. Attach the mounting clips to the underside of the housing by sliding them into the slots from the outside. The stopping pegs must face the housing, and the screw hole must be exposed on the outside of the housing.2. Use three #8 screws (not supplied) to mount the meter to the inside of the enclosure. See the diagram of the underside of the housing (below).Screw holesexposed for mountingThe meter has a number of different possible system wiring configurations (see Wiring section). To configure the meter, set the System Type via the User Interface or Modbus register 130. The System Type tells the meter which of its current and voltage inputs are valid, which are to be ignored, and if neutral is connected. Setting the correct System Type prevents unwanted energy accumulation on unused inputs, selects the formula to calculate the Theoretical Maximum System Power, and determines which phase loss algorithm is to be used. The phase loss algorithm is configured as a percent of the Line-to-Line System Voltage (except when in System Type 10) and also calculates the expected Line to Neutral voltages for system types that have Neutral (12 & 40).Values that are not valid in a particular System Type display as “----” on the User Interface or as QNAN in the Modbus registers.Supported System T ypesTo avoid distortion, use parallel wires for control power and voltage inputs. The following symbols are used in the wiring diagrams on the following pages.Wiring SymbolsWiringDiagram 1: 1-Phase Line-to-Neutral 2- WireSystem 1 CTDiagram 2: 1-Phase Line-to-Line 2-WireSystem 1 CTDiagram 3: 1-Phase Direct Voltage Connection 2 CTDiagram 4: 3-Phase 3-Wire 3 CT no PTUse System Type 11 (2L)Use System Type 31 (3L)Use System Type 10 (1L + 1n)1. Squeeze the ribbed sections of the CT connector and pull the rope out of the connector to open.3. Snap the connector back together securely, ensuring there is no dust or debris in the closure area.4. Connect the CT output leads to the S4000-R meter inputs according to the following diagrams. The white wire is the X1 lead.Control PowerDirect Connect Control Power (DC Control Power)NDirect Connect Control Power (Line to Neutral)Line to Neutral from 90 VAC to 347 VAC (UL) or 300 VAC (CE)Control Power Transformer (CPT) ConnectionDirect Connect Control Power (Line to Line)Line to Line from 90 VAC to 600 VAC (UL). In UL installations the lines may be floating (such as a delta). If any lines are tied to an earth (such as a corner grounded delta), see the Line to Neutral installation limits. In CE compliant installations, the lines mustbe neutral (earth) referenced at less than 300 VAC L-NThe Control Power Transformer may be wired L-N or L-L. Output tomeet meter input requirementsDC Control Power from 125 VDC to 300 VDC(UL and CE max.)Fuse RecommendationsKeep the fuses close to the power source (obey local and national code requirements).For selecting fuses and circuit breakers, use the following criteria:• Select current interrupt capacity based on the installation category and fault current capability.• Select over-current protection with a time delay.• S elect a voltage rating sufficient for the input voltage applied.•Provide overcurrent protection and disconnecting means to protect the wiring. For DC installations, provide external circuit protection. Suggested: 0.5 A, time delay fuses.•The earth connection (G) is required for electromagnetic compatibility (EMC) and is not a protective earth ground.Diagram 5: 3-Phase 4-Wire Wye Direct Voltage InputConnection 3 CTUse System Type 40 (3L + 1n)Diagram 6: 3-Phase 4-Wire Wye Connection 3 CT3 PTUse System Type 40 (3L + 1n)Wiring (cont.)These instructions assume the meter is set to factory defaults. If it has been previously configured, all optional values should be checked.SETUPscreen appears.5. The first Setup screen is S COM (set communications).ADDRBAUDPARS COM screen.S CT (Set Current Transducer) screen.CT SZS CT screen.S SYS (Set System) screen.SYSTMS SYS screen.S PT (Set Potential Transformer) screen. If PTs are not used, then skip this step.RATIOS PT screen.S V (Set System Voltage) screen.VLLSETUP.11. Check that the wrench is not displayed on the LCD.ALERT screen.For full setup instructions, see the configuration instructions on the following pages.Quick SetupInstructionsUser Interface (UI) Menu Abbreviations DefinedThe user can set the display mode to either IEC or IEEE notation in the SETUP menu.Solid State OutputThe Series 4000-R meters have one normally open (N.O.) KY Form A output and one normally closed (N.C.) output.* One is dedicated to energy (Wh), and the other to Alarm. See the Setup section for configuration information.Power Source**3-30 VDC 6-30 VACOver-Current Protective Device* (not supplied)The solid state pulse outputs are rated for 30 VAC/DC nom.Maximum load current is 100 mA at 25°C. Derate 0.56mA per °C above 25°C (e.g. 86 mA@50°C).* The over-current protective device must be rated for the short circuit current at the connection point.** All pulse outputs and communication circuits are only intended to be connected to non-hazardous circuits (SELV or Class 2). Do not connect to hazardous voltages.User Interface for1, 2, o r 3 P h a s S u m m a r y D a t P h a s e A : A l l S y s t e m sP h a s e B :2 & 3 P h a s e S y s t e m s O n l P h a s e C : 3 P h a s e S y s t e m s O n l D e m a n d T o : T o :A L E R TE n e r g y A c c u m u l a t o r s a n d C o u n t e r sSetup MeterReset DataUnitInformationAlert Status (check if Wrench on LCD)To: ENRGYAlert/Reset InformationUI for SetupModbus Address: 1 –247.Baud Rate: 1200 –38400 BaudParity: Odd, Even, None–to step through the options.To Setup p. 2 “SPLOS”(No PT installed). See Install for wiring diagrams. This value must beNote: Bold is the Default.To Setup p. 2 “SPASS”briefly indicate “SAvEd)” to confirm that any changes made have been accepted.UI for Setup (cont.)briefly indicate “SAvEd)” to confirm that any changes made have been accepted.To Setup p. 1 “S PWR”B a c k T o S E T U PDaisy-chaining Devices to the Power MeterThe RS-485 slave port allows the power meter to be connected in a daisy chain with up to 63 2-wire devices.Notes• The terminal’s voltage and current ratings are compliant with the requirements of the EIA RS-485 communications standard.• The RS-485 transceivers are ¼ unit load or less.• RS-485+ has a 47 kΩ pull up to +5V, and RS-485- has a 47 kΩ pull down to Shield (RS-485 signal ground).• Wire the RS-485 bus as a daisy chain from device to device, without any stubs. Use 120 Ω termination resistors at each end of the bus (not included).• Shield is not internally connected to Earth Ground.• Connect Shield to Earth Ground somewhere on the RS-485 bus.For all terminals:• When tightening terminals, apply the correct torque: 0.37 to 0.44 ft·lb (0.5-0.6 N·m).• Use 14-24 gauge (2.1-0.2 mm 2) wire.RS-485Communications0.37–0.44 ft•lb (0.5–0.6 N•m)UStandard Modbus ArrayDefault SettingsModbus Point Map Overview The Series 4000-R features data outputs such as demand calculations, per phase VA and VAR, and VAh VARh accumulators. For security reasons, configuration and resets on all Series 4000-R models are protected by a user configurable passcode. The meter supports variable CTs and PTs, allowing a much wider range of operation from 90V x 5A up to 32000V x 5000A. To promote this, the meter permits variable scaling of the 16-bit integer registers via the scale registers. The 32-bit floating point registers do not need to be scaled.Integer registers begin at 001 (0x001). Floats at 257 (0x101). Configuration registers at 129 (0x081). Values not supported in a particular System Type configuration will report QNAN (0x8000 in Integer Registers, 0x7FC00000 in Floating Point Registers). Supported Modbus CommandsLegendThe following table lists the addresses assigned to each data point. For floating point format variables, each data point appears twice because two 16-bit addresses are required to hold a 32-bit float value.R/W R=read only; R/W=read from either int or float formats, write only to integer format.NV Value is stored in non-volatile memory. The value will still be available if the meter experiences a power loss and reset. FormatUInt Unsigned 16-bit integer.SInt Signed 16-bit integer.ULong Unsigned 32-bit integer; Upper 16-bits (MSR) in lowest-numbered / first listed register (001/002 = MSR/LSR).Float32-bit floating point; Upper 16-bits (MSR) in lowest-numbered / first listed register (257/258 = MSR/LSR). Encoding is per IEEE standard 754 single precision.Units Lists the physical units that a register holds.Scale Factor Some Integer values must be multiplied by a constant scale factor (typically a fraction), to be read correctly. This is done to allow integer numbers to represent fractional numbers.Range Defines the limit of the values that a register can contain.Modbus Point MapModbus Point Map (cont.)Invalid or Quiet Not A Number (QNAN) conditions are indicated by 0x8000 (negative zero) for 16 bit integers and 0x7FC00000 for 32 bit floating point numbers. Floating point numbers are encoded per the IEEE 754 32-bit specifications.T roubleshooting(EFUP T able)产品中有毒有害物质或元素的名称及含量Substances部件名称铅 (Pb)汞 (Hg)镉 (Cd)六价铬 (Cr(VI))多溴联苯(PBB)多溴二苯醚(PBDE)电子线路板 X O O O O OO = 表示该有毒有害物质在该部件所有均质材料中的含量均在 SJ/T11363-2006 标准规定的限量要求以下.X = 表示该有毒有害物质至少在该部件的某一均质材料中的含量超出SJ/T11363-2006标准规定的限量要求.Z000057-0A。

2018产品说明书PRODUCT MANUAL深圳市叁叶源主要生产被动元器件SMD R‐Chip 电阻，产品尺寸：0402‐1206，阻值范围：1‐22兆欧姆，产品具有高可靠性电极设计、兼容所有焊接制程等特点。

Administrator深圳市叁叶源电子有限公司2018/6/1目录Contents●特点Features3●品名构成Type Designation3●结构Construction4●规格尺寸Dimensions4●负荷下降曲线Derating Curve4●额定值Ratings5●常规TCR值5●高精度TCR±50额定值6●特性Characteristics6●推荐焊盘尺寸Recommend Solder Pad Size9●包装Packaging9●IEC E-24、E-96系列电阻值代码对照表12●厚膜电阻阻值代码及标记规则14●片式电阻器使用说明16●焊接Soldering17■常规厚膜片式固定电阻器General Thick Film Chip Fixed Resistor●特点Features体积小、重量轻Miniature and light weight 适应再流焊与波峰焊Suit for reflow and wave flow solder 电性能稳定，可靠性高Stable electrical capability,high reliability 装配成本低，并与自动贴装设备匹配Low assembly cost,suit for automatic SMT equipment 机械强度高，高频特性优越Superior mechanical and frequency characteristics 符合RoHS 指令要求Compliant with RoHS directive 符合无卤素Halogen free requirement●品名构成Type Designation Single Chip ResistorSY 0402J N 100R P (1)(2)(3)(4)(5)(6)(1)(2)(3)(4)(5)(6)SeriesSize Reslstance Toleiance TCRResistance Packing style SY Thinck Film ST Thinck FilmSA Atuomotive Garde0402060308051206B=±0.1%D=±0.5%F=±1%J=±5%N=Base on Spc E=±50ppm/℃D=±25ppm/℃F=±100ppm/℃G=±200ppm/℃1K 100K 10R 4K71MP=Pager TapeB=Embossed Plastic●结构Construction①陶瓷基板Ceramic Substrate ②背电极Bottom Electrode ③面电极Top Electrode ④电阻体Resistor Layer ⑤一次保护Primary Overcoat ⑥二次保护Secondary Overcoat ⑦端电极Edge Electrode ⑧中间电极Barrier Layer ⑨外部电极External Electrode●规格尺寸Dimensions型号Type 尺寸Dimensions(mm)L W t a b 0402 1.00±0.100.50±0.050.35±0.050.20±0.100.25±0.100603 1.60±0.100.80±0.100.45±0.100.30±0.200.30±0.200805 2.00±0.15 1.25+0.15-0.100.55±0.100.40±0.200.40±0.2012063.10±0.151.55+0.15-0.100.55±0.100.45±0.200.45±0.20●负荷下降曲线Derating Curve额定负荷百分比Percent Rated Load环境温度Ambient temperature(℃)使用温度范围：OperatingTemperature Range:①-55℃~125℃②-55℃~155℃注1：图中曲线适用于适用于0402、0603、0805、1206。

E103-W08产品规格书2.4G串口WIFI BLE配网低功耗目录第一章概述 (1)1.1简介 (1)1.2功能特点 (1)1.3应用场景 (2)第二章规格参数 (2)2.1极限参数 (2)2.2工作参数 (2)第三章机械尺寸与引脚定义 (3)3.1E103-W08A引脚尺寸图 (3)3.2E103-W08A引脚尺寸图 (4)第四章推荐连线图 (5)第五章功能说明 (5)5.1工作模式 (5)5.1.1TCP通信 (6)5.1.2MQTT通信 (7)5.1.3HTTP通信 (7)5.2TCP心跳包 (7)5.3自动连接 (7)5.4手动连接 (8)5.5手动断开 (8)5.6BLE配网 (8)5.7状态指示 (8)5.8低功耗 (8)5.9注意事项 (9)第六章默认参数 (9)第七章AT指令及参数 (10)7.1错误码表 (11)7.2基本AT指令 (11)7.2.1AT测试指令 (11)7.2.2重启模块 (11)7.2.3恢复出厂参数 (12)7.2.4查询版本信息 (12)7.2.5查询、设置串口参数 (12)7.2.6查询、设置工作模式 (12)7.2.7查询、设置电源模式 (13)7.3WIFI相关AT指令 (13)7.3.1扫描可用AP (13)7.3.2连接到指定AP (13)7.3.3与AP断开连接 (14)7.3.4查询、设置连接模式 (14)7.3.5查询MAC地址 (14)7.3.6查询、设置主机名 (14)7.4TCP相关AT指令 (15)7.4.1查询网络连接状态 (15)7.4.2建立TCP传输 (15)7.4.3关闭TCP传输 (15)7.4.4查询本地IP (15)7.4.5查询、设置多连接 (15)7.4.6查询、设置TCP模式 (15)7.4.7查询、设置是否打印对端IP、端口 (16)7.4.8查询、设置远程目标参数 (16)7.4.9查询、设置心跳数据 (16)7.5MQTT相关AT指令 (17)7.5.1查询、设置MQTT远程目标 (17)7.5.2查询、设置MQTT发布主题 (17)7.5.3查询、设置MQTT订阅主题 (17)7.5.4查询、设置MQTT登录参数 (17)7.5.5查询、设置MQTT连接参数 (18)7.6HTTP相关参数 (18)7.6.1查询、设置远程目标 (18)7.6.2查询、设置URL (18)7.6.3查询、设置数据类型 (18)7.7BLE相关参数 (19)7.7.1查询、设置BLE广播名 (19)7.7.2查询、设置BLE广播间隙 (19)第八章使用教程 (20)8.1TCP通信 (20)8.1.1透传 (20)8.1.2协议传输 (21)8.2HTTP通信 (23)8.3MQTT通信 (23)8.4BLE配网 (24)第九章焊接作业指导 (27)9.1回流焊温度 (27)9.2回流焊曲线图 (27)修订历史 (28)关于我们 (28)免责申明和版权公告本文中的信息，包括供参考的URL地址，如有变更，恕不另行通知。

华立温控器中文使用说明书————————————————————————————————作者: ————————————————————————————————日期：通过ISO9０02国际质量体系认证coｎfoｒmｉty Certｉficａtiｏn of ISO90０２Qualiｔy Ｍanagｅmeｎt SｙsｔｅｍBWY(WTYＫ）-80２、８03系列变压器温度控制器SＥRIES TRANSFORMＥＲＴＥMＰERＡTURＥ CＯNＴROLLＥR使用说明书DESCRIPTION ＆OPＥRATION ＩNSTRUCTIONS杭州华立仪表有限公司HANG ZHOU HUＡＬI IＮSTＲUMENＴ＆ METER GENERAL PＬANT感谢您使用本厂产品使用前请认真阅读产品使用说明书THAＮＫS FOＲUSＩNＧＯUR ＰＲODUCTSＰLEＡSE RＥAD THE ＤIRＥCTIONS BEＦORE USE目录一、概况 (1)二、工作原理 (5)三、主要技术指标 (5)四、安装及使用 (5)五、注意事项 (10)六、附录Pｔ１00工业铂电阻分度值表 (11)一、概况1、温度控制器根据沈阳变压器研究所制订的ＪB/T630２－92《变压器用压力式温度计》标准的命名如下:+２、温度控制器根据JB/T92３6-1９9９《工业自动化仪表产品型号编制原则》的要求产品命名如下：ﻬﻬﻬ二、工作原理最大插入深度安装孔图一 系列温度控制器外形及安装尺寸B W Y (W T Y K )8010000100K1K100K23浙制01 4920040M100°C60华立仪表变压器温度控制器(以下简称温控器）,主要由弹性元件、毛细管、温包和微动开关组成。

当温包受热时,温包内感温介质受热膨胀所产生的体积增量，通过毛细管传递到弹性元件上，使弹性元件产生一个位移，这个位移经机构放大后指示出被测温度并带动微动开关工作，从而控制冷却系统的投入或退出。

TC397XP256F300SBCKXUMA1AURIX™ TC39x variantsAbout this documentScope and purposeThis document is an addendum to the TC39x Product Data Sheet and User's Manual, listing all planned product variants, key parameters such as memory size and optional features.The User's Manual lists functions implemented on the Silicon, but this document counts functions that are pinning dependent; i.e. functions are counted that are connected to at least one package pin. As pins are overlaid with several functions the pinning needs to be checked (see Product Data Sheet) to determine the number of usable functions in an application.Naming conventionsPrefix:•SAK: T ambient Temperature Range from -40 °C up to +125 °C.•SAL: T ambient Temperature Range from -40 °C up to +150 °C (packaged device).Feature package:•P: Standard feature.•E: Emulation device with all features of the emulated standard type, additionally full MCDS, overlay functionality for calibration, AGBT as trace interface for development (depending on the package).•C,V,Z: Customer Specific.•A: ADAS ext. Memory.•T: ADAS + emulation.•X: Extended Feature device. These products contain the extended memory (EMEM) of the ADAS subsystem.The ADAS peripherals SPU, RIF and CIF are not available.•M: MotionWise software.•F: Extended Flash.•G: Additional Connectivity.•H: ADAS Standard feature.•N: Standard feature with AMU.Table of contentsTable of contentsAbout this document . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1Table of contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .2 1TC39x BD step variants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 1.1TC39x BD step (part 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3 1.2TC39x BD step (part 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6 2TC39x BC step variants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 2.1TC39x BC step (part 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9 2.2TC39x BC step (part 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12 3Memory maps of TC39x variants . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18Disclaimer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .191TC39x BD step variants1.1TC39x BD step (part 1)A table listing the TC39x BD step variants.Table 1TC39x variantsSAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300SStepBD BD BD BD BD BD BD Production statusStandard Standard Standard Standard Standard Standard Standard Package typePG-LFBGA-516PG-LFBGA-516PG-LFBGA-292PG-LFBGA-516PG-LFBGA-516PG-LFBGA-292PG-LFBGA-292 PinoutLFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm ADAS Reference siliconTC39x TC39x TC39x TC39x TC39x TC39x TC39x Temperature range (ambient)-40°C up to+150°C -40°C up to+150°C-40°C up to+150°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°CChip IDAttention:The value of SCU_CHIPID in the UCODE field contains the default value 0 not the µCode version.0xAF0199930x8F0199930x8F0197930x8F0199930xAF0199930x8F0197930xBF019793 Cores / checker cores6/46/46/46/46/46/46/4 Maximum frequency (MHz)300300300300300300300 Program flash (MB)16161616161616 Data flash 0 (single-ended) (KB)1024102410241024102410241024 Total SRAM (without EMEM and Cache) (KB)2528252825282528252825282528 EMEM Size (KB)4096000409604096 1 TC39x BD step variantsTable 1TC39x variants (continued)SAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300SDSPR (KB)240 in CPU0&1;96 other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96otherDLMU (KB)64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU PSPR (KB)64646464646464 LMU (KB)768768768768768768768 DAM (KB)128128128128128128128 AMU1)No No No No No No No ADC (primary groups/channels)8/648/645/408/648/645/404/26 ADC (secondary groups/channels)4/424/604/604/604/604/604/42 ADC (fast compare channels)8888888 ADC (EDSADC channels)14146141466 CAN (modules/nodes)3/3x43/3x43/3x43/3x43/3x43/3x43/3x4 FlexRay (modules/channels)2/2x22/2x22/2x22/2x22/2x22/2x22/2x2 HSSL modules2222222 ASCLIN modules / with ASC and LIN / with 3-wire SPI12/12/1212/12/1212/12/1112/12/1212/12/1212/12/1112/12/9 QSPI modules / with LVDS1AMU is abbreviated as ASC Modeling Unit. For Additional details about AMU, Contact an Infineon Representative1 TC39x BD step variantsTable 1TC39x variants (continued)SAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300S6/26/26/26/26/26/26/1 SENT channels25252025252017 MSC modules4424421 PSI5 channels4444444 PSI5-S moduleYes Yes Yes Yes Yes Yes Yes SDMMC moduleYes Yes Yes Yes Yes Yes Yes Maximum Ethernet availability: 1GBit/100Mbit/No1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s MCDS availabilityMCDS MCDS MCDS MCDS MCDS MCDS MCDS ADAS cluster availableNo No No No No No Yes HSM availableYes Yes Yes Yes Yes Yes Yes 1 TC39x BD step variants1.2TC39x BD step (part 2)A continuation of the TC39x BD step variants. Table 2TC39x BD step (part 2)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300SSAK-TC397XM-256F300SStepBD BD BD BD BD BD Production statusStandard Standard Customerspecific CustomerspecificCustomerspecificStandardPackage typePG-LFBGA-292PG-LFBGA-292PG-LFBGA-292PG-LFBGA-292PG-LFBGA-292PG-LFBGA-292 PinoutADAS LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm Reference siliconTC39x TC39x TC39x TC39x TC39x TC39x Temperature range (ambient)-40°C up to+125°C -40°C up to+125°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°CChip IDAttention:The value of SCU_CHIPID in the UCODE field contains the default value 0 not the µCode version.0xCC0197930xAF0197930xCD0197930xCF0197930xFF0197930x8F019793 Cores / checker cores4/36/44/44/46/46/4 Maximum frequency (MHz)300300300300300300 Program flash (MB)101612161616 Data flash 0 (single-ended) (KB)102410241024102410241024 Total SRAM (without EMEM and Cache) (KB)169625281184208016322528 EMEM Size (KB)409640960000 DSPR (KB)1 TC39x BD step variantsTable 2TC39x BD step (part 2) (continued)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300SSAK-TC397XM-256F300S240 in CPU0&1;96 other 240 in CPU0&1;96 other240 in CPU0&1;96 other240 in CPU0&1;96 other240 in CPU0&1;96 other240 in CPU0&1;96 otherDLMU (KB)64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU PSPR (KB)646464646464 LMU (KB)51276807680768 DAM (KB)012801280128 AMU2)No No No No No No ADC (primary groups/channels)4/265/405/405/405/405/40 ADC (secondary groups/channels)4/424/604/604/604/604/60 ADC (fast compare channels)888888 ADC (EDSADC channels)666666 CAN (modules/nodes)3/3x43/3x43/3x43/3x43/3x43/3x4 FlexRay (modules/channels)2/2x22/2x22/2x22/2x22/2x22/2x2 HSSL modules222222 ASCLIN modules / with ASC and LIN / with 3-wire SPI12/12/912/12/1112/12/1112/12/1112/12/1112/12/11 QSPI modules / with LVDS6/16/26/26/26/26/2 SENT channels2AMU is abbreviated as ASC Modeling Unit. For Additional details about AMU, Contact an Infineon Representative1 TC39x BD step variantsTable 2TC39x BD step (part 2) (continued)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300SSAK-TC397XM-256F300S172020202020 MSC modules122222 PSI5 channels444444 PSI5-S moduleYes Yes Yes Yes Yes-SDMMC moduleYes Yes Yes Yes Yes Yes Maximum Ethernet availability: 1GBit/100Mbit/No1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s MCDS availabilityMCDS MCDS MCDS MCDS MCDS MCDS ADAS cluster availableYes No No No No No HSM availableYes Yes Yes Yes Yes Yes 1 TC39x BD step variants2TC39x BC step variants2.1TC39x BC step (part 1)A table of TC39x BC step variants (part 1).Table 3TCxxx YY stepSAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300SStepBC BC BC BC BC BC BC Production statusStandard Standard Standard Standard Standard Standard Standard Package typePG-LFBGA-516PG-LFBGA-516PG-LFBGA-292PG-LFBGA-516PG-LFBGA-516PG-LFBGA-292PG-LFBGA-292 PinoutLFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm ADAS Reference siliconTC39x TC39x TC39x TC39x TC39x TC39x TC39x Temperature range (ambient)-40°C up to+150°C -40°C up to+150°C-40°C up to+150°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°C-40°C up to+125°CChip IDAttention:The value of SCU_CHIPID in the UCODE field contains the default value 0 not the µCode version.0xAF0199920x8F0199920x8F0197920x8F0199920xAF0199920x8F0197920xBF019792 Cores / checker cores6/46/46/46/46/46/46/4 Maximum frequency (MHz)300300300300300300300 Program flash (MB)16161616161616 Data flash 0 (single-ended) (KB)1024102410241024102410241024 Total SRAM (without EMEM and Cache) (KB)2528252825282528252825282528 EMEM Size (KB)4096000409604096 2 TC39x BC step variantsTable 3TCxxx YY step (continued)SAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300SDSPR (KB)240 in CPU0&1;96 other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96other240 inCPU0&1; 96otherDLMU (KB)64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU PSPR (KB)64646464646464 LMU (KB)768768768768768768768 DAM (KB)128128128128128128128 AMU3)No No No No No No No ADC (primary groups/channels)8/648/645/408/648/645/404/26 ADC (secondary groups/channels)4/604/604/604/604/604/604/42 ADC (fast compare channels)8888888 ADC (EDSADC channels)14146141466 CAN (modules/nodes)3/3x43/3x43/3x43/3x43/3x43/3x43/3x4 FlexRay (modules/channels)2/2x22/2x22/2x22/2x22/2x22/2x22/2x2 HSSL modules2222222 ASCLIN modules / with ASC and LIN / with 3-wire SPI12/12/1212/12/1212/12/1112/12/1212/12/1212/12/1112/12/9 QSPI modules / with LVDS3AMU is abbreviated as ASC Modeling Unit. For Additional details about AMU, Contact an Infineon RepresentativeTable 3TCxxx YY step (continued)SAL-TC399XX-256F300SSAL-TC399XP-256F300SSAL-TC397XP-256F300SSAK-TC399XP-256F300SSAK-TC399XX-256F300SSAK-TC397XP-256F300SSAK-TC397XA-256F300S6/26/26/26/26/26/26/1 SENT channels25252025252017 MSC modules4424421 PSI5 channels4444444 PSI5-S moduleYes Yes Yes Yes Yes Yes Yes SDMMC moduleYes Yes Yes Yes Yes Yes Yes Maximum Ethernet availability: 1GBit/100Mbit/No1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s MCDS availabilityMCDS MCDS MCDS MCDS MCDS MCDS MCDS ADAS cluster availableNo No No No No No Yes HSM availableYes Yes Yes Yes Yes Yes Yes2.2TC39x BC step (part 2)A table of TC39x BC step variants (part 2). Table 4TC39x BC step (part 2)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300SStepBC BC BC BC BC Production statusStandard Standard Customer specific Customer specific Customer specific Package typePG-LFBGA-292PG-LFBGA-292PG-LFBGA-292PG-LFBGA-292PG-LFBGA-292 PinoutADAS LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm LFBGA 0.8 mm Reference siliconTC39x TC39x TC39x TC39x TC39x Temperature range (ambient)-40°C up to +125°C-40°C up to +125°C-40°C up to +125°C-40°C up to +125°C-40°C up to +125°C Chip IDAttention:The value of SCU_CHIPID in the UCODE field contains the default value 0 not the µCode version.0xCC0197920xAF0197920xCD0197920xCF0197920xFF019792 Cores / checker cores4/36/44/44/46/4 Maximum frequency (MHz)300300300300300 Program flash (MB)1016121616 Data flash 0 (single-ended) (KB)10241024102410241024 Total SRAM (without EMEM and Cache) (KB)16962528118420801632 EMEM Size (KB)40964096000 DSPR (KB)240 in CPU0&1; 96other 240 in CPU0&1; 96other240 in CPU0&1; 96other240 in CPU0&1; 96other240 in CPU0&1; 96otherDLMU (KB)Table 4TC39x BC step (part 2) (continued)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300S64 per CPU64 per CPU64 per CPU64 per CPU64 per CPU PSPR (KB)6464646464 LMU (KB)51276807680 DAM (KB)012801280 AMU4)No No No No No ADC (primary groups/channels)4/265/405/405/405/40 ADC (secondary groups/channels)4/424/604/604/604/60 ADC (fast compare channels)88888 ADC (EDSADC channels)66666 CAN (modules/nodes)3/3x43/3x43/3x43/3x43/3x4 FlexRay (modules/channels)2/2x22/2x22/2x22/2x22/2x2 HSSL modules22222 ASCLIN modules / with ASC and LIN / with 3-wire SPI12/12/912/12/1112/12/1112/12/1112/12/11 QSPI modules / with LVDS6/16/26/26/26/2 SENT channels1720202020 MSC modules12222 4AMU is abbreviated as ASC Modeling Unit. For Additional details about AMU, Contact an Infineon RepresentativeTable 4TC39x BC step (part 2) (continued)SAK-TC397QA-160F300SSAK-TC397XX-256F300SSAK-TC397QP-192F300SSAK-TC397QP-256F300SSAK-TC397XZ-256F300SPSI5 channels44444 PSI5-S moduleYes Yes Yes Yes Yes SDMMC moduleYes Yes Yes Yes Yes Maximum Ethernet availability: 1GBit/100Mbit/No1Gbit/s1Gbit/s1Gbit/s1Gbit/s1Gbit/s MCDS availabilityMCDS MCDS MCDS MCDS MCDS ADAS cluster availableYes No No No No HSM availableYes Yes Yes Yes Yes3Memory maps of TC39x variantsThis section describes the influence of the available feature variants on the memory map.Program FlashVariants:•16 MB: umbrella (5 x 3 MB, 1 x 1 MB), see User's Manual.•12 MB: 4 x 3 MB (see Figure below).•10 MB: 3 + 2 + 3 + 2 MB (see Figure below).Figure 1TC39x PFlash variantsCores / checker coresVariants:•6/4: umbrella, see User's Manual•4/4: not available are CPU4 and CPU5 including their RAMs (DSPR, DCACHE, DTAG, PSPR, PCACHE, PTAG, DLMU)•4/3: not available are CPU4 and CPU5 including their RAMs (DSPR, DCACHE, DTAG, PSPR, PCACHE, PTAG, DLMU) and CPU3 lockstep is not available (LCLCON1.LSEN3 must stay 0B).LMUVariants:•768 KB: umbrella, see User's Manual.•512 KB: only LMU0 and LMU1 LMU RAM are available (see Figure below).•0 KB: no LMURAM is available (see Figure below)Figure 2TC39x LMU VariantsDAMVariants:•128 KB: umbrella, see User's Manual•0 KB: none of the DAM RAMs are availableADAS cluster availableVariants:•Yes: umbrella, see User's Manual•No: the following instances are not available: HSPDM, RIF0, RIF1, SPU0, SPU1, SPUCFG0, SPUCFG1, SPU Lockstep SFR.EMEM availabilityVariants:•4096 KB: umbrella, see User's Manual.•0 KB: no EMEM available.ADC availability•Limitation on availability of ADC channels are caused by pin limitations. See Data Sheet for the pinning table of the package.Revision historyDocument version Date ofreleaseDescription of changesV1.02018-06-08•First release.V1.12018-08-06•Added row "Reference Silicon" (needed e.g. for TC37x) to refer user toUser's Manual Appx.V1.22019-03-01•In "About this document": Corrected "overloaded" to "overlaid".•In "About this document": Added Feature Package "M" and "E" andremove "R".•In "About this document": Added clarification concerning AGBT in E, A andT.•In "About this document": Removed feature packages B, C, H.•In "Variant Tables of TC39x": added device "SAK-TC397XM-256F300S"•In "Variant Tables of TC39x": added Feature Package "E" devices(Emulation Devices).V1.32019-06-12•Added the TC39x "BD" step Variants to Chapter 1•Removed the following Variants SAK-TC397XT-25 6F300S, SAK-TC397TT-256F300S for "BC" Step, Chapter 2•Chapter 1 and 2: TC39x Bx step variants table format changed to fit all thecontents.•Chapter 1 and 2:Added new row in the variant tables called "AMU" withthe footnote for additional details.•Chapter: About this document: Feature package definitions are updatedto consistent with the product naming nomenclature definition. Revision historyTrademarksAll referenced product or service names and trademarks are the property of their respective owners.Edition 2019-06Published byInfineon Technologies AG 81726 Munich, Germany© 2019 Infineon Technologies AG All Rights Reserved.Do you have a question about any aspect of this document? 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常用开关电源芯片大全第1 章DC-DC 电源转换器/ 基准电压源1.1 DC-DC 电源转换器1. 低噪声电荷泵DC-DC 电源转换器AAT3113/AAT31142. 低功耗开关型DC-DC 电源转换器ADP30003. 高效3A 开关稳压器AP15014. 高效率无电感DC-DC 电源转换器FAN56605. 小功率极性反转电源转换器ICL76606. 高效率DC-DC 电源转换控制器IRU30377. 高性能降压式DC-DC 电源转换器ISL64208. 单片降压式开关稳压器L49609. 大功率开关稳压器L4970A10.1.5A 降压式开关稳压器L497111.2A 高效率单片开关稳压器L497812.1A 高效率升压/降压式DC-DC 电源转换器L597013.1.5A 降压式DC-DC 电源转换器LM157214. 高效率1A 降压单片开关稳压器LM1575/LM2575/LM2575HV15.3A 降压单片开关稳压器LM2576/LM2576HV16. 可调升压开关稳压器LM257717.3A 降压开关稳压器LM259618. 高效率5A 开关稳压器LM267819. 升压式DC-DC 电源转换器LM2703/LM270420. 电流模式升压式电源转换器LM273321. 低噪声升压式电源转换器LM275022. 小型75V 降压式稳压器LM500723. 低功耗升/降压式DC-DC 电源转换器LT107324. 升压式DC-DC 电源转换器LT161525. 隔离式开关稳压器LT172526. 低功耗升压电荷泵LT175127. 大电流高频降压式DC-DC 电源转换器LT176528. 大电流升压转换器LT193529. 高效升压式电荷泵LT193730. 高压输入降压式电源转换器LT195631.1.5A 升压式电源转换器LT196132. 高压升/降压式电源转换器LT343333. 单片3A 升压式DC-DC 电源转换器LT343634. 通用升压式DC-DC 电源转换器LT346035. 高效率低功耗升压式电源转换器LT346436.1.1A 升压式DC-DC 电源转换器LT346737. 大电流高效率升压式DC-DC 电源转换器LT378238. 微型低功耗电源转换器LTC175439.1.5A 单片同步降压式稳压器LTC187540. 低噪声高效率降压式电荷泵LTC191141. 低噪声电荷泵LTC3200/LTC3200-542. 无电感的降压式DC-DC 电源转换器LTC325143. 双输出/低噪声/降压式电荷泵LTC325244. 同步整流/升压式DC-DC 电源转换器LTC340145. 低功耗同步整流升压式DC-DC 电源转换器LTC340246. 同步整流降压式DC-DC 电源转换器LTC340547. 双路同步降压式DC-DC 电源转换器LTC340748. 高效率同步降压式DC-DC 电源转换器LTC341649. 微型2A 升压式DC-DC 电源转换器LTC342650.2A 两相电流升压式DC-DC 电源转换器LTC342851. 单电感升/降压式DC-DC 电源转换器LTC344052. 大电流升/降压式DC-DC 电源转换器LTC344253.1.4A 同步升压式DC-DC 电源转换器LTC345854. 直流同步降压式DC-DC 电源转换器LTC370355. 双输出降压式同步DC-DC 电源转换控制器LTC373656. 降压式同步DC-DC 电源转换控制器LTC377057. 双2相DC-DC 电源同步控制器LTC380258. 高性能升压式DC-DC 电源转换器MAX1513/MAX151459. 精简型升压式DC-DC 电源转换器MAX1522/MAX1523/MAX152460. 高效率40V 升压式DC-DC 电源转换器MAX1553/MAX155461. 高效率升压式LED 电压调节器MAX1561/MAX159962. 高效率5路输出DC-DC 电源转换器MAX156563. 双输出升压式DC-DC 电源转换器MAX1582/MAX1582Y64. 驱动白光LED 的升压式DC-DC 电源转换器MAX158365. 高效率升压式DC-DC 电源转换器MAX1642/MAX164366.2A 降压式开关稳压器67. 高效率升压式DC-DC MAX1644电源转换器MAX1674/MAX1675/MAX167668. 高效率双输出DC-DC 电源转换器MAX167769. 低噪声1A 降压式DC-DC 电源转换器MAX1684/MAX168570. 高效率升压式DC-DC 电源转换器MAX169871. 高效率双输出降压式DC-DC 电源转换器MAX171572. 小体积升压式DC-DC 电源转换器MAX1722/MAX1723/MAX172473. 输出电流为50mA 的降压式电荷泵MAX173074. 升/降压式电荷泵MAX175975. 高效率多路输出DC-DC 电源转换器MAX180076.3A 同步整流降压式稳压型MAX1830/MAX183177. 双输出开关式LCD 电源控制器MAX187878. 电流模式升压式DC-DC 电源转换器MAX189679. 具有复位功能的升压式DC-DC 电源转换器MAX194780. 高效率PWM 降压式稳压器MAX1992/MAX199381. 大电流输出升压式DC-DC 电源转换器MAX61882. 低功耗升压或降压式DC-DC 电源转换器MAX62983.PWM 升压式DC-DC 电源转换器MAX668/MAX66984. 大电流PWM 降压式开关稳压器MAX724/MAX72685. 高效率升压式DC-DC 电源转换器MAX756/MAX75786. 高效率大电流DC-DC 电源转换器MAX761/MAX76287. 隔离式DC-DC 电源转换器MAX8515/MAX8515A88. 高性能24V 升压式DC-DC 电源转换器MAX872789. 升/降压式DC-DC 电源转换器MC33063A/MC34063A90.5A 升压/降压/反向DC-DC 电源转换器MC33167/MC3416791. 低噪声无电感电荷泵MCP1252/MCP125392. 高频脉宽调制降压稳压器MIC220393. 大功率DC-DC 升压电源转换器MIC229594. 单片微型高压开关稳压器NCP1030/NCP103195. 低功耗升压式DC-DC 电源转换器NCP1400A96. 高压DC-DC 电源转换器NCP140397. 单片微功率高频升压式DC-DC 电源转换器NCP141098. 同步整流PFM 步进式DC-DC 电源转换器NCP142199. 高效率大电流开关电压调整器NCP1442/NCP1443/NCP1444/NCP1445 100. 新型双模式开关稳压器NCP1501101. 高效率大电流输出DC-DC 电源转换器NCP1550102. 同步降压式DC-DC 电源转换器NCP1570103. 高效率升压式DC-DC 电源转换器NCP5008/NCP5009104. 大电流高速稳压器RT9173/RT9173A105. 高效率升压式DC-DC 电源转换器RT9262/RT9262A106. 升压式DC-DC 电源转换器SP6644/SP6645107. 低功耗升压式DC-DC 电源转换器SP6691108. 新型高效率DC-DC 电源转换器TPS54350109. 无电感降压式电荷泵TPS6050x110. 高效率升压式电源转换器TPS6101x111.28V 恒流白色LED 驱动器TPS61042112. 具有LDO 输出的升压式DC-DC 电源转换器TPS6112x113. 低噪声同步降压式DC-DC 电源转换器TPS6200x114. 三路高效率大功率DC-DC 电源转换器TPS75003115. 高效率DC-DC 电源转换器UCC39421/UCC39422116. P WM 控制升压式DC-DC 电源转换器XC6371117. 白光LED 驱动专用DC-DC 电源转换器XC9116118.500mA 同步整流降压式DC-DC 电源转换器XC9215/XC9216/XC9217 119. 稳压输出电荷泵XC9801/XC9802120. 高效率升压式电源转换器ZXLB16001.2线性/ 低压差稳压器121. 具有可关断功能的多端稳压器BAXXX122. 高压线性稳压器HIP5600123. 多路输出稳压器KA7630/KA7631124. 三端低压差稳压器LM2937125. 可调输出低压差稳压器LM2991126. 三端可调稳压器LM117/LM317127. 低压降CMOS500mA 线性稳压器LP38691/LP38693 128. 输入电压从12V 到450V 的可调线性稳压器LR8 129.300mA 非常低压降稳压器（VLDO ）LTC3025 130. 大电流低压差线性稳压器LX8610131.200mA 负输出低压差线性稳压器MAX1735132.150mA 低压差线性稳压器MAX8875133. 带开关控制的低压差稳压器MC33375134. 带有线性调节器的稳压器MC33998135.1.0A 低压差固定及可调正稳压器NCP1117136. 低静态电流低压差稳压器NCP562/NCP563137. 具有使能控制功能的多端稳压器PQxx138. 五端可调稳压器SI-3025B/SI-3157B139.400mA 低压差线性稳压器SPX2975140. 五端线性稳压器STR20xx141. 五端线性稳压器STR90xx142. 具有复位信号输出的双路输出稳压器TDA8133143. 具有复位信号输出的双路输出稳压器TDA8138/TDA8138A 144. 带线性稳压器的升压式电源转换器TPS6110x145. 低功耗50mA 低压降线性稳压器TPS760xx146. 高输入电压低压差线性稳压器XC6202147. 高速低压差线性稳压器XC6204148. 高速低压差线性稳压器XC6209F149. 双路高速低压差线性稳压器XC64011.3基准电压源150. 新型XFET 基准电压源ADR290/ADR291/ADR292/ADR293 151. 低功耗低压差大输出电流基准电压源MAX610x152. 低功耗1.2V 基准电压源MAX6120153.2.5V 精密基准电压源MC1403154.2.5V/4.096V 基准电压源MCP1525/MCP1541155. 低功耗精密低压降基准电压源REF30xx/REF31xx156. 精密基准电压源TL431/KA431/TLV431A第2章AC-DC 转换器及控制器1. 厚膜开关电源控制器DP104C2. 厚膜开关电源控制器DP308P3. D PA-Switch 系列高电压功率转换控制器DPA423/DPA424/DPA425/DPA4264. 电流型开关电源控制器FA13842/FA13843/FA13844/FA138455. 开关电源控制器FA5310/FA53116. P WM 开关电源控制器FAN75567. 绿色环保的PWM 开关电源控制器FAN76018. F PS 型开关电源控制器FS6M07652R9. 开关电源功率转换器FS6Sxx10. 降压型单片AC-DC 转换器HV-2405E11. 新型反激准谐振变换控制器ICE1QS0112. P WM 电源功率转换器KA1M088013. 开关电源功率转换器KA2S0680/KA2S088014. 电流型开关电源控制器KA38xx15.FPS 型开关电源功率转换器KA5H0165R16.FPS 型开关电源功率转换器KA5Qxx17.FPS 型开关电源功率转换器KA5Sxx18. 电流型高速PWM 控制器L499019. 具有待机功能的PWM 初级控制器L599120. 低功耗离线式开关电源控制器L659021. L INK SWITCH TN 系列电源功率转换器LNK304/LNK305/LNK30622. L INK SWITCH 系列电源功率转换器LNK500/LNK501/LNK52023. 离线式开关电源控制器M51995A24. P WM 电源控制器M62281P/M62281FP25. 高频率电流模式PWM 控制器MAX5021/MAX502226. 新型PWM 开关电源控制器MC4460427. 电流模式开关电源控制器MC4460528. 低功耗开关电源控制器MC4460829. 具有PFC 功能的PWM 电源控制器ML482430. 液晶显示器背光灯电源控制器ML487631. 离线式电流模式控制器NCP120032. 电流模式脉宽调制控制器NCP120533. 准谐振式PWM 控制器NCP120734. 低成本离线式开关电源控制电路NCP121535. 低待机能耗开关电源PWM 控制器NCP123036. S TR 系列自动电压切换控制开关STR8xxxx37. 大功率厚膜开关电源功率转换器STR-F665438. 大功率厚膜开关电源功率转换器STR-G865639. 开关电源功率转换器STR-M6511/STR-M652940. 离线式开关电源功率转换器STR-S5703/STR-S5707/STR-S570841. 离线式开关电源功率转换器STR-S6401/STR-S6401F/STR-S6411/STR-S6411F 442. 开关电源功率转换器STR-S651343. 离线式开关电源功率转换器TC33369 ～TC3337444. 高性能PFC 与PWM 组合控制集成电路TDA16846/TDA1684745. 新型开关电源控制器TDA1685046. “绿色”电源控制器TEA150447. 第二代“绿色”电源控制器TEA150748. 新型低功耗“绿色”电源控制器TEA153349. 开关电源控制器TL494/KA7500/MB375950.Tiny Switch Ⅰ系列功率转换器TNY253 、TNY254 、TNY25551.Tiny Switch Ⅱ系列功率转换器TNY264P ～TNY268G52.TOP Switch （Ⅱ）系列离线式功率转换器TOP209 ～TOP22753.TOP Switch-FX 系列功率转换器TOP232/TOP233/TOP23454.TOP Switch-GX 系列功率转换器TOP242 ～T OP25055.开关电源控制器UCX84X56.离线式开关电源功率转换器VIPer12AS/VIPer12ADIP57.新一代高度集成离线式开关电源功率转换器VIPer53 第3章功率因数校正控制/节能灯电源控制器1. 电子镇流器专用驱动电路BL83012. 零电压开关功率因数控制器FAN48223. 功率因数校正控制器FAN75274. 高电压型EL 背光驱动器HV8265. E L 场致发光背光驱动器IMP525/IMP5606. 高电压型EL 背光驱动器/反相器IMP8037. 电子镇流器自振荡半桥驱动器IR21568. 单片荧光灯镇流器IR21579. 调光电子镇流器自振荡半桥驱动器IR215910. 卤素灯电子变压器智能控制电路IR216111. 具有功率因数校正电路的镇流器电路IR216612. 单片荧光灯镇流器IR216713. 自适应电子镇流器控制器IR252014. 电子镇流器专用控制器KA754115. 功率因数校正控制器L656116. 过渡模式功率因数校正控制器L656217. 集成背景光控制器MAX8709/MAX8709A18. 功率因数校正控制器MC33262/MC3426219. 固定频率电流模式功率因数校正控制器NCP165320. E L 场致发光灯高压驱动器SP440321. 功率因数校正控制器TDA4862/TDA486322. 有源功率因数校正控制器UC385423. 高频自振荡节能灯驱动器电路VK05CFL24. 大功率高频自振荡节能灯驱动器电路VK06TL第4章充电控制器1. 多功能锂电池线性充电控制器AAT36802. 可编程快速电池充电控制器BQ20003. 可进行充电速率补偿的锂电池充电管理器BQ20574. 锂电池充电管理电路BQ2400x5. 单片锂电池线性充电控制器BQ2401x6. U SB 接口单节锂电池充电控制器BQ2402x7.2A 同步开关模式锂电池充电控制器BQ241008. 集成PWM 开关控制器的快速充电管理器BQ29549. 具有电池电量计量功能的充电控制器DS277010. 锂电池充电控制器FAN7563/FAN756411.2A 线性锂/锂聚合物电池充电控制器ISL629212. 锂电池充电控制器LA5621M/LA5621V13.1.5A 通用充电控制器LT157114.2A 恒流/恒压电池充电控制器LT176915. 线性锂电池充电控制器LTC173216. 带热调节功能的1A 线性锂电池充电控制器LTC173317. 线性锂电池充电控制器LTC173418. 新型开关电源充电控制器LTC198019. 开关模式锂电池充电控制器LTC400220.4A 锂电池充电器LTC400621. 多用途恒压/恒流充电控制器LTC400822.4.2V 锂离子/锂聚合物电池充电控制器LTC405223. 可由USB 端口供电的锂电池充电控制器LTC405324. 小型150mA 锂电池充电控制器LTC405425. 线性锂电池充电控制器LTC405826. 单节锂电池线性充电控制器LTC405927. 独立线性锂电池充电控制器LTC406128. 镍镉/ 镍氢电池充电控制器M62256FP29. 大电流锂/镍镉/镍氢电池充电控制器MAX150130. 锂电池线性充电控制器MAX150731. 双输入单节锂电池充电控制器MAX1551/MAX155532. 单节锂电池充电控制器MAX167933. 小体积锂电池充电控制器MAX173634. U SB 接口单节锂电池充电控制器MAX181135. 多节锂电池充电控制器MAX187336. 双路输入锂电池充电控制器MAX187437. 单节锂电池线性充电控制器MAX189838. 低成本/多种电池充电控制器MAX190839. 开关模式单节锂电池充电控制器MAX1925/MAX192640. 快速镍镉/镍氢充电控制器MAX2003A/MAX200341. 可编程快速充电控制器MAX712/MAX71342. 开关式锂电池充电控制器MAX74543. 多功能低成本充电控制器MAX846A44. 具有温度调节功能的单节锂电池充电控制器MAX8600/MAX860145. 锂电池充电控制器MCP73826/MCP73827/MCP7382846. 高精度恒压/ 恒流充电器控制器MCP73841/MCP73842/MCP73843/MCP73844 647. 锂电池充电控制器MCP73861/MCP7386248. 单节锂电池充电控制器MIC7905049. 单节锂电池充电控制器NCP180050. 高精度线性锂电池充电控制器VM7205Welcome To Download !!!欢迎您的下载，资料仅供参考！。