【EP3553939A1】SEMICONDUCTORDEVICEMOTORDRIVESYSTEMAN

Embedded Multi-Media Card(e•MMC™ 5.1)EMMC16G-IB29-PE90EMMC32G-IB29-PE90EMMC64G-IB29-PE90v1.0Product Features•Packaged managed NAND flash memory with e•MMC™ 5.1 interface•Backward compatible with all prior e•MMC™ specification revisions•153-ball JEDEC FBGA RoHS Compliant package•Operating voltage range:o VCCQ = 1.8 V/3.3 Vo VCC = 3.3 V•Operating Temperature (T case) - 40C to +85C•Storage Temperature -55C to +85C•Compliant with e•MMC™ 5.1 JEDEC Standard Number JESD84-B51•Factory configured with pseudo Single Level Cell (pSLC) mode for enhanced reliability and performance•Factory configured with reliable writee•MMC™ Specific Feature Support•High-speed e•MMC™ protocol•Variable clock frequencies of 0-200MHz•Ten-wire bus interface (clock, 1 bit command, 8 bit data bus) with an optional hardware reset •Supports three different data bus widths: 1 bit(default), 4 bits, 8 bits•Bus Modes:o Single data transfer rate: up to 52MB/s (using 8 parallel data lines at 52MHz)o Dual data rate mode (DDR-104) : up to 104MB/s @ 52MHzo High speed, single data rate mode (HS-200) : up to 200MB/s @ 200MHzo High speed, dual data rate mode (HS-400) : up to 400MB/s @ 200MHz•Supports alternate boot operation mode to provide a simple boot sequence methodo Supports SLEEP/AWAKE (CMD5)o Host initiated explicit sleep mode for power saving•Enhanced write protection with permanent and partial protection options•Multiple user data partition with enhanced attribute for increased reliability•Error free memory accesso Cyclic Redundancy Code (CRC) for reliable command and data communicationo Internal error correction code (ECC) for improved data storage integrityo Internal enhanced data management algorithmo Data protection for sudden power failure during program operations•Securityo Secure bad block erase commandso Enhanced write protection with permanent and partial protection options•Power off notification for sleep•Field firmware update (FFU)•Production state awareness•Device health report•Command queuing•Enhanced strobe•Cache flushing report•Cache barrier•Background operation control & High Priority Interrupt (HPI)•RPMB throughput improvement•Secure write protection•Pre EOL information•Optimal sizeProduct DescriptionKingston’s e•MMC™ products conform to the JEDEC e•MMC™ 5.1standard. These devices are an ideal universal storage solution for many commercial and industrial applications. In a single integrated packaged device, e•MMC™ combines triple-level cell (TLC) NAND flash memory with an onboard e•MMC™ controller, providing an industry standard interface to the host system. The integrated e•MMC™ controller directly manages NAND flash media which relieves the host processor of these tasks, including flash media error control, wear-leveling, NAND flash management and performance optimization. Future revision to the JEDEC e•MMC™ standard will always maintain backward compatibility. The industry standard interface to the host processor ensures compatibility across future NAND flash generations as well, easing product sustainment throughout the product life cycle. ConfigurationsKingston’s e•MMC™ products support a variety of configurations that allow the e•MMC™ device to be tailored to your specific application needs. The most popular configurations described below are each offered under standard part numbers.Standard TLC – By default the e•MMC™ device is configured with the NAND flash in a standard TLC mode. This configuration provides reasonable performance and reliability for many applications. Pseudo Single Level Cell (pSLC) – The TLC NAND flash in the Kingston e•MMC™ device can be configured to further improve device endurance, data retention, reliability and performance over the standard TLC configuration. This is done by converting the NAND TLC cells to a pseudo single level cell (SLC) configuration. In this configuration, along with the performance and reliability gains, the device capacity is reduced by 2/3 of the capacity. This one-time configuration is achieved by setting the e•MMC™ enhanced attribute for the hardware partition.Kingston e•MMC™ can be ordered preconfigured with the option of reliable write or pSLC at no additional cost. Standard TLC devices can also be one-time configured in-field by following the procedures outlined in the JEDEC e•MMC™ specification. The JEDEC e•MMC™ specification allows for many additional configurations such as up to 4 additional general purpose (GPn) hardware partitions each with the option to support pSLC and reliable write. Additionally, Kingston provides a content loading service that can streamline your product assembly while reducing production costs. For more information, contact your Kingston representative.Kingston e•MMC™ devices are fully compliant with the JEDEC Standard Specification No. JESD84-B51. This datasheet provides technical specifications for Kingston’s family of e•MMC™ devices. Refer to the JEDEC e•MMC™ standard for specific information related to e•MMC™ device function and operation. See: /sites/default/files/docs/JESD84-B51.pdfe•MMC™ Mode and ControllerTLC mode using PS8229 - Leading edge 3D NAND flash technology in TLC mode rated to 3,000 endurance cycles.- Strong data protection with LDPC Error control- Improved data integrity with end-to-end data protection.pSLC mode using PS8229 - Leading edge 3D NAND flash technology in pSLC mode.- Strong data protection with LDPC Error control- Improved data integrity with end-to-end data protection.Part NumberingFigure 1 – Part Number FormatEMMC 16G - xxxx - PE90A B C DPart Number FieldsA: Product Family : EMMCB: Device Capacity : Available capacities of 16GB – 64GBC: Hardware Revision and ConfigurationD: Device Firmware Revision and ConfigurationTable 1 - Device SummaryDevice PerformanceTable 2 below provides sequential read and write speeds for all capacities. Performance numbers can vary under different operating conditions. Values are given at HS400 bus mode. Contact your Kingston Representative for performance numbers using other bus modes.Power ConsumptionDevice current consumption for various device configurations is defined in the power class fields of the EXT_CSD register. Power consumption values are summarized in Table 3 below.Device and Partition CapacityThe device NAND flash capacity is divided across two boot partitions (2048 KB each), a Replay Protected Memory Block (RPMB) partition (512 KB), and the main user storage area. Four additional general purpose storage partitions can be created from the user partition. These partitions can be factory preconfigured or configured in-field by following the procedure outlined in section 6.2 of the JEDEC e•MMC™ specification JESD84-B51. A small portion of the NAND storage capacity is used for the storage of the onboard controller firmware and mapping tables. Additionally, several NAND blocks are held in reserve to boost performance and extend the life of the e•MMC™ device. Table 4 identifies the specific capacity of each partition. This information is reported in the device EXT_CSD register. The contents of this register are also listed in the Appendix.e•MMC™ Bus ModesKingston e•MMC™ devices support all bus modes defined in the JEDEC e•MMC™ 5.1 specification. These modes are summarized in Table 6 below.Signal DescriptionTable 7 - e•MMC™ Signals Name Type DescriptionCLK I Clock: Each cycle of this signal directs a one bit transfer on the command and either a one bit (1x) or a two bits transfer (2x) on all the data lines. The frequency may vary between zero and the maximum clock frequency.DAT[7:0] I/O/PP Data: These are bidirectional data channels. The DAT signals operate in push-pull mode. These bidirectional signals are driven by either the e•MMC™ device or the host controller. By default, after power up or reset, only DAT0 is used for data transfer. A wider data bus can be configured for data transfer, using either DAT0-DAT3 or DAT0-DAT7, by the e•MMC™ host controller. The e•MMC™ device includes internal pull-ups for data lines DAT1-DAT7. Immediately after entering the 4-bit mode, the device disconnects the internal pull ups of lines DAT1, DAT2, and DAT3. Correspondingly, immediately after entering to the 8-bit mode, the device disconnects the internal pull-ups of lines DAT1–DAT7.CMD I/O/PP/OD Command: This signal is a bidirectional command channel used for device initialization and transfer of commands. The CMD signal has two operation modes: open-drain for initialization mode, and push-pull for fast command transfer. Commands are sent from the e•MMC™ host controller to the e•MMC™ device and responses are sent from the device to the host.DS O This signal is generated by the device and used for output in HS400 mode. The frequency of this signal follows the frequency of CLK. For data output each cycle of this signal directs two bits transfer(2x) on the data - one bit for positive edge and the other bit for negative edge. For CRC status response output and CMD response output (enabled only HS400 enhanced strobe mode), the CRC status and CMD Response are latched on the positive edge only, and don't care on the negative edge.RST_n I Hardware Reset: By default, hardware reset is disabled and must be enabled in the EXT_CSD register if used. Otherwise, it can be left un-connected.RFU - Reserved for future use: These pins are not internally connected. Leave floatingNC - Not Connected: These pins are not internally connected. Signals can be routed through these balls to ease printed circuit board design. See Kingston’s Design Guidelines for further details.VSF - Vendor Specific Function: These pins are not internally connectedVddi - Internal Voltage Node: Note that this is not a power supply input. This pin provides access to the output of an internal voltage regulator to allow for the connection of an external Creg capacitor. See Kingston’s Design Guidelines for further details.Vcc S Supply voltage for core Vccq S Supply voltage for I/ODesign GuidelinesDesign guidelines are outlined in a separate document. Contact your Kingston Representative for more information.Package DimensionsFigure 2 – Package DimensionsFigure 3 – Ball Pattern DimensionsBall Assignment (153 ball)Table 8 – Ball Assignment, Top View (HS400)1 2 3 4 5 6 7 8 9 10 11 12 13 14A NC NC DAT0 DAT1 DAT2 Vss RFU NC NC NC NC NC NC NC AB NC DAT3 DAT4 DAT5 DAT6 DAT7 NC NC NC NC NC NC NC NC BC NC Vddi NC Vssq NC Vccq NC NC NC NC NC NC NC NC CD NC NC NC NC NC NC NC DE NC NC NC RFU Vcc Vss VSF VSF VSF NC NC NC EF NC NC NC Vcc VSF NC NC NC FG NC NC RFU Vss VSF NC NC NC GH NC NC NC DS Vss NC NC NC H J NC NC NC Vss Vcc NC NC NC J K NC NC NC RST_n RFU RFU Vss Vcc VSF NC NC NC K L NC NC NC NC NC NC L M NC NC NC Vccq CMD CLK NC NC NC NC NC NC NC NC M N NC Vssq NC Vccq Vssq NC NC NC NC NC NC NC NC NC N P NC NC Vccq Vssq Vccq Vssq RFU NC NC RFU NC NC NC NC P1 2 3 4 5 6 7 8 9 10 11 12 13 14 Note: VSF, RFU and NC balls are not electrically connected. RFU balls may be defined with functionality by the Joint Electron Device Engineering Council (JEDEC) in future revisions of the e•MMC™ standard. Please refer to Kingston’s design guidelines for more info.Device MarkingFigure 4 - EMMC Package Marking240xxxx-xxx.xxxxYYWW PPPPPPPPxxxxxxx-xxxx2xxxxxxTAIWANKingston Logo240xxxx-xxx.xxxx：Internal control numberYYWW：Date code (YY– Last 2 digits ofyear, WW- Work week)PPPPPPPP： Internal control numberxxxxxxx-xxxx Sales P/N2xxxxxx : Internal control numberCountry：TAIWANCard Identification Register (CID)The Card Identification (CID) register is a 128-bit register that contains device identification information used during the e•MMC™ protocol device identification phase. Refer to JEDEC Standard Specification No.JESD84-B51 for details.Field Byte ValueMID [127:120] 0x70reserved [119:114] 0x00CBX [113:112] 0x01OID [111:104] 0x00PNM [103:56 ] IB2916(16G) IB2932(32G) IB2964(64G)PRV [ 55:48 ] 0x90PSN [ 47:16 ] RandomMDT [ 15:8 ] month, yearCRC [ 7:1 ] Follows JEDEC Standard reserved [ 0:0 ] 0x01Card Specific Data Register [CSD]The Card-Specific Data (CSD) register provides information on how to access the contents stored in e•MMC™. The CSD registers are used to define the error correction type, maximum data access time, data transfer speed, data format…etc. For details, refer to section 7.3 of the JEDEC Standard Specification No.JESD84-B51.Field Byte ValueCSD_Structure [127:126] 0x03 (V2.0)SPEC_VER [125:122] 0x04 (V4.0~4.2)reserved [121:120] 0x00TAAC [119:112] 0x4F (40ms)NSAC [111:104] 0x01TRAN_SPEED [103:96 ] 0x32 (26Mbit/s)CCC [ 95:84 ] 0x0F5READ_BL_LEN [ 83:80 ] 0x09 (512 Bytes)READ_BL_PARTIAL [ 79:79 ] 0x00WRITE_BLK_MISALIGN [ 78:78 ] 0x00READ_BLK_MISALIGN [ 77:77 ] 0x00DSR_IMP [ 76:76 ] 0x00reserved [ 75:74 ] 0x00C_SIZE [ 73:62 ] 0xFFFVDD_R_CURR_MIN [ 61:59 ] 0x07 (100mA)VDD_R_CURR_MAX [ 58:56 ] 0x07 (200mA)VDD_W_CURR_MIN [ 55:53 ] 0x07 (100mA)VDD_W_CURR_MAX [ 52:50 ] 0x07 (200mA)C_SIZE_MULT [ 49:47 ] 0x07 (512 Bytes)ERASE_GRP_SIZE [ 46:42 ] 0x1FERASE_GRP_MULT [ 41:37 ] 0x1FWP_GRP_SIZE [ 36:32 ] 0x0FWP_GRP_ENABLE [ 31:31 ] 0x01DEFAULT_ECC [ 30:29 ] 0x00R2W_FACTOR [ 28:26 ] 0x02WRITE_BL_LEN [ 25:22 ] 0x09 (512 Bytes)WRITE_BL_PARTIAL [ 21:21 ] 0x00reserved [ 20:17 ] 0x00CONTENT_PROT_APP [ 16:16 ] 0x00FILE_FORMAT_GRP [ 15:15 ] 0x00COPY [ 14:14 ] 0x00PERM_WRITE_PROTECT [ 13:13 ] 0x00TMP_WRITE_PROTECT [ 12:12 ] 0x00FILE_FORMAT [ 11:10 ] 0x00Field Byte ValueECC [ 9:8 ] 0x00CRC [ 7:1 ] Follow JEDEC Standard reserved [ 0:0 ] 0x01Extended Card Specific Data Register [EXT_CSD]The Extended CSD register defines the Device properties and selected modes. It is 512 bytes long. The most significant 320 bytes are the Properties segment, which defines the Device capabilities and cannot be modified by the host. The lower 192 bytes are the Modes segment, which defines the configuration the Device is working in. These modes can be changed by the host by means of the SWITCH command. For details, refer to section 7.4 of the JEDEC Standard Specification No.JESD84-B51.Field Byte ValueReserved [511:506] 0EXT_SECURITY_ERR [505:505] 0x00S_CMD_SET [504:504] 0x01HPI_FEATURES [503:503] 0x01BKOPS_SUPPORT [502:502] 0x01MAX_PACKED_READS [501:501] 0x3CMAX_PACKED_WRITES [500:500] 0x20DATA_TAG_SUPPORT [499:499] 0x01TAG_UNIT_SIZE [498:498] 0x03TAG_RES_SIZE [497:497] 0x00CONTEXT_CAPABILITIES [496:496] 0x05LARGE_UNIT_SIZE_M1 [495:495] 0x17(16G) 0x2F(32G) 0x5F(64G)EXT_SUPPORT [494:494] 0x03 SUPPORTED_MODES [493:493] 0x01FFU_FEATURES [492:492] 0x00 OPERATION_CODE_TIMEOUT [491:491] 0x00FFU_ARG [490:487] 65535 BARRIER_SUPPORT [486:486] 0x01Reserved [485:309] 0CMDQ_SUPPORT [308:308] 0x01CMDQ_DEPTH [307:307] 0x0FReserved [306:306] 0x00 NUMBER_OF_FW_SECTORS_CORRECTLY_PROGRAMMED [305:302] 0 VENDOR_PROPRIETARY_HEALTH_REPORT [301:270] 0 DEVICE_LIFE_TIME_EST_TYP_B [269:269] 0x01DEVICE_LIFE_TIME_EST_TYP_A [268:268] 0x01PRE_EOL_INFO [267:267] 0x01 OPTIMAL_READ_SIZE [266:266] 0x01OPTIMAL_WRITE_SIZE [265:265] 0x08Field Byte Value OPTIMAL_TRIM_UNIT_SIZE [264:264] 0x01 DEVICE_VERSION [263:262] 0FIRMWARE_VERSION [261:254] 0x90 PWR_CL_DDR_200_360 [253:253] 0x00 CACHE_SIZE [252:249] 1024 GENERIC_CMD6_TIME [248:248] 0x32 POWER_OFF_LONG_TIME [247:247] 0xFF BKOPS_STATUS [246:246] 0x00 CORRECTLY_PRG_SECTORS_NUM [245:242] 0 INI_TIMEOUT_AP [241:241] 0x64 CACHE_FLUSH_POLICY [240:240] 0x01 PWR_CL_DDR_52_360 [239:239] 0x00 PWR_CL_DDR_52_195 [238:238] 0x00PWR_CL_200_195 [237:237] 0x00PWR_CL_200_130 [236:236] 0x00 MIN_PERF_DDR_W_8_52 [235:235] 0x00 MIN_PERF_DDR_R_8_52 [234:234] 0x00 Reserved [233:233] 0x00TRIM_MULT [232:232] 0x11(16G) 0x11(32G) 0x22(64G)SEC_FEATURE_SUPPORT [231:231] 0x55 SEC_ERASE_MULT [230:230] 0xF7 SEC_TRIM_MULT [229:229] 0xF7 BOOT_INFO [228:228] 0x07Reserved [227:227] 0x00 BOOT_SIZE_MULT [226:226] 0x20ACC_SIZE [225:225] 0x07(16G) 0x08(32G) 0x09(64G)HC_ERASE_GRP_SIZE [224:224] 0x01ERASE_TIMEOUT_MULT [223:223] 0x11(16G) 0x11(32G) 0x22(64G)REL_WR_SEC_C [222:222] 0x01HC_WP_GRP_SIZE [221:221] 0x10 S_C_VCC [220:220] 0x08S_C_VCCQ [219:219] 0x08 PRODUCTION_STATE_AWARENESS_TIMEOUT [218:218] 0x14 S_A_TIMEOUT [217:217] 0x15 SLEEP_NOTIFICATION_TIME [216:216] 0x0FField Byte ValueSEC_COUNT [215:212] 10207232 (16G) 20414464 (32G) 40828928 (64G)SECURE_WP_INFO [211:211] 0x01 MIN_PERF_W_8_52 [210:210] 0x08 MIN_PERF_R_8_52 [209:209] 0x08 MIN_PERF_W_8_26_4_52 [208:208] 0x08 MIN_PERF_R_8_26_4_52 [207:207] 0x08 MIN_PERF_W_4_26 [206:206] 0x08 MIN_PERF_R_4_26 [205:205] 0x08 Reserved [204:204] 0x00 PWR_CL_26_360 [203:203] 0x00 PWR_CL_52_360 [202:202] 0x00 PWR_CL_26_195 [201:201] 0x00 PWR_CL_52_195 [200:200] 0x00 PARTITION_SWITCH_TIME [199:199] 0xFF OUT_OF_INTERRUPT_TIME [198:198] 0xFF DRIVER_STRENGTH [197:197] 0x1F DEVICE_TYPE [196:196] 0x57 Reserved [195:195] 0x00 CSD_STRUCTURE [194:194] 0x02 Reserved [193:193] 0x00 EXT_CSD_REV [192:192] 0x08 CMD_SET [191:191] 0x00Reserved [190:190] 0x00 CMD_SET_REV [189:189] 0x00 Reserved [188:188] 0x00 POWER_CLASS [187:187] 0x00 Reserved [186:186] 0x00HS_TIMING [185:185] 0x01 STROBE_SUPPORT [184:184] 0x01 BUS_WIDTH [183:183] 0x02Reserved [182:182] 0x00 ERASED_MEM_CONT [181:181] 0x00 Reserved [180:180] 0x00 PARTITION_CONFIG [179:179] 0x00 BOOT_CONFIG_PROT [178:178] 0x00 BOOT_BUS_CONDITIONS [177:177] 0x00 Reserved [176:176] 0x00 ERASE_GROUP_DEF [175:175] 0x00 BOOT_WP_STATUS [174:174] 0x00C - 4Field Byte Value BOOT_WP [173:173] 0x00 Reserved [172:172] 0x00 USER_WP [171:171] 0x00 Reserved [170:170] 0x00 FW_CONFIG [169:169] 0x00 RPMB_SIZE_MULT [168:168] 0x20 WR_REL_SET [167:167] 0x00 WR_REL_PARAM [166:166] 0x15 SANITIZE_START [165:165] 0x00 BKOPS_START [164:164] 0x00 BKOPS_EN [163:163] 0x00 RST_n_FUNCTION[162:162] 0x00 HPI_MGMT[161:161] 0x00 PARTITIONING_SUPPORT [160:160] 0x07 MAX_ENH_SIZE_MULT [159:157] 623(16G) 1246(32G) 2492(64G) PARTITIONS_ATTRIBUTE[156:156] 0x01 PARTITION_SETTING_COMPLETED[155:155] 0x01 GP_SIZE_MULT_4 [154:152] 0 GP_SIZE_MULT_3 [151:149] 0 GP_SIZE_MULT_2 [148:146] 0 GP_SIZE_MULT_1[145:143] 0 ENH_SIZE_MULT[142:140] 623(16G) 1246(32G) 2492(64G)ENH_START_ADDR[139:136] 0 Reserved[135:135] 0x00 SEC_BAD_BLK_MGMNT[134:134] 0x00 PRODUCTION_STATE_AWARENESS[133:133] 0x00 TCASE_SUPPORT [132:132] 0x00 PERIODIC_WAKEUP[131:131] 0x00 PROGRAM _CID_CSD_DDR_SUPPORT[130:130] 0x01 Reserved[129:128] 0 VENDOR_SPECIFIC_FIELD[127:67 ] 538968064ERROR_CODE [ 66:65 ] 0 ERROR_TYPE[ 64:64 ] 0x00 NATIVE_SECTOR_SIZE [ 63:63 ] 0x00 USE_NATIVE_SECTOR [ 62:62 ] 0x00 DATA_SECTOR_SIZE [ 61:61 ] 0x00 INI_TIMEOUT_EMU[ 60:60 ] 0x00C - 5FieldByte Value CLASS_6_CTRL [ 59:59 ] 0x00 DYNCAP_NEEDED[ 58:58 ] 0x00 EXCEPTION_EVENTS_CTRL [ 57:56 ] 0 EXCEPTION_EVENTS_STATUS [ 55:54 ] 0 EXT_PARTITIONS_ATTRIBUTE[ 53:52 ] 0 CONTEXT_CONF[ 51:37 ] 0 PACKED_COMMAND_STATUS [ 36:36 ] 0x00 PACKED_FAILURE_INDEX [ 35:35 ] 0x00 POWER_OFF_NOTIFICATION[ 34:34 ] 0x00 CACHE_CTRL [ 33:33 ] 0x00 FLUSH_CACHE [ 32:32 ] 0x00 BARRIER_CTRL [ 31:31 ] 0x00 MODE_CONFIG[ 30:30 ] 0x00 MODE_OPERATION_CODES[ 29:29 ] 0x00 Reserved [ 28:27 ] 0 FFU_STATUS[ 26:26 ] 0x00 PRE_LOADING_DATA_SIZE [ 25:22 ] 0MAX_PRE_LOADING_DATA_SIZE[ 21:18 ] 3304106(16G) 6608213(32G) 13216426(64G)PRODUCT_STATE_AWARENESS_ENABLEMENT[ 17:17 ] 0x01 SECURE_REMOVAL_TYPE[ 16:16 ] 0x01 CMDQ_MODE_EN[ 15:15 ] 0x00 Reserved[ 14:0 ]。

1200AP40 1200AP60、1203P60200D6、203D6 DAP8A 可互代203D6/1203P6 DAP8A2S0680 2S08803S0680 3S08805S0765 DP104、DP7048S0765C DP704加24V的稳压二极管ACT4060 ZA3020LV/MP1410/MP9141ACT4065 ZA3020/MP1580ACT4070 ZA3030/MP1583/MP1591MP1593/MP1430 ACT6311 LT1937ACT6906 LTC3406/AT1366/MP2104AMC2576 LM2576AMC2596 LM2596AMC3100 LTC3406/AT1366/MP2104AMC34063A AMC34063AMC7660 AJC1564AP8012 VIPer12AAP8022 VIPer22ADAP02 可用SG5841 /SG6841代换DAP02ALSZ SG6841DAP02ALSZ SG6841DAP7A、DP8A 203D6、1203P6DH321、DL321 Q100、DM0265RDM0465R DM/CM0565RDM0465R/DM0565R 用cm0565r代换（取掉4脚的稳压二极管）DP104 5S0765DP704 5S0765DP706 5S0765DP804 DP904FAN7601 LAF0001LD7552 可用SG6841代（改4脚电阻）LD7575PS 203D6改1脚100K电阻为24KOB2268CP OB2269CPOB2268CP SG6841改4脚100K电阻为20-47KOCP1451 TL1451/BA9741/SP9741/AP200OCP2150 LTC3406/AT1366/MP2104OCP2160 LTC3407OCP2576 LM2576OCP3601 MB3800OCP5001 TL5001OMC2596 LM2596/AP1501PT1301 RJ9266PT4101 AJC1648/MP3202PT4102 LT1937/AJC1896/AP1522/RJ9271/MP1540SG5841SZ SG6841DZ/SG6841DSM9621 RJ9621/AJC1642SP1937 LT1937/AJC1896/AP1522/RJ9271/MP1540STR-G5643D STR-G5653D、STR-G8653DTEA1507 TEA1533TEA1530 TEA1532对应引脚功能接入THX202H TFC719THX203H TFC718STOP246Y TOP247YVA7910 MAX1674/75 L6920 AJC1610VIPer12A VIPer22A[audio01]ICE2A165(1A/650V.31W);ICE2A265(2A/650V.52W);ICE2B0565(0.5A/650V.23W):ICE2B165(1A/650V.31W);ICE2B265(2A/650V.52W);ICE2A180(1A/800V.29W);ICE2A280(2A/800.50W).KA5H0365R, KA5M0365R, KA5L0365R, KA5M0365RN# u) t! u1 W1 B) R, PKA5L0365RN, KA5H0380R, KA5M0380R, KA5L0380R1、KA5Q1265RF/RT（大小两种体积）、KA5Q0765、FSCQ1265RT、KACQ1265RF、FSCQ0765RT、FSCQ1565Q这是一类的，这些型号的引脚功能全都一样，只是输出功率不一样。

MM5ZxxxST1G Series, SZMM5ZxxxST1G Series Zener Voltage Regulators 500 mW SOD−523 Surface MountThis series of Zener diodes is packaged in a SOD−523 surface mount package. They are designed to provide voltage regulation protection and are especially attractive in situations where space is at a premium. They are well suited for applications such as cellular phones, hand held portables, and high density PC boards. Specification Features•Standard Zener Breakdown V oltage Range −2.4 V to 18 V •Steady State Power Rating of 500 mW•Small Body Outline Dimensions:0.047″ x 0.032″ (1.20 mm x 0.80 mm)•Low Body Height: 0.028″ (0.7 mm)•ESD Rating of Class 3 (> 16 kV) per Human Body Model •Tight Tolerance V Z•SZ Prefix for Automotive and Other Applications Requiring Unique Site and Control Change Requirements; AEC−Q101 Qualified and PPAP Capable•These Devices are Pb−Free and are RoHS Compliant*Mechanical CharacteristicsCASE:V oid-free, transfer-molded, thermosetting plasticEpoxy Meets UL 94, V−0LEAD FINISH: 100% Matte Sn (Tin)MOUNTING POSITION:AnyQUALIFIED MAX REFLOW TEMPERATURE: 260°CDevice Meets MSL 1 RequirementsMAXIMUM RATINGSRating Symbol Max UnitTotal Device Dissipation FR−4 Board, (Note 1) @ T A = 25°CDerate above 25°C P D5004.0mWmW/°CThermal Resistance from Junction−to−Ambient (Note 1)R q JA250°C/WJunction and Storage Temperature Range T J, T stg−65 to+150°CStresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality should not be assumed, damage may occur and reliability may be affected.1.FR−4 printed circuit board, single−sided copper, mounting pad 1 cm2.*For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D.Device Package Shipping†ORDERING INFORMATIONCathode AnodeSee specific marking information in the device marking column of the Electrical Characteristics table on page 2 of this data sheet.DEVICE MARKING INFORMATIONSOD−523CASE 502STYLE 1MARKING DIAGRAMXX= Specific Device CodeM Date Code*G= Pb−Free Package(Note: Microdot may be in either location)*Date Code orientation may vary dependingupon manufacturing location.MM5ZxxxST1G SOD−523(Pb−Free)3,000 /Tape & Reel†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our T ape and Reel Packaging Specifications Brochure, BRD8011/D.SOD−523(Pb−Free)SZMM5ZxxxST1G3,000 /Tape & ReelSOD−523(Pb−Free)SZMM5ZxxxST5G8,000 /Tape & ReelELECTRICAL CHARACTERISTICS (T A = 25°C unless otherwise noted,V F = 0.9 V Max. @ I F = 10 mA for all types) Symbol Parameter V Z Reverse Zener Voltage @ I ZTI ZT Reverse CurrentZZT Maximum Zener Impedance @ I ZTI ZK Reverse CurrentZ ZK Maximum Zener Impedance @ I ZKI R Reverse Leakage Current @ V RV R Reverse VoltageI F Forward CurrentV F Forward Voltage @ I FQ V Z Maximum Temperature Coefficient of V Z C Max. Capacitance @V R = 0 and f = 1 MHzV Figure 1. Zener Voltage RegulatorELECTRICAL CHARACTERISTICS (V F = 0.9 Max @ I F = 10 mA for all types)Device*DeviceMarkingTestCurrentIzt mAZener VoltageVZZ ZK I Z= 1.0mA WMaxZ ZTI Z = IZT@ 10%Mod WMaxMaxIR @ VRd VZ/dt (mV/k)@ I ZT1 = 5 mA C pF Max @V R = 0f = 1 MHzMin Max m A V Min MaxMM5Z2V4ST1G T2 5.0 2.43 2.631000100120 1.0−3.50450MM5Z2V7ST1G T3 5.0 2.67 2.911000100100 1.0−3.50450MM5Z3V3ST1G T5 5.0 3.32 3.53100095 5.0 1.0−3.50450MM5Z3V6ST1G T6 5.0 3.60 3.85100090 5.0 1.0−3.50450MM5Z3V9ST1G T7 5.0 3.89 4.16100090 3.0 1.0−3.5−2.5450MM5Z4V3ST1G T8 5.0 4.17 4.43100090 3.0 1.0−3.50450MM5Z4V7ST1G/T5G T9 5.0 4.55 4.7580080 3.0 2.0−3.50.2260MM5Z5V1ST1G TA 5.0 4.98 5.250060 2.0 2.0−2.7 1.2225MM5Z5V6ST1G TC 5.0 5.49 5.7320040 1.0 2.0−2.0 2.5200MM5Z6V2ST1G TE 5.0 6.06 6.3310010 3.0 4.00.4 3.7185MM5Z6V8ST1G TF 5.0 6.65 6.9316015 2.0 4.0 1.2 4.5155MM5Z7V5ST1G TG 5.07.287.616015 1.0 5.0 2.5 5.3140MM5Z8V2ST1G TH 5.08.028.36160150.7 5.0 3.2 6.2135MM5Z9V1ST1G TK 5.08.859.23160150.5 6.0 3.87.0130MM5Z12VST1G TN 5.011.7412.2480250.18.0 6.010130MM5Z16VST1G TU 5.015.8516.5180400.0511.210.414105MM5Z18VST1G TW 5.017.5618.3580450.0512.612.416100 Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product performance may not be indicated by the Electrical Characteristics if operated under different conditions.*Include SZ-prefix devices where applicable.TYPICAL CHARACTERISTICSTEMPERATURE (°C)25010040200P O W E R D I S S I P A T I O N (%)50751001251508060Figure 2. Steady State Power DeratingPACKAGE DIMENSIONSSOD −523CASE 502ISSUE ENOTES:1.DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994.2.CONTROLLING DIMENSION: MILLIMETERS.3.MAXIMUM LEAD THICKNESS INCLUDES LEAD FINISH.MINIMUM LEAD THICKNESS IS THE MINIMUM THICKNESS OF BASE MATERIAL.4.DIMENSIONS D AND E DO NOT INCLUDE MOLD FLASH, PRO-TRUSIONS, OR GATE BURRS.DIM MIN NOM MAX MILLIMETERS D 1.10 1.20 1.30E 0.700.800.90A 0.500.600.70b 0.250.300.35c 0.070.140.20L 0.30 REF H 1.50 1.60 1.70*For additional information on our Pb −Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D.SOLDERING FOOTPRINT*E RECOMMENDEDSIDE VIEW2XBOTTOM VIEWL2L2X2XL20.150.200.25STYLE 1:PIN 1.CATHODE (POLARITY BAND)2.ANODEON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. SCILLC products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application, Buyer shall indemnify and hold SCILLC and its officers, employees, subsidiaries, affiliates,and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was negligent regarding the design or manufacture of the part. SCILLC is an Equal Opportunity/Affirmative Action Employer. This literature is subject to all applicable copyright laws and is not for resale in any manner.PUBLICATION ORDERING INFORMATION。

WMI Provider GUIPanasonic (PSSNA)Version: 1.00 L31Update Notes∙Added CF33 Skylake Main tabs (missing some BIOS options).∙Added support for FZ-Q1, FZ-Q2MK1, FZ-XZ6 (EU), CF-33 and CF20MK2∙Added support for “Secure Boot Control” Setting (Models supported – CF-20MK1+, CF-54MK1+, and FZ-M1MK2System Requirements∙Windows XP, Windows Vista, Windows 7, Windows 8, or Windows 10.∙.NET Framework 3.5∙Panasonic Misc Driver∙Panasonic WMI Provider 3.13 (included in installation)Supported ModelsCF-W8 mk1CF-T8 mk1, mk3, mk4CF-F8 mk1, mk3CF-C1 mk1, mk2CF-C2 mk1, mk2FZ-M1 mk1, mk2FZ-M1V mk1, mk2FZ-G1 mk1, mk2, mk3, mk4FZ-Q1 mk1FZ-Q2 mk1CF-AX2 mk1, mk2CF-AX3 mk1, mk2, mk3CF-LX3 mk2, mk3CF-D1 mk1, mk2, mk3CF-54 mk1, mk2UT-MA6 mk1UT-MB5 mk1FZ-Y1 mk2CF-74 mk4CF-52 mk2, mk3, mk4, mk5CF-53 mk1, mk2, mk3, mk4CF-19 mk3, mk4, mk5, mk6, mk7. mk8CF-30 mk3CF-31 mk1, mk2, mk3, mk4, mk5CF-33Mk1CF-20 mk1CF-U1 mk1, mk2CF-H1 mk1, mk2CF-H2 mk1, mk2, mk3*Special note for some settings in the WMI Tool:∙“Secure Boot Control” Setting– Is read-only, cannot be changed for security reasons∙“UEFI Boot” Setting – Cannot be enabled through WMI, for security reasons∙“Set CSM Support” Setting –Changing setting will fail when “Secure Boot” Setting is enabledWMI - BIOS configuration ToolUsageDouble click "WMI Provider GUI" shortcut to start the utility. WMI Provider GUI is a Windows based utility that can be used to modify BIOS settings on Panasonic Toughbooks. The modifications can be applied on the same unit on which the utility is running, or remotely by exporting a VBS script which is then executed on a remote unit.Operation: Login ScreenThe utility can run in two modes which are selectable at start up.The "Connect to local PC" mode can be used to export BIOS settings on the currently running machine. The "Config only mode" can be used to generate .INI config files which can then be opened later, or it can be used to export VBS scripts.If "Connect to local PC" is selected, the utility will attempt to establish a connection with the BIOS, if the BIOS is protected by a supervisor password, you will be asked to enter it now. The supervisor password is required to make modifications to the BIOS, in the local connection and in the VBS script. Operation: Main Window in local connection modeOnce in the main window, you can change any BIOS settings that are available on the model to which you are connected to. The current values of the settings will be displayed in the window, select the categories under "BIOS" on the left to display the appropriate settings on the right side.The "Apply to BIOS" option must be clicked to apply the BIOS settings to the local machine. Once complete, the message "BIOS settings successfully applied" will be displayed, if any error occurred while applying the settings, a log file is available, called "toughbookwmi.txt" which will contain a detailed description of the error. Please send this file, including a screenshot of the error, to the person from whom you received this utility.Operation: Main Window in config only modeSince in "Config only mode" the model is unknown, it should be selected in the "Filter by model/mark" options at the top of the window. The exported VBS script will remember this model number and will verify it before applying them.Operation: VBS scriptA VBS script can be exported from both config and local connection mode. When executed, this script will apply the settings on the machine on which it is executed on. Administrators can generate specific settings to apply on their units, then export the VBS script, deploy this script along with the installation of WMI Provider, and then execute the script remotely to apply the settings. If a supervisor password is set up on the machine, it must be passed to the script as a command line argument,e.g. ”m yBiosScript.vbs secret”. It is recommended to use the command line utility ”c script”included with Windows to execute the scripts, this will display all output from the script on the console including any errors. The output can also be exported to log a file.Example:cscript myBiosScript.vbs secret > logfile.txtThis command will execute ”m yBiosScript.vbs” with the supervisor password“secret” and write the results to the file ”logfile.txt”.WMI - BIOS configuration Walkthrough1.WMI Tool consists of two parts: WMI GUI and WMI provider library, first the WMI provider must beinstalled, then we will be able to run “ToughBook WMI GUI.exe”. (WMI Tool can be used to modify BIOS settings on Panasonic Toughbook devices: The desired modifications can be applied to a local unit or remote units by exporting VBS script files executed on remote unit.)2.After running the “ToughBook WMI GUI.exe”,you will be prompted to select one of two modes,which are explained below.i.Connect to Local PC ModeConnect to local PC Guide:a.Establishes connection with BIOS (this mode is used to modify BIOS on the currentmachine), if BIOS is protected with Supervisor password, user will be asked to enterSupervisor Password. If prompted to enter password: enter the appropriateSupervisor password assigned to your computer. (Supervisor password is required tomake modification to BIOS in local connection mode and in the VBS scripts)b.After entering password, you are now able to change BIOS parameters by selecting thecategory on the left side, and changing the parameters using the dropdown menu.Once finished selecting the custom BIOS parameters, click on "apply to BIOS" to applyBIOS settings to local machine. Once this operation is completed, you will see "BIOSsettings successf ully applied“, if any error occurs – a log file will be created showingthe details of the occurred error.132ii.Config Only ModeConfig Only Mode Guide:a.This mode can be used to generate .INI files or to export VB scripts (used to create acustom BIOS configuration which can be sent to other machines to apply the selectedsettings). Select the computer model by “F ilter model/mark” menu at the top. (VBscript will remember model number before apply those settings)b.After selecting the model and mark, select the settings you want to change using thecategories on the left and using the dropdown menus.c.When finished selecting the desired settings, the custom configuration can be savedand applied later on a different machine the WMI tool by saving as an “.INI” file. To doso, press on “File”, then “Save as” and choose where you would like to save the file.12 435d.It is also possible to save the configured WMI settings as a VB script (after you haveselected the desired BIOS settings). To do so, press on “File”, then “Export to VBS” and choose where you would like to save the file.12e.The VB scripts created in the previous step can be applied to BIOS using cscript utilityusing syntax shown below, using the Windows command prompt. The commandoutput will be logged into log.txt file and will be found at the specified file location.EXAMPLE COMMAND:(If your .vbs file (VB script) is named “MyCustomBIOS.vbs” and is located at filelocation “C:\MyFolder\” and your BIOS Supervisor password is “secret”. Thecommand should as be as shown below.C:\MyFolder>cscript MyCustomBIOS.vbs secret > log.txtApplying settings using VB script and command prompt.。

玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理玉林万顺达电脑芯片级维修资料 2010-07-20整理。

NTE2055Integrated CircuitCMOS, 3 1/2 Digit A/D ConverterDescription:The NTE2055 is a high performance, low power, 3 1/2 digit A/D converter combining both linear CMOS and digital CMOS circuits on a single monolithic IC. Available in a 24–Lead DIP type package, this device is de-signed to minimize use of external components. With two external resistors and two external capacitors, the system forms a dual slope A/D converter with automatic zero correction and automatic polarity.The NTE2055 is ratiometric and may be used over a full–scale range from 1.999V to 199.9mV. Systems using this device may operate over a wide range of power supply voltages for ease of use with batteries, or with stan-dard 5V supplies. The output drive conforms with standard B–Series CMOS specifications and can drive a low–power Schottky TTL load.The high impedance MOS inputs allow applications in current and resistance meters as well as voltmeters. In addition to DVM/DPM applications, the NTE2055 finds use in digital thermometers, digital scales, remote A/D, A/D control systems, and in MPU systems.Features:D Accuracy: ±0.05% of Reading ±1 CountD Two Voltage Ranges: 1.999V and 199.9mVD Up to 25 Conversions /sD Z in > 100MΩD Auto–Polarity and Auto–ZeroD Single Positive Voltage ReferenceD Standard B–Series CMOS Outputs: Drives One Low Power Schottky LoadD Uses On–Chip System Clock, or External ClockD Wide Supply Range: e.g., ±4.5V to ±8.0VD Overrange and Underrange Signals AvailableD Operates in Auto Ranging CircuitsD Operates with LED and LCD DisplaysD Low External Component CountD Chip Complexity: 1326 FETsAbsolute Maximum Ratings:. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .DC Supply Voltage, V DD to V EE–0.5V to +18V Voltage, Ant Pin, Referenced to V EE, V–0.5V to V DD+0.5V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .DC Input Current, Per Pin, I in±10mA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Operating Temperature Range, T A–40° to +85°C. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Storage Temperature Range, T stg–65° to +150°C. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Note 1.This device contains circuitry to protect the inputs against damage due to high static voltages or electric fields; however, it is advised that normal precautions be taken to avoid applications of any voltage higher than maximum rated voltages to this high impedance circuit. For proper operation it is recommended that V in and V out be constrained to the range V EE≤ (V in or V out) ≤ V DD.Recommended Operating Conditions: (V SS = 0 or V EE)DC Supply Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .V DD to Analog GND, V DD+5.0 to 8.0V. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .V EE to Analog GND, V EE–2.8 to –8.0V Clock Frequency, f Clk32 to 400kHz . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Zero Offset Correction Capacitor, C o0.1 ±20%µF. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Electrical Characteristics:(C I = 0.1µF mylar, R I = 470kΩ @ V ref = 2V, R I = 27kΩ @ V ref = 200mV,R C = 300kΩ, T A = +25°C ; all voltages referenced to Analog GND, Pin1, unlessotherwise specified)Note 2.Accuracy – The accuracy of the meter at full scale is the accuracy of the setting of the reference volt-age. Zero is recalculated during each conversion cycle. The meaningful specification is linearity.In other words, the deviation from correct reading for all inputs other than positive full scale and zero is defined as the linearity specification.Note 3.Symmetry – Defined as the difference between a negative and positive reading of the same voltage at or near full scale.Note 4.Referenced to V SS for Pin9. Referenced to V EE for Pin10.Truth Table (DS1 =1)Notes for Truth Table:Q3–1/2 digit, low for “1”, high for “0”Q2–Polarity: “1” = positive, “0” = negative Q0–Out of range condition exists if Q0 =1. When used in conjunction with Q3 the typeof out of range condition is indicated, i.e., Q3 = 0 → OR or Q3 = 1 → UR.When only segment b and c of the decoder are connected to the 1/2 digit of the display 4,0, 7, and 3 appear as 1.The overrange indication (Q3 = 0 and Q0 = 1) occurs when the count is greater than 1999,e.g., 1.999V for a reference of 2V. The underrage indication, useful for autoranging circuits,occurs when the count is less than 180, e.g., o.180V for a reference of 2V.Caution:If the most significant digit is connected to a display other than a “1” only; such asa full digit display, segments other thanb andc must be disconnected. The BCD ti seven decoder must blank on BCD inputs 1010 to 1111.。

Code Device Manufacturer BasePackage Leaded Equivalent/Data0 2SC3603 Nec CX SOT173N pn RF fT 7GHz 005 SSTPAD5 Sil J -PAD-5 5pA leakage diodep01 PDTA143ET Phi N SOT23 pnp dtr 4k7+4k7 t01 PDTA143ET Phi N SOT23 pnp dtr 4k7+4k701 Gali-1 MC AZ SOT89 DC-8GHz MMIC amp 12dB gain 010 SSTPAD10 Sil J - PAD-10 10pA leakage diode011 SO2369R SGS R SOT23R2N236902 BST82 Phi M - n-ch mosfet 80V 175mA02 MRF5711L Mot X SOT143npn RF MRF57102 DTCC114T Roh N - 50V 100mA npn sw + 10k base res 02 Gali-2 MC AZ SOT89 DC-8GHz MMIC amp 16dB gainp02 PDTC143ET Phi N SOT23 npn 4k7+4k7 bias res t02 PDTC143ET Phi N SOT23 npn 4k7+4k7 bias res03 Gali-3 MC AZ SOT89 DC-3GHz MMIC amp 22dB gain 03 DTC143TE Roh N EMT3 npn dtr R1 4k7 50V 100mA 03 DTC143TUA Roh N SC70 npn dtr R1 4k7 50V 100mA 03 DTC143TKA Roh N SC59 npn dtr R1 4k7 50V 100mA 04 DTC114TCA Roh N SOT23 npn dtr R1 10k 50V 100mA 04 DTC114TE Roh N EMT3 npn dtr R1 10k 50V 100mA 04 DTC114TUA Roh N SC70 npn dtr R1 10k 50V 100mA 04 DTC114TKA Roh N SC59 npn dtr R1 10k 50V 100mA04 MRF5211L Mot X SOT143 pnp RF MRF52104 Gali-4 MC AZ SOT89 DC-4GHz MMIC amp 17.5 dBm-04 PMSS3904 Phi N SOT323 2N3904 t04 PMBS3904 Phi N SOT23 2N390405 Gali-4 MC AZ SOT89 DC-4GHz MMIC amp 18 dBm o/p 05 DTC124TE Roh N EMT3 npn dtr R1 22k 50V 100mA 05 DTC124TUA Roh N SC70 npn dtr R1 22k 50V 100mA 05 DTC124TKA Roh N SC59 npn dtr R1 22k 50V 100mA 05F TSDF1205R Tfk WQ - fT12GHz npn 4V 5mA06 Gali-6 MC AZ SOT89 DC-4GHz MMIC amp 115 dBm o/p06 DTC144TE Roh N EMT3 npn dtr R1 47k 50V 100mA 06 DTC144TUA Roh N SC70 npn dtr R1 47k 50V 100mA 06 DTC144TKA Roh N SC59 npn dtr R1 47k 50V 100mA-06 PMSS3906 Phi N SOT323 2N3906 t06 PMBS3906 Phi N SOT23 2N3906020 SSTPAD20 Sil J - PAD-20 20pA leakage diode 050 SSTPAD50 Sil J - PAD-50 50pA leakage diode081 SO2369AR SGS R SOT23R 2N2369A09 DTC115TUA Roh N SC70 npn dtr R2 100k 50V 100mA 09 DTC115TKA Roh N SC59 npn dtr R2 100k 50V 100mA0A MUN5111DW1 Mot DO SOT363 dual pnp dtr 10k+10k 0A DTC125TUA Roh N SC70 npn dtr R2 100k 50V 100mA 0A DTC125TKA Roh N SC59 npn dtr R2 100k 50V 100mA0B MUN5112DW1 Mot DO SOT363 dual pnp dtr 22k+22k 0C MUN5113DW1 Mot DO SOT363 dual pnp dtr 47k+47k 0D MUN5114DW1 Mot DO SOT363 dual pnp dtr 10k+47k 0E MUN5115DW1 Mot DO SOT363 dual pnp dtr R1 10k 0F MUN5116DW1 Mot DO SOT363 dual pnp dtr R1 4k7 0G MUN5130DW1 Mot DO SOT363 dual pnp dtr 1k0+1k0 0H MUN5131DW1 Mot DO SOT363 dual pnp dtr 2k2+2k2 0J MUN5132DW1 Mot DO SOT363 dual pnp dtr 4k7+4k7 0K MUN5133DW1 Mot DO SOT363 dual pnp dtr 4k7+47k 0L MUN5134DW1 Mot DO SOT363 dual pnp dtr 22k+47k 0MMUN5135DW1 MotDOSOT363dual pnp dtr 2k2+47k对应型号代码 厂家 封装特性Code Device Manufacturer Base Package Leaded Equivalent/Data12SC3587Nec CX -npn RF fT10GHz1BA277Phi I SOD523VHF Tuner band switch diode1 (red)BB669Sie I SOD32356-2.7 pF varicap10MRF9411L Mot X SOT143npn Rf 8GHz MRF94110A PZM10NB2A Phi A SOT346dual ca 10V 0.3W zener10A ZXRE1004FF Zet G SOT23Micropower (4µA) 1.22V Voltage ref. 3% 10B ZXRE1004EF Zet G SOT23Micropower (4µA) 1.22V Voltage ref. 2% 10C ZXRE1004DF Zet G SOT23Micropower (4µA) 1.22V Voltage ref. 1% 10D ZXRE1004CF Zet G SOT23Micropower (4µA) 1.22V Voltage ref. 0.5% 10F ZXRE4041FF Zet G SOT23Micropower 1.222V Voltage ref. 3%10G ZXRE4041EF Zet G SOT23Micropower 1.222V Voltage ref. 2%10H ZXRE4041DF Zet G SOT23Micropower 1.222V Voltage ref. 1%10J ZXRE4041CF Zet G SOT23Micropower 1.222V Voltage ref. 0,5% 10V PZM10NB Phi C SOT34610V 0.3W zener10Y BZV49-C10Phi O SOT8910V 1W zener11MRF9511L Mot X SOT143npn RF 8GHz MRF95111MUN5311DW1Mot DP SOT363npn/pnp dtr 10k+10k11PDTA114EU Phi N SOT416pnp dtrp11PDTA114TT Phi N SOT23pnp dtrt11PDTA114TT Phi N SOT23pnp dtr11A PZM11NB2A Phi A SOT346dual ca 11V 0.3W zener11A MMBD1501A Nat C SOT23Si diode 200V 100mA11V PZM11NB Phi C SOT34611V 0.3W zener11Y BZV49-C11Phi O SOT8911V 1W zener12MUN5312DW1Mot DP SOT363npn/pnp dtr 22k+22k12DTA123EUA Rho N SC70pnp dtr 2k2+2k2 50V 100ma12DTA123EKA Rho N SC59pnp dtr 2k2+2k2 res 50V 100map12PDTC114TT Phi N SOT23npn dtrt12PDTC114TT Phi N SOT23npn dtr12A MMBD1502A Nat K SOT23Si diode 200V 100mA12A PZM12NB2A Phi A SOT346dual ca 12V 0.3W zener12E ZC2812E Zet D SOT23dual series RF schottky15V 20mA12F ZXRE125FF ZET G SOT23Micropower 1.22V Voltage ref. 3%12G ZXRE125EF ZET G SOT23Micropower 1.22V Voltage ref. 2%12H ZXRE125DF ZET G SOT23Micropower 1.22V Voltage ref. 1%12J ZXRE125CF ZET G SOT23Micropower 1.22V Voltage ref. 0,5%12V PZM12NB Phi C SOT34612V 0.3W zener12Y BZV49-C12Phi O SOT8912V 1W zener13DTA143EUA Rho N SC70pnp dtr 4k7+4k7 50V 100ma13DTA143EKA Rho N SC59pnp dtr 4k7+4k7 50V 100ma13DTA143ECA Rho N SOT23pnp dtr 4k7+4k7 50V 100ma13t BC846BPN Phi N SOT363BC546B13s BAS125Sie C SOT23Schottky sw 24V 100mA13s BAS125W Sie C SOT323Schottky sw 24V 100mA13MA4CS103A M/A C SOT23Schottky RF 20V 100mA13MUN5313DW1Mot DP SOT363npn/pnp dtr 47k+47k13A MMBD1503A Nat D SOT23dual Si diode 200V 100mA13A PZM13NB2A Phi A SOT346dual ca 13V 0.3W zener13E ZC2813E Zet A SOT23dual ca RF schottky15V 20mA13V PZM13NB Phi C SOT34613V 0.3W zener13Y BZV49-C13Phi O SOT8913V 1W zener14s BAS125-04Sie D SOT23Dual series Schottky 25V 100mA14s BAS125-04W Sie D SOT323Dual series Schottky 25V 100mA14BAT114-099R Sie DQ -Quad Schottky crossover ring14DTA114EUA Roh N SC70pnp dtr 10k + 10k14DTA114EKA Roh N SC59pnp dtr 10k + 10k14MUN5314DW1Mot DP SOT363npn/pnp dtr 10k R114DTA114ECA Roh N SOT23pnp dtr 10k + 10k14A MMBD1504A Nat B -dual cc Si diode 200V 100mA15s BAS125-05Sie B SOT23dual cc Schottky 25V 100mA15s BAS125-05W Sie B SOT323dual cc Schottky 25V 100mA15DTA124EUA Roh N SC70pnp dtr 30V 50mA 22k+22k15DTA124EKA Roh N SC59pnp dtr 30V 50mA 22k+22k15DTA124ECA Roh N SOT23pnp dtr 30V 50mA 22k+22k15MUN5315DW1Mot DP SOT363npn/pnp dtr 10k R115MMBT3960Mot N -2N396015A MMBD1505A Nat A -dual ca Si diode 200V 100mA 15A PZM15NB2A Phi A SOT346dual ca 15V 0.3W zener15V PZM15NB Phi C SOT34615V 0.3W zener15Y BZV49-C15Phi O SOT8915V 1W zenerp16PDTC114ET Phi N SOT23npn dtrt16PDTC114EU Phi N SOT323npn dtr16s BAS125-06Sie A SOT23dual ca Schottky 25V 100mA 16s BAS125-06W Sie A SOT323dual ca Schottky 25V 100mA 16MUN5316DW1Mot DP SOT363npn/pnp dtr 4k7 R116DTA144EUA Roh N SC70pnp dtr 30V 50mA 47k+47k 16DTA144EKA Roh N SC59pnp dtr 30V 50mA 47k+47k 16V PZM16NB Phi C SOT34616V 0.3W zener16Y BZV49-C16Phi O SOT8916V 1W zener17s BAS125-07Sie S SOT143dual Schottky 25V 100mA 17s BAS125-07W Sie S SOT343dual Schottky 25V 100mAp17PDTC124ET Phi N SOT23npn dtrt17PDTC124EU Phi N SOT323npn dtr18BFP181T Tfk X -npn Rf fT 7.8GHz 10V 20mA 18PDTC143ZK Phi N SOT346npn dtr 4k7+47kp18PDTC143ZT Phi N SOT23npn dtr 4k7+47kt18PDTC143ZT Phi N SOT23npn dtr 4k7+47k18V PZM18NB Phi C SOT34618V 0.3W zener18Y BZV49-C18Phi O SOT8918V 1W zener19PDTA143ZK Phi N SOT346pnp dtr 4k7+47k19DTA115EUA Rho N SC70pnp dtr 100k+100k 50V 100ma 19DTA115EKA Rho N SC59pnp dtr 100k+100k 50V 100ma p19PDTA143ZT Phi N SOT23pnp dtr 4k7+47kt19PDTA143ZT Phi N SOT23pnp dtr 4k7+47k100SSTPAD100Sil J SOT23PAD-100 100pA leakage diode 101PZM10NB1Phi C SOT34610V 0.3W zener102PZM10NB2Phi C SOT34610V 0.3W zener103PZM10NB3Phi C SOT34610V 0.3W zener111PZM11NB1Phi C SOT34611V 0.3W zener111DTA113ZUA Roh N SC70pnp dtr 1k+10k 50V 100mA 112PZM11NB2Phi C SOT34611V 0.3W zener113PZM11NB3Phi C SOT34611V 0.3W zener113DTA143ZUA Roh N SC70pnp dtr 4k7+47k 50V 100mA 121PZM12NB1Phi C SOT34612V 0.3W zener121DTC113ZUA Roh N SC70npn dtr 1k+10k 50V 100mA 122PZM12NB2Phi C SOT34612V 0.3W zener123PZM12NB3Phi C SOT34612V 0.3W zener123DTC143ZUA Roh N SC70npn dtr 4k7+47k 50V 100mA 131PZM13NB1Phi C SOT34613V 0.3W zener132PZM13NB2Phi C SOT34613V 0.3W zener132DTA123JUA Roh N SC70pnp dtr 2k2+47k 50V 100mA 133PZM13NB3Phi C SOT34613V 0.3W zener142DTA123JUA Roh N SC70npn dtr 2k2+47k 50V 100mA 151PZM15NB1Phi C SOT34615V 0.3W zener152PZM15NB2Phi C SOT34615V 0.3W zener153PZM15NB3Phi C SOT34615V 0.3W zener156DTA144VUA Roh N SC70pnp dtr 47k+10k 50V 100mA 161PZM16NB1Phi C SOT34616V 0.3W zener162PZM16NB2Phi C SOT34616V 0.3W zener163PZM16NB3Phi C SOT34616V 0.3W zener166DTC144VUA Roh N SC70npn dtr 47k+10k 50V 100mA 179FMMT5179Zet N -2N5179181PZM18NB1Phi C SOT34618V 0.3W zener182PZM18NB2Phi C SOT34618V 0.3W zener183PZM18NB3Phi C SOT34618V 0.3W zener1A BC846A Phi N SOT23BC546A1A BC846AT Phi N SOT416BC546A1Ap BC846A Phi N SOT23BC546A1At BC846A Phi N SOT23BC546A1At BC846AW Phi N SOT323BC546A1A-BC846AW Phi N SOT323BC546A1A FMMT3904Zet N SOT232N39041A MMBT3904Mot N SOT232N39041A IRLML2402IR F SOT23n-ch mosfet 20V 0.9Ap1A PMMT3904Phi N SOT232N3904p1A PXT3904Phi N SOT892N3904t1A PMMT3904Phi N SOT232N3904t1A PMST3904Phi N SOT3232N3904-1A PMST3904Phi N SOT3232N39041AM MMBT3904L Mot N SOT232N39041B BC846B Phi N SOT23BC546B1B BC846BT Phi N SOT416BC546B1Bp BC846B Phi N SOT23BC546B1Bt BC846B Phi N SOT23BC546B1Bt BC846BW Phi N SOT323BC546B1B-BC846BW Phi N SOT323BC546B1B FMMT2222Zet N SOT232N22221B MMBT2222Mot N SOT232N22221B IRLML2803IR F SOT23n-ch mosfet 30V 0.9Ap1B PMBT2222Phi N SOT232N2222t1B PMBT2222Phi N SOT232N2222t1B PMST2222Phi N SOT2332N2222-1B PMST2222Phi N SOT3232N22221Bs BC817UPN Sie N SC74-1Cp BAP50-05Phi B SOT23dual cc GP RF pin diode 1C FMMT-A20Zet N SOT23MPSA201C MMBTA20L Mot N SOT23MPS39041C IRLML6302IR F SOT23p-ch mosfet 20V 0.6A1Cs BC847S Sie-SOT363BC4571Dp BC846Phi N SOT23BC4561Dt BC846Phi N SOT23BC4561Dt BC846W Phi N SOT323BC4561D-BC846W Phi N SOT323BC4561D MMBTA42Mot N SOT23MPSA42 300V npn1D IRLML5103IR F SOT23p-ch mosfet 30V 0.6Ap1D PMBTA42Phi N SOT23MPSA42 300V npnp1D PXTA42Phi N SOT89MPSA42 300V npnt1D PMBTA42Phi N SOT23MPSA42 300V npnt1D PMSTA42Phi N SOT323MPSA42 300V npn1Ds BC846U Sie N SC74BC4561Ds BC846U Sie-SOT363BC4561DN2SC4083Roh N -npn 11V 3.2GHz TV tuners 1DR MSD1328R Mot N SOT346npn gp 25V 500mA1E BC847A Phi N SOT23BC547A1E BC847AT Phi N SOT416BC547A1Ep BC847A Phi N SOT23BC547A1Et BC847A Phi N SOT23BC547A1Et BC847A Phi N SOT323BC547A1E-BC847A Phi N SOT323BC547A1ER BC847AR Phi R SOT23R BC547A1E FMMT-A43Zet N -MPSA431E MMBTA43Mot N SOT23MPSA43 200V npnt1E PMBTA43Mot N SOT23MPSA43 200V npnt1E PMSTA43Mot N SOT323MPSA43 200V npn1Es BC847A Sie N SOT23BC4571Es BC847AW Sie N SOT323BC4571EN2SC4084Roh N -npn 20V 2.0GHz TV tuners 1F BC847B Phi N SOT23BC547B1F BC847BT Phi N SOT416BC547B1Fs BC847B Sie N SOT23BC547B1Fs BC847BT Sie N SC75BC547B1Fs BC847BW Sie N SOT323BC547B1Fp BC847B Phi N SOT23BC547B1Ft BC847B Phi N SOT23BC547B1Ft BC847BW Phi N SOT323BC547B1F-BC847BW Phi N SOT323BC547B1FR BC847BR Phi R SOT23R BC547B1F MMBT5550Mot N SOT232N5550 140V npnp1F PMBT5550Phi N SOT232N5550 140V npnt1F PMBT5550Phi N SOT232N5550 140V npnt1F PMST5550Phi N SOT3232N5550 140V npn1FZ FMBT5550Zet N SOT232N5550 140V npn1G BC847C Phi N SOT23BC547C1G BC847CT Phi N SOT416BC547C1Gp BC847C Phi N SOT23BC547C1Gt BC847CW Phi N SOT323BC547C1G-BC847CW Phi N SOT323BC547C1Gs BC847C Sie N SOT23BC547C1Gs BC847CW Sie N SOT323BC547C1GR BC847CR Phi R SOT23R BC547C1GT SOA06SGS N SOT23MPSA061G FMMT-A06Zet N SOT23MPSA061G MMBTA06Mot N SOT23MPSA06p1G PMMTA06Phi N SOT23MPSA06t1G PMMTA06Phi N SOT23MPSA06t1G PMMTA06Phi N SOT323MPSA061GM MMBTA06Mot N SOT23MPSA061Hp BC847Phi N SOT23BC5471Ht BC847Phi N SOT23BC5471Ht BC847W Phi N SOT323BC5471H-BC847W Phi N SOT323BC5471H FMMT-A05Zet N -MPSA051H MMBTA05Mot N SOT23MPSA05t1H MMBTA05Phi N SOT323MPSA051HT SOA05SGS N SOT23MPSA051J BC848A Phi N SOT23BC548A1Js BC848A Sie N SOT23BC548A1Js BC848AW Sie N SOT323BC548A1J FMMT2369Zet N SOT232N23691J MMBT2369Mot N SOT23MPS23691Js BCV61A Sie VQ SOT143npn current mirror hFe 180 1Jp BCV61A Phi VQ SOT143npn current mirror hFe 180 p1J PMBT2369Phi N SOT232N2369t1J PMBT2369Phi N SOT232N2369t1J PMBT2369Phi N SOT3232N23691JA MMBT2369A Mot N SOT23MPS2369A1JR BC848AR Phi R SOT23R BC548A1JZ BC848A Zet N SOT23BC548A1K BC848B ITT N SOT23BC548B1Kp BC848B Phi N SOT23BC548B1Ks BC848B Sie N SOT23BC548B1Ks BC848BW Sie N SOT323BC548B1K MMBT6428Mot N SOT23MPSA18 50Vp1K PMBT6428Phi N SOT23MPSA18 50Vt1K PMBT6428Phi N SOT23MPSA18 50Vt1K PMBT6428Phi N SOT323MPSA18 50V1K FMMT4400Zet N SOT232N44001Ks BCV61B Sie VQ SOT143B npn current mirror hFe 290 1Kp BCV61B Phi VQ SOT143B npn current mirror hFe 290 1KR BC848BR Phi R SOT23R BC548B1KM MMBT6428L Mot N SOT23MPSA18 50V1KZ FMMT4400Zet N SOT232N44001L BC848C ITT N SOT23BC548C1Lp BC848C Phi N SOT23BC548C1Ls BC848C Sie N SOT23BC548C1Ls BC848CW Sie N SOT323BC548C1L MMBT6429Mot N -MPSA18 45V1L FMMT4401Zet N -2N44011L BCV61C Sie VQ SOT143B npn current mirror hFe 520 1Lp BCV61C Phi VQ SOT143B npn current mirror hFe 520 p1L PMBT6429Phi N SOT23MPSA18 45Vt1L PMBT6429Phi N SOT23MPSA18 45Vt1L PMBT6429Phi N SOT323MPSA18 45V1LR BC848CR Phi R SOT23R BC548C1Mp BC848Phi N SOT23BC5481M MMBTA13Mot N SOT23MPSA13 darlington1Mp BCV61Phi VQ SOT143B npn current mirror1M FMMT-A13Zet N SOT23MPSA13p1M PXTA13Phi N SOT89MPSA13 darlingtonp1M PMBTA13Phi N SOT23MPSA13 darlingtont1M PMBTA13Phi N SOT23MPSA13 darlington1N FMMT-A14Zet N SOT23MPSA141N MMBTA14Mot N SOT23MPSA14 darlington1N5ZTX11N15DF Zet N SOT23npn 15V 3A low saturation V p1N PMBTA14Mot N SOT23MPSA14 darlingtonp1N PXTA14Mot N SOT89MPSA14 darlingtont1N PMBTA14Mot N SOT23MPSA14 darlington1P FMMT2222A Zet N -2N2222A1P MMBT2222A Mot N SOT232N2222A1P BC847PN Sie DI -pnp/npn separate pair gp AF p1P PMBT2222A Phi N SOT232N2222Ap1P PXT2222A Phi N SOT892N2222At1P PMBT2222A Phi N SOT232N2222At1P PMST2222A Phi N SOT3232N2222A1Q MMBT5088Mot N SOT23MPSA18 Vce 30Vp1Q PMBT5088Phi N SOT23MPSA18 Vce 30Vt1Q PMBT5088Phi N SOT23MPSA18 Vce 30Vt1Q PMST5088Phi N SOT323MPSA18 Vce 30V1R MMBT5089Mot N SOT23MPSA18 Vce 25Vt1R PMST5089Phi N SOT323MPSA18 Vce 25V1S MMBT2369A Nat N SOT232N2369A 500MHz sw npn 1S MSC3130Mot H SOT346npn RF fT 1.4GHz 10V1T MMBT3960A Mot N -2N3960A1U MMBT2484L Mot N SOT23MPSA181V MMBT6427Mot H SOT232N6426/7 darlington npn 1Vp BF820Phi N SOT23npn 300V 50mA BF4201Vt BF820Phi N SOT23npn 300V 50mA BF4201Vt BF820W Phi N SOT323npn 300V 50mA BF4201V-BF820W Phi N SOT323npn 300V 50mA BF4201W FMMT3903Zet N SOT232N39031Wp BF821Phi N SOT23pnp 300V 50mA BF4211Wt BF821Phi N SOT23pnp 300V 50mA BF4211W t BF822W Phi N SOT323pnp 300V 50mA BF4211W -BF822W Phi N SOT323pnp 300V 50mA BF4211X MMBT930L Mot N SOT23MPS39041Xp BF822Phi N SOT23npn 250V 50mA BF4221Xt BF822Phi N SOT23npn 250V 50mA BF4221Y MMBT3903Mot N SOT232N39031Yp BF823Phi N SOT23pnp 250V 50mA BF4231Yt BF823Phi N SOT23pnp 250V 50mA BF4231Z BAS70-06Zet A SOT23dual RF CA schottky diode 1Z MMBT6517Mot N SOT232N6517 npn Vce 350VCode Device Manufacturer Base Package Leaded Equivalent/Data2BAT62-02W Sie I SCD80BAT16 schottky diode2 (blue)BAR64-03W Sie I SOD323pin diode22SC3604Nec CX -npn RF fT8GHz 12dB@2GHz2 (white) BB439Sie I SOD32329-5 pF varicap20MRF5811Mot X SOT143npn Rf fT 5GHz 0.2A-20PDTC114WU Phi N SOT323npn dtr20F TSDF1220Tfk X SOT143fT 12GHz npn 6V 20mA20V PZM20NB Phi C SOT34620V 300mW zener20Y BZV49-C20Phi O SOT8920V 1W zener21Gali-21MC AZ SOT89DC-8GHz MMIC amp 14 dB gain 22MMBT4209Nat N SOT23pnp sw 850MHz 2N420922DTC123EUA Rho N SC70npn dtr 2k2+2k2 50V 100ma 22DTC123EKA Rho N SC59npn dtr 2k2+2k2 50V 100ma 22V PZM22NB Phi C SOT34622V 300mW zener22Y BZV49-C22Phi O SOT8922V 1W zener23MMBT3646Nat N SOT23npn sw 350MHz 2N364623DTC143EUA Roh N SC70pnp dtr 50V 100mA 4k7+ 4k7 23DTC143EKA Roh N SC59pnp dtr 50V 100mA 4k7+ 4k7 -23PDTA114TU Phi N SOT323pnp dtr R1 10kt23PDTA114TU Phi N SOT323pnp dtr R1 10k24MMBD2101Nat C SOT23Si diode 100V 200mA23U TK61023S Tok-SOT23-5Voltage detector23U TK16123Tok-SOT23L ADJ Digital Delay Line24DTC114ECA Roh N SOT23npn dtr 50V 100mA 10k + 10k 24DTC114EUA Roh N SC70npn dtr 50V 100mA 10k + 10k 24DTC114EKA Roh N SC59npn dtr 50V 100mA 10k + 10k 242SC5006Nec N -npn RF fT 4.5GHz @3V 7mA 24F ZHT2431F02Zet H SOT23High temp. Adjustable zener shunt Reg.-24PDTC114TU Phi N SOT323npn dtr R1 10kt24PDTC114TU Phi N SOT323npn dtr R1 10k24V PZM24NB Phi C SOT34624V 300mW Zener24Y BZV49-C24Phi O SOT8924V 1W zener25MMBD2102Nat K SOT23Si diode 100V 200mA25DTC124ECA Roh N SOT23npn dtr 50V 100mA 22k + 22k 25DTC124EKA Roh N SC59npn dtr 50V 100mA 22k + 22k 25DTC124EUA Roh N SC70npn dtr 50V 100mA 22k + 22k 25U TK61025S Tok-SOT23-5Voltage detector26MMBD2103Nat D SOT23dual MMBD120126DTC144EKA Roh N SC59npn dtr 50V 30mA 47k + 47k 26DTC144EUA Roh N SC70npn dtr 50V 30mA 47k + 47k 27MMBD2104Nat B SOT23dual cc MMBD120127U TK61027S Tok-SOT23-5Voltage detector27V PZM27NB Phi C SOT34627V 300mW Zener27Y BZV49-C27Phi O SOT8927V 1W zener28BFP280T Tfk W -npn RF fT 7GHz 8V 10mA 28MMBD2105Nat A SOT23dual ca MMBD1201-28PDTA114WU Phi N SOT323pnp dtr29MMBD1401Nat C SOT23Si diode 200V 100mA29DTC115EE Roh N EMT3npn dtr 100k +100k 50V 20mA 29DTC115EUA Roh N SC70npn dtr 100k +100k 50V 20mA 29DTC115EKA Roh N SC59npn dtr 100k +100k 50V 20mA 200SSTPAD200Sil J -PAD-200 200pA leakage diode 201PZM20NB1Phi C SOT34620V 300mW Zener202PZM20NB2Phi C SOT34620V 300mW Zener203PZM20NB3Phi C SOT34620V 300mW Zener221PZM22NB1Phi C SOT34622V 300mW Zener222PZM22NB2Phi C SOT34622V 300mW Zener223PZM22NB3Phi C SOT34622V 300mW Zener241PZM24NB Phi C SOT34624V 300mW Zener242PZM24NB Phi C SOT34624V 300mW Zener243PZM20NB Phi C SOT34624V 300mW Zener271PZM2.7NB1Phi C SOT346 2.7V 300mW Zener272PZM2.7NB2Phi C SOT346 2.7V 300mW Zener2A MMBT3906L Mot N SOT232N39062A MMBT3906W Mot N SOT3232N39062A FMMT3906Zet N SOT232N3906t2A PMBT3906Phi N SOT232N3906t2A PMST3906Phi N SOT3232N3906p2A PMBT3906Phi N SOT232N3906p2A PXT3906Phi O SOT892N39062A4PZM2.4NB2A Phi A SOT346dual 2.4V cc Zener2A7PZM2.7NB2A Phi A SOT346dual 2.7V cc Zener2B BC849B ITT N SOT23BC549B2Bs BC849B Sie N SOT23BC549B2Bs BC849BW Sie N SOT323BC549B2Bp BC849B Phi N SOT23BC549B2Bt BC849BW Phi N SOT323 BC549B2B-BC849BW Phi N SOT323 BC549B2B FMMT2907Zet N SOT232N29072B MMBT2907Mot N SOT23MPS2907p2B PMBT2907Phi N SOT232N2907t2B PMBT2907Phi N SOT232N29072BR BC849BR Phi R SOT23R BC549B2BZ FMMT2907Zet N SOT232N29072C BC849C ITT N SOT23BC549C2Cs BC849C Sie N SOT23BC549C2Cs BC849CW Sie N SOT323BC549C2Cp BC849C Phi N SOT23BC549C2Ct BC849C Phi N SOT23BC549C2Ct BC849CW Phi N SOT323BC549C2C-BC849CW Phi N SOT323BC549C2C MMBTA70Mot N SOT23MPSA702CR BC849CR Phi R SOT23R BC549C2CZ FMMTA70Zet N SOT23MPSA702D MMBTA92Mot N SOT23MPSA92 pnp Vce 300Vp2D PMBTA92Phi N SOT23MPSA92 pnp Vce 300Vp2D PXTA92Phi O SOT89MPSA92 pnp Vce 300Vt2D PMBTA92Phi N SOT23MPSA92 pnp Vce 300Vt2D PMSTA92Phi N SOT323MPSA92 pnp Vce 300V2E MMBTA93Mot N SOT23MPSA93 pnp Vce 200V2E FMMT-A93Zet N SOT23MPSA93t2E PMBTA93Phi N SOT23MPSA93 pnp Vce 200Vt2E PMSTA93Phi N SOT323MPSA93 pnp Vce 200V2F BC850B ITT N SOT23 BC550B2Fs BC850B Sie N SOT23 BC550B2Fs BC850BW Sie N SOT323 BC550B2Fp BC850B Phi N SOT23 BC550B2Ft BC850B Phi N SOT23 BC550B2Ft BC850BW Phi N SOT323 BC550B2F-BC850BW Phi N SOT323 BC550B2F FMMT2907A Zet N SOT232N2907A2F MMBT2907A Mot N SOT23MPS2907A2F MMBT2907AW Mot N SOT323MPS2907Ap2F PMBT2907A Phi N SOT232N2907Ap2F PXT2907A Phi O SOT892N2907At2F PMBT2907A Phi N SOT232N2907At2F PMBT2907A Phi N SOT3232N2907A2FR BC850BR Phi R SOT23R BC550B2G BC850C ITT N SOT23 BC550C2Gs BC850C Sie N SOT23 BC550C2Gp BC850C Phi N SOT23 BC550C2Gt BC850C Phi N SOT323 BC550C2Gt BC850CW Phi N SOT323 BC550C2G-BC850CW Phi N SOT323BC550C2G FMMT-A56Zet N SOT23MPSA562G MMBTA56Mot N SOT23MPSA56p2G PMBTA56Phi N SOT23MPSA56t2G PMBTA56Phi N SOT23MPSA56t2G PMSTA56Phi N SOT323MPSA562GM MMBTA56Mot N SOT23MPSA562GR BC850CR Phi R SOT23R BC550C2GT SOA56SGS N SOT23MPSA562H ABA-52563Agi DU SOT363 3.5 GHz Broadband Amplifier2H FMMT-A55Zet N SOT23MPSA552H MMBTA55Mot N SOT23MPSA552HT SOA55SGS N SOT23MPSA55t2H PMBTA55Phi N SOT23MPSA55t2H PMSTA55Phi N SOT323MPSA552J MMBT3640Mot N SOT23MPS3640 pnp sw2K BAT754Phi C SOT23Schottky barrier diode2K FMMT4402Zet N SOT232N44022K MMBT8598Mot N -2N4125 pnp 60V2L BAT754A Phi J SOT23Schottky barrier double diodes 2L MMBT5401Mot N SOT232N5401 pnp 150V2L FMMT4403Zet N SOT232N4403p2L PMBT5401Phi N SOT232N5401 pnp 150Vt2L PMBT5401Phi N SOT232N5401 pnp 150Vt2L PMST5401Phi N SOT3232N5401 pnp 150V2M BAT754C Phi B SOT23Schottky barrier double diodes 2M FMMT5087Zet N SOT232N50872M MMBT404Mot N SOT23pnp-chopper 24V 150mA2N BAT754S Phi D SOT23Schottky barrier double diodes 2N MMBT404A Mot N SOT23pnp-chopper 35V 150mA2N0ZXT11N20DF Zet N SOT23npn 20V 2.5A low sat switch2P FMMT2222R Zet R SOT23R2N22222P MMBT5086Mot N SOT232N50862Q MMBT5087Mot N SOT232N50872R HSMS-8102HP Z SOT2310-14GHz schottky mixer pair2T SO4403SGS N SOT232N44032T MMBT4403Mot N SOT232N4403p2T PMBT4403Phi N SOT232N4403p2T PXT4403Phi O SOT892N4403t2T PMBT4403Phi N SOT232N4403t2T PMST4403Phi N SOT3232N44032T HT2Zet N SOT23pnp 80V 100mA2U MMBTA63Mot N SOT23MPSA63 darlingtont2U PMBTA63Phi N SOT23MPSA63 darlington2V MMBTA64Mot N SOT23MPSA64 darlingtonp2V PXTA64Phi O SOT89MPSA64 darlingtont2V PMBTA64Phi H SOT23MPSA64 darlington2V4PZM2.4NB Phi C SOT346 2.4V 300mW Zener2V7PZM2.7NB Phi C SOT346 2.7V 300mW Zener2W FMMT3905Zet N SOT232N39052W MMBT8599Mot N -2N4125 Vce 80V pnp2X SO4401SGS N SOT232N44012X MMBT4401Mot N SOT232N4401p2X PMBT4401Phi N SOT232N4401p2X PxT4401Phi O SOT892N4401t2X PMBT4401Phi N SOT232N4401t2X PMST4401Phi N SOT3232N44012Y4BZV49-C2V4Phi O SOT89 2.4V 1W zener2Y7BZV49-C2V7Phi O SOT89 2.7V 1W zener2Z MMBT6520Mot N SOT232N6520 pnp Vce 350V2Z BAS70-04Zet D SOT23dual series RF schottky 70V 15mA 2Z5BAS70-05Zet B SOT23dual cc RF Schottky 70V 15mACode Device Manufacturer Base Package Leaded Equivalent/Data3BAT60A Sie I SOD32310V 3A sw schottky3BAT62-02W Sie I SCD80-30MUN5330DW1Mot DP SOT363npn/pnp dtr 1k0+1k030U TK61030S Tok-SOT23-5Voltage detector30V PZM30NB1Phi C SOT34630V 300mW zener30Y BZV49-C30Phi O SOT8930V 1W zener301FDV301N Fch M SOT23n-ch 'digital' fet 25V 0.22A302FDV302P Fch M SOT23p-ch 'digital' fet 25V 0.13A303FDV303N Fch M SOT23n-ch 'digital' fet 25V 0.68A304FDV304P Fch M SOT23p-ch 'digital' fet 25V 0.46A31MUN5331DW1Mot DP SOT363npn/pnp dtr 2k2+2k231MMBD1402Nat K SOT23Si diode 200V 100mAp31PDTA143XT Phi N SOT23pnp dtr 4k7+10kt31PDTA143XT Phi N SOT23pnp dtr4k7+10k32MUN5332DW1Mot DP SOT363npn/pnp dtr 4k7+4k732MMBD1403Nat D SOT23dual Si diode 200V 100mA32BAT32Sie CS -18GHz zero-bias schottkyp32PDTC143XT Phi N SOT23pnp dtr 4k7+10kt32PDTC143XT Phi N SOT23pnp dtr 4k7+10ks33MUN5333DW1Mot DP SOT363npn/pnp dtr 4k7+47k33DTA143XE Roh N EMT3pnp dtr 4k7+10k 50V 100mA33DTA143XUA Roh N SC70pnp sw 4k7+10k bias res 50V 100mA 33DTA143XKA Roh N SC59pnp sw 4k7+10k bias res 50V 100mA 33MMBD1404Nat B SOT23dual cc Si diode 200V 100mA33Gali-33MC AZ SOT89DC-4GHz MMIC amp 19dB gain 33U TK61033S Tok-SOT23-5Voltage detector33V PZM33NB1Phi C SOT34633 300mW zener33Y BZV49-C33Phi O SOT8933V 1W zener34MUN5334DW1Mot DP SOT363npn/pnp dtr 22k+47k34MMBD1405Nat A SOT23dual ca Si diode 200V 100mA 331NDS331N Fch M SOT23n-ch mosfet 1.3A 20V331PZM3.3NB1Phi C SOT346 3.3V 300mW zener332PZM3.3NB2Phi C SOT346 3.3V 300mW zener332NDS332N Fch M SOT23p-ch mosfet 0.4A, 1A pk, 20V 335NDS335N Fch M SOT23n-ch mosfet 70 mA, 1.7A pk, 20V 336NDS336N Fch M SOT23p-ch mosfet 0.27A, 1.2A pk, 20V 337NDS337N Fch M SOT23n-ch mosfet 50 mA, 2.5A pk 20V 338NDS338N Fch M SOT23p-ch mosfet 0.13A, 1.6Apk 20V 342SC5007Nec N -npn RF fT 7GHz @3V 7mA340FDV340P Fch M SOT23p-ch mosfet 20V 70 mA35MUN5335DW1Mot DP SOT363npn/pnp dtr 2k2+47k35DTA124XE Roh N EMT3pnp dtr 22k+47k 50V 50mA35DTA124XUA Roh N SC70pnp dtr 22k+47k 50V 50mA35DTA124XKA Roh N SC59pnp dtr 22k+47k 50V 50mA351NDS351N Fch M SOT23n-ch mosfet 1.1A 30V352NDS352N Fch M SOT23p-ch mosfet 0.5A 20V355NDS355N Fch M SOT23n-ch mosfet 0.1A, 1.6A pk 30V 356NDS356N Fch M SOT23p-ch mosfet 0.3A, 1.1A pk 20V 357NDS357N Fch M SOT23n-ch mosfet 2.5Apk 30V358NDS358N Fch M SOT23p-ch mosfet 0.2A, 1.6A pk 30V 358FDN358N Fch M SOT23p-ch mosfet 0.2A 1.6A pk 30V 360FDN360P Fch M SOT23p-ch mosfet 80mA, 2a PK, 30V 361PZM3.6NB1Phi C SOT346 3.6V 300mW Zener362PZM3.3NB2Phi C SOT346 3.6V 300mW Zener36U TK61036S Tok-SOT23-5Voltage detector36V PZM36NB1Phi C SOT34636V 300mW Zener36Y BZV49-C36Phi O SOT8936V 1W zener391PZM3.9NB1Phi C SOT346 3.9V 300mW Zener392PZM3.9NB2Phi C SOT346 3.9V 300mW Zener39V PZM39NB1Phi C SOT34639V 300mW Zener39Y BZV49-C39Phi O SOT8939V 1W zener3A BC856A ITT N SOT23BC556A3A BC856AT Phi N SOT416BC556A3Ap BC856A Phi N SOT23BC556A3At BC856A Phi N SOT23BC556A3As BC856A Sie N SOT23BC556A3At BC856AW Phi N SOT323BC556A3A-BC856AW Phi N SOT323BC556A3A MMBTH24Mot N SOT23VHF mixer npn fT 600MHz 3A0PZM3.0NB2A Phi C SOT346dual 3.0V Zener3A3PZM3.3NB2A Phi C SOT346dual 3.3V Zener3A6PZM3.6NB2A Phi C SOT346dual 3.6V Zener3A9PZM3.9NB2A Phi C SOT346dual 3.9V Zener3AR BC856AR Phi R SOT23R BC556A3B BC856B ITT N SOT23BC556B3B BC856BT Phi N SOT416BC556B3Bp BC856B Phi N SOT23BC556B3Bs BC856B Sie N SOT23BC556B3Bt BC856B Phi N SOT23BC556B3Bt BC856BW Phi N SOT323BC556B3B-BC856BW Phi N SOT323BC556B3B FMMT918Zet N SOT232N9183B MMBT918Mot N SOT232N9183BR BC856BR Phi R SOT23BC556B3C FMMTA20R Zet R SOT23R MPSA203C BC857Sie DO -pnp separate pair gp AF 3D BC856Phi N SOT23BC556 hfe 75 min3Dp BC856Phi N SOT23BC556 hfe 75 min3Dt BC856Phi N SOT23BC556 hfe 75 min3Dt BC856W Phi N SOT323BC556 hfe 75 min3D-BC856W Phi N SOT323BC556 hfe 75 min3D MMBTH81L Mot N SOT23UHF pnp fT 600MHz3D BC856S Sie DO -pnp separate pair gp AF 3E BC857A Phi N SOT23BC557A3E BC857AT Phi N SOT416BC557A3Ep BC857A Phi N SOT23BC557A3Et BC857A Phi N SOT23BC557A3Et BC857A Phi N SOT323BC557A3E-BC857A Phi N SOT323BC557A3E MMBTH10Mot N SOT23MPSH10 fT 650MHz3E FMMT-A42Zet N SOT23MPSA423EM MMBTH10L Mot N SOT23VHF amp 650MHz fT3ER BC857AR Phi R SOT23R BC557A3EZ FMMTH10Zet N SOT23npn fT 650MHz3F BC857B Phi N SOT23BC557B3F BC857BT Phi N SOT416BC557B3Fp BC857B Phi N SOT23BC557B3Fs BC857B Sie N SOT23BC557B3Ft BC857B Phi N SOT23BC557B3Ft BC857BW Phi N SOT323BC557B3Ft BC857BS Phi N SOT363BC557B3F-BC857BW Phi N SOT323BC557B3FR BC857BR Phi R SOT23R BC557B3G BC857C Phi N SOT23BC557C3Gp BC857C Phi N SOT23BC557C3G BC857C Phi N SOT23BC557C3Gs BC857C Sie N SOT23BC557C3Gt BC857C Phi N SOT23BC557C3Gt BC857CW Phi N SOT323BC557C3G-BC857CW Phi N SOT323BC557C3G MMBTH11NS N SOT23-3G MGSF3454X Mot DK TSOP6n-ch enh tmosfet 1.75A 3GR BC857CR Phi R SOT23R BC557CR3Hp BC857C Phi N SOT23BC5573Ht BC857C Phi N SOT23BC5573Ht BC857CW Phi N SOT323BC5573H MMBTH30NS N SOT23-3H-BC857CW Phi N SOT323BC5573J MMBTH69Mot N SOT23pnp UHF fT 2GHz3J BC858A Phi N SOT23BC558A3Js BC858A Sie N SOT23BC558A3JR BC858AR Phi R SOT23R BC558A3Js BCV62A Sie VQ SOT143pnp current mirror hFe 180。

ELECTRONIC GIANT EG2113D芯片数据手册大功率MOS管、IGBT管栅极驱动芯片版本变更记录目录1. 特点 (4)2. 描述 (4)3. 应用领域 (4)4. 引脚 (5)4.1. 引脚定义 (5)4.2. 引脚描述 (6)5. 结构框图 (7)6. 典型应用电路 (7)7. 电气特性 (8)7.1 极限参数 (8)7.2 典型参数 (9)7.3 开关时间特性及死区时间波形图 (10)8. 应用设计 (11)8.1 Vcc端电源电压 (11)8.2 输入逻辑信号要求和输出驱动器特性 (11)8.3 自举电路 (12)9. 封装尺寸 (13)9.1 SOW16封装尺寸 (13)9.2 SOP16封装尺寸 (14)EG2113D芯片数据手册V1.01. 特点◼高端悬浮自举电源设计，耐压可达600V◼集成内部自举二极管，外围器件少◼最高频率支持500KHZ◼低端VDD电压范围3.3V-5V◼低端VCC电压范围10V-20V◼输出电流能力IO+/- 2A/2A◼内建死区控制电路◼自带闭锁功能，彻底杜绝上、下管输出同时导通◼HIN输入通道高电平有效，控制高端HO输出◼LIN输入通道高电平有效，控制低端LO输出◼静态电流小于50uA◼封装形式：SOW16和SOP162. 描述EG2113D是一款高性价比的大功率MOS管、IGBT管栅极驱动专用芯片，内部集成了逻辑信号输入处理电路、死区时控制电路、闭锁电路、电平位移电路、脉冲滤波电路、自举二极管及输出驱动电路，专用于无刷电机控制器中的驱动电路。

EG2113D高端的工作电压可达600V，低端Vcc的电源电压范围宽10V～20V，静态功耗小于50uA。

该芯片具有闭锁功能防止输出功率管同时导通，输入通道HIN和LIN 内建了一个200K下拉电阻，在输入悬空时使上、下功率MOS管处于关闭状态,输出电流能力IO+/- 2A/2A，采用SOP16和SOW16封装。

PMD MCU可编程变频马达驱动 专用单片机TOLS Software System Engineering(Shanghai) Co.,LTD1Toshiba PMD MCU RoadmapPlanningPMD2 Sine wave or square wave commutation types available870/X core 20 MHz100 TMP88FW44 120kB pins TMP88FW44 120kB Flash Flash 100 pinsPMD3 Vector Control16-bit DSP Core 20MHzUnder development Automotive useVector Engine 40MHz ~ 80MHz +5V single power supply64 pins 64 pins 32kB 32kBTMP77CM70TPMD 1 channel 256kB 256kBPMD 22channels PMD channelsVector Engine80 pins 80 TMP88FW45 120kBpins TMP88FW45 120kB Flash FlashPMD 22channels PMD channelsVector Control32-bit RISC Core 100 pins 100 pinsTMP19A71PMD 2 channelsTMP88CS43 TMP88CS43PMD 22channels PMD channels80 pins 80 pins 64kB Flash 64kB Flash 64 pins 64 pins 64kB Flash 64kB Flash 44/42 pins 44/42 pins 16kB Flash 16kB Flash 44 pins 44 pins 16/8kB Flash 16/8kB FlashUnder development Automotive usePMD2 plus Instruction execution speed of870/C1 Core 1.6 faster than 870/XTMP88CS42 TMP88CS42Improved PMDPMD 22channels PMD channelsTMP89FM82TPMD 1 channel48 pins 48 pins 32kB 32kBPMD2+BiCMOS870/C1 CoreTMP88CH41 TMP88CH41PMD 11channel PMD channelPlanningMulti-purposeTMP88CH47 TMP88CH47 TMP88CH48 TMP88CH48 TMP88CH49 TMP88CH49PMD1870/X Core 16 MHzTMP89FM5x48 pins 48 pins 32kB 32kBSiPTBxxxxxxPMD+BiCMOSTMP88F846New!!TMP88FH41PMD 1 channel28 pins 28 pins 16kB Flash 16kB FlashSpeed up44 pins TMP89FM5y 44 pins 32kB 32kB 30 pins TMP89FH5z 30 pinsAll-in one motor control MCU & DriverPMD 1 channel16kB 16kBTMP88CH40 TMP88CH40PMD 11channel PMD channelSiP: Silicon in packageTOLS Software System Engineering(Shanghai) Co.,LTD2PMD MCU应用领域Phase-2 PMD 870/X Core@20MHz44/42pinTMP88CH41N/UPMD 1ch单个变频马达 控制应用TMP88CH40N/MPMD 1ch28pinTMP88CS43FPMD 2ch80pinTMP88CS42N/FPMD 2ch64pinTMP19A71100pinPMD 2ch单芯片双路变频 马达应用3TOLS Software System Engineering(Shanghai) Co.,LTD电机控制电路的结构电机控制系统框图 以下通过方波驱动不带传感器的BLDC (brushless DC)电机来说明控制方法 DC 电流 PMD 电路 三相 PWM 保护电路 位置检测 电角度定时器 波形运算 PDU,PDV,PDW U,V,W,X,Y,Z CL,EMG 功率驱动 前相: U,V,W 后相: X,Y,ZMCU 速度控制 错误处理 位置值预置 采样定时器 设置 等等.软件工作量小接口简单DC MotorTOLS Software System Engineering(Shanghai) Co.,LTD4PMD MCU 与通用MCU性能对比通用MCU 位置检测 软件查找，位置信号的检测被 延迟。

青岛恒达新款多功能液晶维修编程器V9.0版使用说明书恒达公司多功能液晶维修编程器，集成了目前市场上所有液晶维修编程器的功能，并在此基础上又增加了一些独特的功能，可以说是目前国内市场上功能最全的液晶维修工具。

产品功能：1、支持乐华、凯旋等通用驱动板烧录2、支持三星全系列液晶显示器MCU在线烧录工作3、支持三星全系列液晶显示器MCU离线烧录工作4、支持NT68F63L系列MCU在离线烧录5、支持NT68F633系列MCU在离线烧录6、支持老款MCU为42针脚的MCU烧录7、支持在线读取MCU数据功能8、支持离线读取MCU数据功能9、支持三星CRT显示器工厂软件调整10、支持所有普通CRT显示器数据更新11、支持读取所有普通显示器数据12、支持软件自动升级产品清单：1、多功能编程器一个2、25针并口数据线一条3、编程器专用电源一个4、软件配套光盘一张（内含通用板程序、三星程序一套，CRT程序等）5、赠送9000多种液晶屏定义产品图片及相关接口如下图：一、烧录通用驱动板以目前用得最多的乐华2025L板为例：1、打开光盘，找到“通用驱动程序”文件夹下的“编程器烧录安装程序”里面“并口驱动”，打开该文件夹里的“”软件，会出现如下图所示：点击后，如下图所示点击YES，弹出下图所示点击下一步（即NEXT），安装时用默认的目录安装就可以了，下一步，点击下一步，下一步下一步，安装完成，点击Finish后，重启电脑就可以了。

安装好烧录程序以后，将编程器的并口连线接到电脑的并口，2025L板的连接示意图如下：将编程器和2025L驱动板（编程器用函授套装里的专用电源，2025L板用普通的12V4A电源）通电，通电后即可执行下列操作：打开“2025板最新程序及软件”文件夹里面的小蜘蛛图标，打开后，如下图所示：选择 RTD 2120 ISP（注此界面其它选项按默认的），点击后会弹出如下图：选择Main选项，如图点击64K按钮，会弹出如下图对话框，选择升级文件（即你所需要烧录的驱动程序）打开“2025板最新程序及软件”后，如下图：选择升级文件后用鼠标单击升级按钮，即开始升级，这时会看到百分数在跑，如下图从1%跑到100%后，出现如下图则表示升级成功，然后板卡会自动开机。

k3569场效应管参数及代换
摘要：
1.介绍K3569 场效应管的参数
2.K3569 与其他场效应管的代换情况
3.K3569 在实际应用中的注意事项
正文：
一、K3569 场效应管的参数
K3569 是一种600V、10A 的场效应管，具有较高的电压和电流承受能力。

它的主要参数包括源极漏极电压、栅极电压、漏极电流等，这些参数决定了场效应管的工作性能。

二、K3569 与其他场效应管的代换情况
K3569 可以替换K3562 场效应管，因为两者的电压和电流参数相似。

但是，K3562 不能替换K3569，因为K3562 的电流承受能力较低（6A），无法满足K3569 的需求。

此外，K3569 还可以与其他场效应管如6N80、
7N80 等进行替换，具体替换情况需要根据实际应用中的电压和电流需求来确定。

三、K3569 在实际应用中的注意事项
在实际应用中，使用K3569 场效应管时需要注意以下几点：
1.根据电路需求选择合适的场效应管型号，注意电压和电流参数的匹配。

2.在使用过程中要注意散热，场效应管工作时会产生热量，过高的温度会影响其性能和寿命。

3.确保场效应管的工作环境符合其额定参数的要求，避免因电压、电流等参数超出范围而导致损坏。

总之，K3569 是一种性能优良的场效应管，广泛应用于各种电子设备中。

Application NoteC005 Pos Fbk Alignment for PMAC motorsHA502487C005_002AC30P/D V2.13 onwardsCopyright 2018 Parker SSD Drives, a division of Parker Hannifin Ltd.All rights strictly reserved. No part of this document may be stored in a retrieval system, or transmitted in any form or by any means to persons not employed by a Parker SSD Drives company without written permission from Parker SSD Drives, a division of Parker Hannifin Ltd . Although every effort has been taken to ensure the accuracy of this document it may be necessary, without notice, to make amendments or correct omissions. Parker SSD Drives cannot accept responsibility for damage, injury, or expenses resulting therefrom.iRequirementsIntended UsersThis Application Note is to be made available to all persons who are required to install,configure or service equipment described herein, or any other associated operation.The information given is intended to enable the user to obtain maximum benefit from theequipment.Application AreaThe equipment described is intended for industrial motor speed control utilising AC induction orAC synchronous machines.PersonnelInstallation, operation and maintenance of the equipment should be carried out by qualifiedpersonnel. A qualified person is someone who is technically competent and familiar with allsafety information and established safety practices; with the installation process, operation andmaintenance of this equipment; and with all the hazards involved.HazardsRefer to the Safety Information given at the front of the Product Manual supplied with everyParker SSD Drives product.iiC005P OS F BK A LIGNMENT FOR PMACM OTORSAbstractThis Application Note gives information and how to use the Pos Fbk Alignment feature to align position frommotor feedback to the PMAC motor back EMF. This is required to run the PMAC motor in Vector Control mode. Pre-RequisiteThe pre-requisites are :- a AC30 drive- a feedback attached to the motor with the associated feedback option fitted into the drive.Parameters described below are part of PMAC Motor Data and Pos Fbk Aligmnent. IntroductionBy definition, the motor Vector Control is based on the assumption that the back EMF is crossing the 0V line in a positive direction when the electrical position is also crossing the 0° line in a positive way. Another requirement is to insure a positive ‘encoder/resolver’ rotation with a positive electrical motor rotation ( U, V, W ).1The Pos Fbk Alignment feature is used to automatically calculate any offset between the Zero encoder absolute position and the motor back EMF, as well as selecting the correct wiring of the motor ( U, V, W sequence ) with the encoder position.The feature needs to be run at least once with a PMAC motor associated to an absolute encoder type.The feature needs to be run after each power cycle with a PMAC motor associated to a relative encoder type (pulse encoder for example ). In that case, the absolute position information is lost by the power cycle and thealignment is required after power ON.The feature is run on a motor free to rotate, no load attached to the motor shaft.Regardless of the Alignment Method selected, the motor should move during the sequence.Pos Fbk Alignment operation2 Methods can be selected to align feedback and motor.Alignment Method = MANUALThe motor is moved to an electrical position corresponding to the motor phase selected by Alignment On Motor parameter.This electrical position depends on the PMAC Wiring type selected and on the real motor phase wiring.PMAC Encoder Offset is calculated by looking at real position from the active encoder compared to theoretical position where the motor is.So, it depends also on the encoder settings ( inverted or not ).For standard connections ( correct U, V, W motor wiring sequence and position from encoder varying in a positive way looking at the motor front shaft ), position offset is extracted and written back into PMAC Encoder Offset.Correct connection of the encoder means that a clockwise rotation of the motor front shaft equals a positiveposition variation.Correct motor wiring means phase U, V, W rotating in a correct sequence for a clock wise rotation of the motor front shaft.Considering a standard connection, the following table gives possible encoder and PMAC Wiring settings and results on speed control :** Looking the front shaft of the motor23*** The motor is uncontrolled. It could overspeed, be stalled, or running at constant speed without any control.Alignment Method = AUTOMATICIn case of a correct wiring of encoder and/or motor phases, the sequence is as follows :Current%Elec pos 1 2 3 4 5 6 7 8 9 10 11 12States 210°-30°90°During the final state ( 11 ) , the Alignment Offset is automatically calculated and is passed back to 1808 PMAC Encoder OffsetAlso 1809 PMAC Wiring is set to STANDARDIn the case of a wrong wiring of encoder and/or motor phases, the sequence is as follows :Current%Elec pos 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18States 210°-30°90°From State 4 to 9, a wrong direction as been detected, and the direction should be reverted. Alignment Direction is set to REVERSE.During the final state ( 17 ), the Alignment Offset is automatically calculated and is passed back to 1808 PMAC Encoder OffsetAlso 1809 PMAC Wiring is set to REVERSE.In that case, the direction of motor rotation has been changed during the Pos Alignment sequence. Please verify if the new direction is compatible with your application.If you want to change it, please change the Invert parameter of the active encoder used to control the motor and run again the Pos alignment sequence.Setting up Alignment Method = DIRECTION TEST allows to verify the direction of positive electrical position by slowly rotating the motor. A correct wiring of the motor phases should turn the motor in a clockwise direction looking at the front shaft of the motorThe motor is slowly rotated with the following sequence U, V, W, U, V, W…..It allows to verify the rotation direction and detect any wiring inversion on the motor phases.Active encoder Invert parameter has no effect during this test.Looking at the position variation from the active encoder may help to know if the active encoder is correctlywired.Considering a correct connection of the motor phases :When running this Method, either set 1257 Seq Stop Method to DISABLE VOLTAGE or 0505 Zero SpeedThreshold to 1% otherwise you may end up with a motor rotating at slow speed for 60s without any possibility to stop it.Running the sequenceThe feature is run on a motor free to rotate, no load attached to the motor shaft.Regardless of the Alignment Method selected, the motor should move during the sequence.The sequence is validated by Alignment Enable input.The drive waits for a START/TORQUE ON condition to start the cycle.The sequence can be stopped by a STOP/TORQUE OFF command anywhere during the cycle.A successful sequence sets Alignment Ended = TRUE.A STOP/TORQUE OFF command is needed to stop the sequence.If Alignment Method is set to AUTOMATIC, it is possible that the direction of motor rotation for apositive setpoint could be reversed. The parameter PMAC Wiring can be changed by the sequence ifan incompatibility of direction between the encoder and the motor phases wiring is found.Alignment on Power OnAs the feature needs to be run after each power cycle with a PMAC motor associated to a relative encoder type ( pulse encoder for example ), a parameter 1796 Alignment On Power On xould bet set up to TRUE.4Set to TRUE, it automatically trips the drive after a power up on a Start command until an Alignment sequence is run and completed successfully.ApplicationBelow is a simple example on how to force the system to run a Pos Alignment sequence on the first start after power_up :Alignment On Power On has been set to TRUEAlignment Method is set to Manual ( It could have been set to AUTOMATIC ).Alignment Enable is TRUE from Start-up.The first start command will run the Pos Alignment sequence.A running and successfully sequence resets Alignment_Enable to FALSE.A 1s negative pulse is generated at the end of the sequence ( positive at Q output of TP_1). This information can be used to toggle any command to start the system.The feature is run on a motor free of rotation, no load attached to the motor shaft.Depending of the Alignment Method selected, the motor is moving during the sequence.56。

不知道发过没？各大LED驱动芯片大全Fairchild (美国飞兆) FSEZ 1016主要应用于3W灯杯3WFSEZ 1216主要应用于5W灯杯5WFSQ 110主要应用于8W左右LED电源8WFSDH 321主要应用于8W左右LED电源8WKA5M02659RN主要应用于12W左右LED电源12WKA5M0365R/KA5M0380RYDTU主要应用于30W左右LED电源30WFSDL0165/FSDM0265/FSDM0365 主要应用于12-18WLED电源12-18WKA5L0365RN/KA5M0365RN主要应用于24WLED电源25WSG6859 + 2N60/4N60主要应用于日光灯等外置式LED电源30W 以下SG6741 + 7N60C/7N60C主要应用于日光灯等外置式LED电源60W 以下FSFR2100主要应用于LED路灯和大功率LED电源200W待补充Power Integrations (PI) LNK603/613PG/DG主要应用于2.5W的LED灯杯2.5WLNK604/614PG/DG主要应用于3.5W的LED灯杯3.5WLNK605/615PG/DG主要应用于4.5W的LED灯杯4.5WLNK606/616PG/GG主要应用于5.5W的LED灯杯5.5WTNY274/275/276/277P/G主要应用于5-8W LED电源5-8WTNY278/279/280P/G主要应用于10-14W LED电源10-14W待补充Supertex (美国超科) AT9933专为汽车设计用高达70V功率驱动ICHV9921/22/2385 to 264V AC or DC input voltage of 20 to400V. 20/30/50mAHV9925Output Current to 50mA;Universal 85-264V AC Operation;Fixed OFF-Time BuckConverter;Internal 500V Power MOSFETHV9903Power efficiency of up to 85%;Drives up to 6 White LEDs;2.6V to 4.6VSupply;power stage can operate at 1.8V;Built-in Soft Start;DC and PWM DimmingControlHV9910高压大功率直驱LED恒流器件HV9911高压双向检测大功率直驱LED恒流ICHV9931高压双向检测大功率直驱LED恒流IC,可PWM灰度调节待补充National (美国国半) 针对带有双电流槽和与IC兼容亮度控制的白色LED和QLED显示器的高效升压器LM3402针对高功率LED驱动器、6V至42V输入电压范围的0.5A持续电流降压电路LM3402HV 针对高功率LED驱动器,6V至75V输入电压范围的0.5A持续电流降压电路LM3404针对高功率LED驱动器,6V至42V输入电压范围的1A持续电流降压电路LM3404HV 针对高功率LED驱动器、6V至75V输入电压范围的1.0A持续电流降压电路LM5022针对升压和SEPIC稳压器的60V低压侧控制器,允许控制外部MOSFET来为LED提供LM2735 520kHz/1.6MHz - 有效使用空间的升压和SEPIC DC-DC稳压器LM3405用于LED驱动器500kHz/1.6MHz 1A恒流降压稳压器LM2754具有超时保护功能的800mA开关电容Flash LED驱动器LM27965具有I2C兼容亮度控制功能的双显示器白光LED驱动器LM27966带有I2C兼容接口的白光LED驱动器LM2727/ LM2737 频道的FET 同步的为低输出电压顽强反抗调整者控制器待补充美国国家半导体公司白色LED低功率驱动部分LM3519高的频率推进白色LED用高速的PWM 光亮控制驱动ICLM2731SOT23 小封装小功率LED驱动应用SOT23 小封装5V升压到12-30V,120-300mALM26238-14V 转换成输出电压在1.24-14V之间,达到90% 的效率LM3557为白色LED2.7V-7.5V的递升转换器,多大5颗LED小体积背光指示LM35022.5-5.5V升压到16-44V,多达4-10颗LED小体积背光指示LM27512 X,1.5 X 电容器式倍压白色LED的引导驱动ICLM3590系列小功率白色LED简单驱动,降压型LM2707系列小功率白色LED简单驱动,升压型LM35082.7Vto5.5V 升压17.5V 驱动4个白色LED达到30mA 应用ICLM2793白色的低噪音引2.5-5.5V,1.5倍压双重的功能光亮控制ICLM2792接受输入电压从3.0V到5.8V的范围和维持持续的电容器类光亮控制LM2791受输入电压从3V到5.8V的范围和维持持续的36mA由外部的固定电阻决定. LM2705直流的升压式150mA的直流转换器LM2703直流的升压式350mA的直流转换器LM3501同时的递升直流/ 直流转换器为白色LED的驱动LM2794/LM2795 多路驱动补给的电容器类比和PWM 灰度控制LM27953 白色LED四路的和3/2 x转变了电容器推进式驱动LM3570低的噪音白色LED,应用与手持式设备多路控制多颗LED背光指示LM3595 平行的白色LED驱动应用LM2704 2.2-7V升压20V,550mA,SOT小封装LED驱动LM2750 低的噪音转变了电容器小功率升压驱动LM2796 双重的3/2 x 的白色LED驱动电容器式应用ICLM27964 有I2C 的独立控制的,多按键区域背光指示应用ICLM2756有I2C 的独立控制的,多按键区域背光指示应用ICLM2754带有超时保护功能的800mA开关电容器Flash LED驱动器LM3551/LM35521A白色用闪光灯驱动应用LM3224直流的递升PWM 的615 KHz/1.25 MHz/直流转换器待补充美国国家半导体公司照明管理单元(LMU)LM4970声音同步化LED驱动器IC适合任何颜色LP3943RGB/白色/ 蓝色16通道引导的LED驱动器LP3944RGB/白色/ 蓝色8 通道引导的LEDLP5520RGB背光LED驱动器LP5521可编程的三通道LED 驱动器LP5522可编程的LED驱动器LP3958高电压推进的照明管理转换器LED应用ICLP5526高的电压推进的照明管理可达到150mA序列闪光的驱动ICLP3936为六白色的照明管理系统引导和一RGB 或闪光引导LP3931双路的RGB 用高亮度驱动DC-DC转换器LP3933为六白色的照明管理系统应用和二RGB 或闪光应用ICLP3954电话LED指示包括展览背光、RGB、按键区和照相机闪光等应用LP3950颜色用声音的同步装置引导LED驱动LP39526个通道的颜色用声音的同步引导驱动应用ICLP39542多路LED背光管理ICLP55281四路RGB驱动器LP5527为照相机闪光的极小驱动和4以I2C应用Programmability,连接性测试和声音LP55271为照相机闪光的极小驱动和4以I2C应用Programmability,连接性测试和声音待补充International Rectifier (IR) IRS2540S/2540PBF一款高压,高频降压调节控制集成电路,该产品用于要求多个LED的交流-直流离线,非隔离应用电路或要求直流-直流混合色能力的应用.应用包括室内外标牌,以及建筑,娱乐,设计和装饰照明.IRS2541S/2541PBF一款高压,高频降压调节控制集成电路,该产品用于要求多个LED的交流-直流离线,非隔离应用电路或要求直流-直流混合色能力的应用.应用包括室内外标牌,以及建筑,娱乐,设计和装饰照明.待补充Nxp (恩智浦) LED屏幕配套部分逻辑IC,飞利浦系列:74HC595D逻辑8位移位寄存器74HC245D3态8总线收发器74HC138D3-8线译码器、多路转换74HC164D8位移位寄存器(串进并出)74HC04D逻辑6非门74HC08D逻辑6非门驱动器74HC244D8缓冲/线驱动/线接收(3态)待补充Maxim-Dallas (美国美信) 美国美信高亮度LED驱动器部分MAX16800高电压6.5-40V驱动35-350mA多颗LED应用驱动ICMAX16801A/BPWM 控制器265V AC-85V AC1A LED驱动器MAX16802A/BPWM 控制器10.8VDC-24VDC 1A LED驱动器MAX16803 高压、350mA、高亮度LED驱动器, 提供PWM亮度调节和5V稳压器MAX16804 高电压5.5V-40V,350mA驱动和PWM 控制暗淡MAX16805/MAX16806 EEPROM可设计的,高电压,350mA台灯等现场调光驱动应用MAX16807/MAX16808 集成8通道LED驱动器,具有开关模式boost及SEPIC控制器MAX16809/MAX16810 集成16通道LED驱动器,具有开关模式boost及SEPIC控制器MAX168181.5 MHz,30A高效率LED恒流驱动MAX16819/MAX168202MHz高光亮LED驱动和5000:1灰度等级调节MAX16823高电压4.5-40V,3通道独立,5mA到70mA和外接BJT时可达到2AMAX16824/MAX16825 3通道、高亮度LED (HB LED)驱动器,6.5V至28V输入电压MAX7302低电压LED驱动器,提供闪烁控制、PWM调节、瞬变检测及电平转换待补充美国美信白光LED驱动器部分MAX8678白光LED在喇叭上整合应用ICMAX1698,MAX1698A便携式LCD屏背光源白光LED驱动应用ICMAX1848手机等小屏锂电池单色LED背光源恒流驱动ICMAX1916小体低压差式恒流驱动ICMAX1910/MAX1912锂电池1.5x/2x倍压式LED驱动器,最大120mAMAX1570锂电池1x/1.5x 倍压式LED驱动器,多路可PWM调光MAX1984/MAX1985/MAX1986白色LED超高效率恒流驱动MAX1582/MAX1582Y可编程升压型2段恒流驱动ICMAX1553/MAX1554高效率, 升压到40V为2 到10 白色LED的转换器驱动MAX1573白色泵式1 x/1.5 x驱动器,小体积QFN型封装MAX1561/MAX1599高效率,升压型转换器26V驱动2到6颗白色LED驱动MAX1574180mA,1x/2x倍压白色泵式驱动IC 3毫米x3毫米TDFN小封装MAX1583白色的引导照相机-闪光推进转换器MAX1575白色LED驱动1x/1.5x电荷泵式光源指示MAX1576480mA白色LED1x/1.5x/2x电荷泵式从背光照亮到照相机闪光灯应用MAX1578/MAX1579TFT屏与LED背光整合驱动应用ICMAX8595Z/MAX8596Z高效率,2.6-5.5V升压型32V,25mA,2-8颗LED驱动应用MAX1577Y/MAX1577Z1.2 A 白色LED闪光灯应用ICMAX8630W/MAX8630X125mA 1x/1.5x电荷泵式为5颗白色LED小型TDFN封装MAX8631X/YLED电荷泵式1x/1.5x/2x4毫米x 4毫米的二LDOs使QFN超薄封装MAX8790六线白色LED恒流驱动,适合笔记本等中尺寸LCD背光MAX8607为1.5A的1MHz PWM 推进转换器白色LED应用照相机闪光MAX8647/MAX8648 超高效率电荷泵式6LED的/ RGB驱动应用,瘦小的QFN封装待补充ONSEMI (美**森美) NCP56122通道泵式可PWM的白色LED驱动产品是LCD屏背光照明,操作模态1 x 和1.5 x 泵式驱动,87% 效率连同0.2% 相配误差.NCP5623带I2C控制的三路输出RGB LED驱动器,完全支持RGB照明或白光LED背光,内置”渐进调光”功能,能效高达94%的电荷泵,具备1x和2x两种工作模式,采用节省空间的极小型LLGA-12 2.0×2.0×0.5 mm封装NCP3065, NCV3065输出1.5 A ,输入电压 3.0 V to 40 V, PWM灰度调节,为汽车应用设计NCP5007小型小体2.7 to5.5 V 升压驱动多颗LED,小屏背光及背光指示等应用NCP5008,NCP50092.7 到6.0 V 输入电压范围,从Vbat 到15 V 的输出电压,外设光敏电阻NCP5010: Integrated Backlight LED BoostDriverNCP5030: Buck-Boost Converter to Drive aSingle LED from 1 Li-Ion or 3 Alkaline BatteriesNCP5604A, NCP5604BHigh Efficiency White LEDDriverNCP5603: High Efficiency Charge PumpConverter / White LED DriverNCP5602: 2-Channel Charge Pump White LEDDriver with I²C ControlNUD4001AC−DC 输入5.0 V, 12 V or 24 V.输出最大500mA,最简易型LED驱动ICNUD4011AC−DC 输入最大120 V.输出最大70mA,最简易型多颗LED驱动ICZetex (英国ZETEX ) ZXLB1600 LED/OLED 升压偏置1.6 - 5.5 28 75 350 MSOP10ZXLD1100 LED 升压驱动器2.5 - 5.5 28V(最大) 60 350 SC70-6ZXLD1101 LED 升压驱动器2.5 - 5.5 28V(最大) 60 350 TSOT23-5ZXLD1320 内置开关式1.5A LED 驱动器4 至18 18 122000 TDFN1433 ZXLD1321 内置开关式1A LED 驱动器1.2 至12 18 122000 TDFN1433 ZXLD1322 内置开关式0.7A LED 驱动器2.5 至15 18 122000 DFN1433 ZXLD1350 内置开关式350mA LED 驱动器7 至30 30 15 370TSOT23-5 ZXLD1360 内置开关式1A LED 驱动器7 至30 30 201000 TSOT23-5 ZXLD1362 内置开关式1A LED 驱动器6 至60 60 651000 TSOT23-5 ZXLD1575 x1/x1.5 充电泵6 通道驱动器2.7 至5.5 5.5 1000120 QFN1644 ZXLD1601 LCD/OLED 升压偏置2.5 - 5.5 VIN 至28 60 320 SC70-6ZXLD1615 LCD/OLED 升压偏置2.5 - 5.5 VIN 至28 60 320 TSOT23-5 ZXLD1937 LED 升压驱动器2.5 - 5.5 28V(最大) 60 350 TSOT23-5ZXSC300 LED 升压/降压驱动器0.8 -8.0 Vin 至Vm 200 外置开关SOT23-5 ZXSC310 LED 升压/降压驱动器0.8 -8.0 Vin 至Vm 200 外置开关SOT23-5 ZXSC380 内置开关式单室简易升压0.8 - 6.0 Vin 至20V 80 - SOT23ZXSC400 LED 升压驱动器1.8 - 8.0 Vin 至Vm 150 外置开关SOT23-6 ZXSC440 相机闪光灯驱动器1.8 - 8.0 Vin 至Vm 150 外置开关MSOP8待补充Texas Instruments (TI) TI 美国德州仪器公司屏幕驱动部分TLC59048/16 通道LED 驱动器TLC59058/16 通道LED 驱动器TLC591116 通道LED 驱动器TLC5916/TLC59178通道LED驱动器TLC592016 通道LED 驱动器TLC592116 通道LED 驱动器TLC5922带有点校正的16 通道LED 驱动器TLC5923带有点校正的16 通道LED 驱动器TLC5924具有点校正功能和预充电FET 的16 通道LED 驱动器TLC593012 通道LED 驱动器TLC5940带有EEprom 点校正与灰度PWM 控制的16 通道LED 驱动器TLC5941带有点校正与灰度PWM 控制的16 通道LED 驱动器TLC5945带有点校正、灰度PWM 控制和无延迟的16 通道LED 驱动器TI 美国德州仪器公司白光LED驱动器TPS60250具有I2C 接口的用于7 个WLED 的1.2A 高功率高效充电泵TPS60251具有I2C 接口的用于7 个WLED 的1.2A 高功率高效充电泵TPS60252同步推进转换器I2C/可并立的接口白色驱动器TPS6102*可调节、1.5A 开关、96% 高效升压转换器,具有降压模式TPS61040/41用于LCD 和白光LED 的,输入1.8-6V出28V 400mA 开关升压转换器TPS61042输入1.8-6V出30V 500mA 开关升压转换器,用于白光LED 应用领域TPS61043升压PWM灰度可调恒流LED驱动TPS6104528V 85% 效率的升压转换器,用于LCD 应用领域TPS61055具有I2C 兼容接口的 1.2A 高功率白光LED 驱动器TPS61058具有1.1A 开关的高功率单个白光LED 驱动器TPS61059具有1.5A 开关的高功率单个白光LED 驱动器TPS61060/TPS61061/TPS61062具有白光LED 亮度控制电源的15V、400mA 开关,1MHz 升压转换器TPS61080具有集成功率二极管的27V、500mA 开关、1.2MHz 升压转换器TPS61081具有集成功率二极管的27V、500mA 开关、1.2MHz 升压转换器TPS61140具有OLED和LCD背光屏双重驱动的应用ICTPS61141具有OLED和LCD背光屏双重驱动的应用ICTPS61150使用单一控制双输出LED驱动背光源驱动ICTPS61151使用单一控制双输出LED驱动背光源驱动ICTPS61150A使用单一控制双输出背光源驱动多大14颗LED能力的ICTPS61160PWM白光LED 2.7-18V升压500mA,最多6pcs LEDTPS61161PWM白光LED 2.7-18V升压500mA,最多10pcs LEDTPS61165PWM白光LED 3-18V升压1.2A,最多3pcs LEDTPS75103LDO低压差背光源LED驱动ICTPS75105LDO低压差背光源LED驱动ICTPS61180/1/25-24V输入多路25mA,最大10WLED背光驱动ICToshiba (日本东芝) TB627258位移位恒流驱动ICTB62726AN/AF16位全彩LED大屏幕TB62726ANG/AFG16位全彩LED大屏幕TCA62746AFG/AFNG16位全彩LED大屏幕带断、短路侦测及温度保护Siti (台湾点晶科技股份) DD311单信道大功率恒流驱动IC最大1A最高耐压36V线性恒流ICDD312单信道大功率恒流驱动IC最大1A最高耐压18V线性恒流ICDD313三信道大功率恒流驱动IC500mA R/G/B恒流驱动ICDM412三通道装饰照明专用可直接数据级联恒流IC 200mA R/G/B恒流驱动ICDM413三通道装饰照明专用PWM输出驱动IC 100mA R/G/B恒流驱动ICDM114,DM115新版8位驱动IC 主要是用于屏幕及灯饰DM115B通用8位恒流驱动IC 恒流一致性及稳定性高DM11A8位恒流动,用于护栏管,屏幕灯饰使用DM11C8位驱动IC 具有短断点侦测及温度保护功能,屏幕灯饰使用DM13C16位驱动IC 具有短断点侦测及温度保护功能,屏幕灯饰使用DM13A16位恒流驱动,面对低端屏幕客户DM134,DM135, DM13616位驱动IC 主要用于LED屏幕及护栏管DM13216位1024级PWM输出驱动ICDM13716位开,短路,过温智能侦测驱动ICDM13316位开路检测&64级电流调整&过温警示驱动ICDM1638x3信道4096级PWM驱动ICDM6214×3装饰照明专用PWM输出驱动恒流ICDM63112比特内置PWM+实时检测恒流驱动ICDM63216比特内置PWM+实时检测恒流驱动ICDM1638×3通道4096级PWM输出恒流驱动ICDM1648×3通道4096级PWM输出恒流驱动ICDD211二倍升压驱动IC 2-3.3V 最大升压100mA固定式恒流ICDD2313信道驱动IC 5-30mA 可设置小体上电即亮型ICDD2334信道驱动IC 5-30mA 可设置小体、可开关型ICDD2121.5-5.5V二倍升压最大400mA电流输出驱动单颗LED恒流ICPC112,PC1132.8-5V四倍升压驱动20mA小功率多颗LED恒流ICST2225A35输出信道之数字/字母LED驱动芯片Addtek (广鹏科技)A701、A702固定式5-30mA灯饰恒流A703120mA可开式6-50V降压型恒流ICA705220mA、2.7-12V固定降压型单路恒流ICA7065-40mA、5-50V/PWM多路可开关型恒流ICAMC711x固定式小电流灯饰应用AMC711x_E固定式小电流灯饰应用AMC71352-6V低压差固定式恒流驱动IC1颗LEDAMC71405-50V DC&DC 最大500mA电流可调,1颗或多颗LED驱动ICAMC71505-24V DC&DC 最大1.5A固定式,1-3颗LED驱动ICAMC7169LED保护ICMBI (台湾聚积科技) MBI18011路恒流驱动1.2A电流可设定PWM信号灰度调节MBI18022路恒流驱动360mA电流可两路单独设定PWM信号灰度调节MBI18044路恒流驱动240mA电流可设定PWM信号灰度调节MBI181616路恒流驱动电流可设定PWM信号灰度调节MBI5024面对低端客户16位LED屏幕、护栏灯管恒流驱动ICMBI502516位最大45mALED屏幕、护栏灯管恒流驱动ICMBI502616位最大90mA LED屏幕、护栏灯管恒流驱动ICMBI502816位最大90mA LED屏幕、护栏灯管恒流驱动IC,具电流增益功能MBI503016位内置PWM高灰阶LED恒流驱动ICMBI503116位内置PWM高灰阶LED恒流驱动IC,相对5030低端客户MBI5039MBI51688位LED屏幕、护栏灯管恒流驱动ICMBI60103位级联式LED灯饰屏幕,R/G/B单独电流可设置恒流驱动IC StarChips (晶錡科技) SCT202416位移位LED恒流驱动,适合目前LED大屏幕使用3-40mASCT202616位移位LED恒流驱动,适合目前LED大屏幕使用3-90mASCT221016位移位LED恒流驱动,适合LED大屏幕及插件护栏管使用3-120mASCT21108位移位LED恒流驱动IC,主要用于灯饰产品SCT251212位移位护栏管专用IC,3路OE灰度可以单独调节SCT20073路点光源驱动IC,可兼容MIB6010Shamrock (台湾芯瑞)SMD7333-40V电压输入,内置MOS管降压型驱动电流1ASMD7353-40V电压输入,降压型驱动电流700mA(可替代AMC7150)SMD736最高40V电压输入,内置MOS管降压型驱动电流3ASMD802市电直驱1A LED驱动IC(可替代HV9910)SMD911市电直驱IC,外置MOS LED隔离方案驱动ICSMD912市电隔离型直驱IC,外置MOS LED驱动ICOB (台湾昂宝) OB656380W PFC Module 400V 0.2ATM PFCOB6573300W PFC Module 400V 0.75A CCM PFCOB6561P36W LED Driver 24V 1.5ATM PFCTAC (台湾台创) TAC7135TAC7136TAC9920TAC5240TAC5241深圳市泉芯电子QX2706 背光恒流驱动2.7V~5.5V <=30V <=200mA <=85% SOT23-6QX2705 背光恒流驱动2.7V~5.5V <=30V <=200mA <=87% SOT23-5QX2703 背光恒流驱动2.7V~5.5V <=30V <=200mA <=87% SOT23-5QX7136 矿灯/手电筒驱动2.7V~6V- <=3A - SOT89-5QX7135 矿灯/手电筒驱动2.7V~6V- <=400mA - SOT-89-3 TO-252-2QX5234 三通道恒流驱动5.5V~17V <=17V <=200mA - SOP16 SSOP16 TSSOP16QX5238/9 背光恒流驱动2.7V~6V 2.7V~6V 15mA/20mA <=90% SOT23-6 MSOP-8QX2305 LED日光灯恒流驱动2V~400V - - <=90% SOP-8QX9910 LED日光灯恒流驱动2.5V~400V 2.5V~400V <=1A <=90% SOP-8QX5232B 太阳能草坪灯驱动1.2V~4V 1.2V~4V <=120mA <=90% DIP-8QX5251 太阳能草坪灯驱动0.9V~1.5V - <=300mA <=92% TO-94QX62726 LED显示屏恒流驱动4V~5.5V <=10V <=90mA - SSOP24-300-1.00 SSOP24-150-0.635QX5241 大功率低压恒流驱动5.5V~36V 5.5V~36V <=2A <=95% SOT23-6杭州士兰微电子SB1672616位恒流驱动全彩屏幕ICSC16722可级连、大电流输出的专用LED驱动电路SB42351350mA低压差白光固定式LED驱动芯片SB42510PWM控制、1A白光LED恒流芯片SA7525PFC功率因素控制技领半导体上海有限公司ACT34US-T SOT23-6 65kHz 7W 0.3WProduction ACT351HQ-T SIP-4 Adjustable 2W < 0.3WSampling ACT353HQ-T SIP-4 Adjustable 3W < 0.3WSampling ACT355HQ-T SIP-4 Adjustable 3.5W < 0.3WSampling ACT50UC-T SOT23-5 65kHz 18W 0.3WProduction ACT50DH DIP-8 65kHz 30W 0.3WProduction华润矽威科技(上海) PT4107通用18V~450V市电输入,高亮度LED驱动器.PT411530V/1.2A,高调光比LED恒流驱动器深圳市明微电子有限公司SM16130 LED驱动控制电路SM16128 LED驱动控制电路SM16126C 16位恒流LED驱动器SM16126B 16位恒流LED驱动器SM74HC595 LED显示驱动专用集成电路SM8061 高效节能功率因子校正芯片。