IC-Hersteller (103)
- Alle Hersteller
Analog Devices
Infineon Technologies
Microchip
Onsemi
Renesas
ROHM
STMicroelectronics
Texas Instruments
- 3peak incorporated (28)
- Ablic (23)
- Acco Semiconductor (1)
- Advanced Power (4)
- Allegro Microsystems (100)
- Alpha & Omega Semiconductor (37)
- AnalogySemi (3)
- AnDAPT Inc (204)
- Anpec (13)
- AXElite (2)
- Backward (6)
- Bright Power Semiconductor (1)
- Broadcom (46)
- Cambridge GaN Devices (18)
- Chipanalog Micro (10)
- Cologne Chips (1)
- Convenient Power (1)
- Dialog Semiconductor (12)
- Diodes Incorporated (259)
- Divimath (8)
- Elmos AG (1)
- EPC (136)
- e-Peas Semiconductors (1)
- Eta Solutions Co. Ltd. (9)
- GaN Systems (8)
- GaNPower (3)
- Giantec (1)
- Gstek Wuxi (1)
- Helix Semiconductor (7)
- IKON (1)
- Indie Semiconductor (8)
- Innovision Semiconductor Inc (2)
- Intel (68)
- Inventchip Technology (3)
- ISSI (51)
- JoulWatt (20)
- KDPOF (3)
- Kinetic Technology (8)
- Lattice semiconductor Corporation (38)
- Littelfuse (1)
- Lumissil Microsystems (8)
- M3 Technology (M3Tek) (7)
- Macnica (22)
- Marvell Semiconductor (1)
- MaxLinear (181)
- Menlo Micro (1)
- MikroE (25)
- MindCet (2)
- Monolithic Power Systems (980)
- Navitas Semiconductor Inc (6)
- NewEdge Technologies, Inc. (1)
- Nexperia (266)
- Nisshinbo Micro Device Inc. (10)
- Novosense Micro (1)
- NXP (333)
- O2 Micro International Ltd (10)
- On Bright (7)
- Panasonic (2)
- PN Junction Semiconductor (2)
- Power Integrations (117)
- Powermat (1)
- Pulsiv (19)
- Qorvo (96)
- Realsil SuRealsil(tek) Microelectronics (1)
- Richtek (297)
- Sanken Electric Co., Ltd. (16)
- Sckipio (6)
- Semtech (86)
- SG-Micro (54)
- SiFive (2)
- Silanna Semiconductor (9)
- Silergy Corporation (33)
- Silicon Laboratory Inc. (108)
- Silicontent Technology (59)
- Silvertel (59)
- Skycore Semiconductors (1)
- Skyworks (33)
- Southchip (14)
- Summit Wireless (1)
- Tagore Tech (7)
- Taiwan Semiconductor (1)
- TDK Corporation (1)
- Tempo Semiconductor (1)
- Torex (37)
- Toshiba (25)
- Transphorm (21)
- TransSIP (2)
- Union (21)
- uPI Semiconductor (2)
- Valens Semiconductor (31)
- Wise Integration (3)
- Wolfspeed (23)
- Xilinx (22)
- XL Semiconductor (3)
- XYSemi (62)
STMicroelectronics IPS4260LM | Demoboard X-NUCLEO-OUT07A1
Industrial digital output expansion board based on IPS4260LM for STM32 Nucleo
Details
| Topologie | Sonstige Topologie |
| Eingangsspannung | 8-50 V |
| IC-Revision | 1 |
Beschreibung
The X-NUCLEO-OUT07A1 industrial digital output expansion board for STM32 Nucleo provides a powerful and flexible environment for the evaluation of the driving and diagnostic capabilities of the IPS4260LM quad low-side smart power solid state relay, in a digital output module connected to 0.5 A industrial loads.Dual channels and single channel configurations are possible by proper setting of J9 and J10 (see below).The X-NUCLEO-OUT07A1 interfaces with the microcontroller on the STM32 Nucleo via STISO620 and STISO621 and Arduino®R3 connectors. The expansion board can be connected to either a NUCLEO-F401RE or a NUCLEO-G431RB development board.The digital isolators STISO620 and STISO621 (featuring 2.8k VRMS galvanic isolation) and the isolated dc-dc DC1 (featuring 3kVDC isolation) protects the logic side from the typical harsh environment on the process side.The logic side is the application side of the MCU and it is supplied by the VISO_L rail (3.3 or 5.0 V). When the X-NUCLEO-OUT07A1 is stacked on a NUCLEO-F401RE, or on a NUCLEO-G431RB, the VISO_L is supplied by the Nucleo board if connected to a PC/Laptop by USB cable. If the X-NUCLEO-OUT07A1 is used standalone, then VISO_L can be supplied by the CN6[4] (SW1 = close 1-2) or CN6[5] (SW1 = close 2-3).The process side is the application side beyond the galvanic isolation barrier. On the process side there are two supply rails: the 5V_P rail (5.0 V) and one rail between the 10V_P (SW7 close 1-2) and the V_FIELD_RP rail (SW7 close 2-3).Both the 5V_P and the 10V_P rails are generated by the DC1, while the V_FIELD_RP rail is supplied externally.The 5V_P rail supplies both the digital isolators and the red diagnostic LEDs D7 (open load detection) and D8 (overload and overtemperature diagnostic).The 10V_P rail supplies the IPS4260LM (U1): the loads are connected between the CN2[1, 2] and CN3[1, 2] connectors and the process side supply rail (typically 24 V). The reference rail (ground) of the power process side supply rail must be connected to CN1[2], too.Alternatively (SW7 close 2-3) the V_FILED_RP rail supplies U1: the loads are connected between the CN2[1, 2] and CN3[1, 2] connectors and the process side supply rail (typically 24 V). The positive pole and the ground of the power process side supply rail must be connected to CN1[1] and CN1[2], respectively.The SW8 allows the selection of which external TVS is used for the demagnetization of the inductive load and for sustaining the surge pulse on the output stage. Setting SW8 close to 1-2 the D9 is selected: this selection is valid both if U1 is supplied by the 10V_P or by the V_FIELD_RP rail. Setting SW8 close to 2-3 the D10 is selected: this selection is valid only when U1 is supplied by the V_FIELD_RP.The four low side power switches integrated in U1 can be activated/deactivated by the control signals IN1_L, IN2_L, IN3_L and IN4_L: by default, these signals are controlled by CN5[2,1] and CN9[8,7] through SW2[1-2], SW3[1-2], SW4[1-2] (IN4_L goes through direct connection to U6). .The four on board green LEDS D1, D2, D3, and D4 can be enabled by closing J6[1-2, 3-4, 5-6, 7-8]: these are driven ON/OFF according to the status (active/inactive) of the respective low side power switch (OUT1, OUT2, OUT3, OUT4) integrated in the U1.The user can enable/disable the cutoff featured by U1 by J8[7-8]: open (cutoff active) or closing (cutoff disabled).Also, J8[1-2, 3-4, 5-6] allows the user can set the desired current limitation level (J8[1-2] ==> 0.5A; J8[3-4] ==> 1A; J8[5-6] ==> 2A). The J9 and J10 allow the user to easily parallelize the input and output channels and achieve dual channel low side (J9[1-2, 5-6] and J10[1-2, 5-6]) or single channel low side (J9[1-2, 3-4, 5-6] and J10[1-2, 3-4, 5-6]).The open load detection feature offered by U1 is enabled only when the J7[1-2, 3-4, 5-6, 7-8] are closed. Note that the signalization of D7 must be ignored when J7 is open.The two cumulative diagnostic signals FLT_L (overload and overtemperature) and OL_L (open load) are available on the CN9[6] (SW6[1-2]) and on CN9[5], respectively.The four per-channel overload diagnostic signals DIAG1_L, DIAG2_L, DIAG3_L, DIAG4_L are available on the CN5[10] (SW5[1-2]), CN5[9], CN8[6] and CN8[5], respectively.It is also possible to evaluate a system composed of a X-NUCLEO-OUT07A1 stacked on other expansion boards.
Typische Anwendungen
- Industrial digital output
Weiterführende Informationen
Artikeldaten
Artikel Nr. | Datenblatt | Simulation | Downloads | Status | Produktserie | Pins | PCB/Kabel/Panel | Modularity | Typ | Wire Section | λDom typ.(nm) | Farbe | λPeak typ.(nm) | IV typ.(mcd) | VF typ.(V) | Chiptechnologie | 2θ50% typ.(°) | C | Tol. C | VR(V (DC)) | Bauform | Betriebstemperatur | Q(%) | DF(%) | RISO | Keramiktyp | L(mm) | B(mm) | H(mm) | Fl(mm) | Verpackung | L(µH) | IRP,40K(A) | RDC max.(mΩ) | fres(MHz) | Montageart | Endurance(h) | IRIPPLE(mA) | ILeak(µA) | Raster(mm) | Ø D(mm) | IR(A) | Arbeitsspannung(V (AC)) | Farbe | Gender | Muster | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
 | WR-PHD Kurzschlussbrücken, 1, – | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWR-PHD Kurzschlussbrücken | Pins1 | – | – | – | – | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +125 °C | – | – | Isolationswiderstand1000 MΩ | – | Länge2.44 mm | – | – | – | VerpackungBeutel | – | – | – | – | – | – | – | – | Raster2.54 mm | – | Nennstrom3 A | Arbeitsspannung250 V (AC) | FarbeSchwarz | GenderJumper | |||
 | WR-TBL Series 2141 - 3.50 mm Horiz. Entry Modular, 2, Käfigzugklemme | Simulation– | Downloads6 Dateien | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | Pins2 | PCB/Kabel/PanelPCB | ModularityJa | TypHorizontal | Wire Section 24 to 16 (AWG) 0.2 to 1 (mm²) | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +105 °C | – | – | – | – | Länge7.05 mm | – | – | – | VerpackungKarton | – | – | – | – | MontageartTHT | – | – | – | Raster3.5 mm | – | Nennstrom10 A | Arbeitsspannung300 V (AC) | – | – | |||
 | WR-PHD Stiftleisten - Einreihig, 2, – | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWR-PHD Stiftleisten - Einreihig | Pins2 | – | – | TypGerade | – | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +105 °C | – | – | Isolationswiderstand1000 MΩ | – | Länge5.08 mm | – | – | – | VerpackungBeutel | – | – | – | – | MontageartTHT | – | – | – | Raster2.54 mm | – | Nennstrom3 A | Arbeitsspannung250 V (AC) | – | GenderStiftleiste | |||
 | WR-PHD Stiftleisten - Einreihig, 3, – | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWR-PHD Stiftleisten - Einreihig | Pins3 | – | – | TypGerade | – | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +105 °C | – | – | Isolationswiderstand1000 MΩ | – | Länge7.62 mm | – | – | – | VerpackungBeutel | – | – | – | – | MontageartTHT | – | – | – | Raster2.54 mm | – | Nennstrom3 A | Arbeitsspannung250 V (AC) | – | GenderStiftleiste | |||
 | WR-PHD Stiftleisten - Zweireihig, 6, – | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWR-PHD Stiftleisten - Zweireihig | Pins6 | – | – | TypGerade | – | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +105 °C | – | – | Isolationswiderstand1000 MΩ | – | Länge7.62 mm | – | – | – | VerpackungBeutel | – | – | – | – | MontageartTHT | – | – | – | Raster2.54 mm | – | Nennstrom3 A | Arbeitsspannung250 V (AC) | – | GenderStiftleiste | |||
 | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWR-PHD Stiftleisten - Zweireihig | Pins8 | – | – | TypGerade | – | – | – | – | – | – | – | – | – | – | – | – | Betriebstemperatur -40 °C up to +105 °C | – | – | Isolationswiderstand1000 MΩ | – | Länge10.16 mm | – | – | – | VerpackungBeutel | – | – | – | – | MontageartTHT | – | – | – | Raster2.54 mm | – | Nennstrom3 A | Arbeitsspannung250 V (AC) | – | GenderStiftleiste | ||||
 | WE-GF SMT-Induktivität, –, – | Simulation– | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWE-GF SMT-Induktivität | – | – | – | – | – | – | – | – | – | – | – | – | – | – | – | Bauform3225 | Betriebstemperatur -40 °C up to +105 °C | Güte30 % | – | – | – | Länge3.2 mm | Breite2.5 mm | Höhe2.2 mm | – | – | Induktivität6.8 µH | Performance Nennstrom0.55 A | Gleichstromwiderstand1800 mΩ | Eigenresonanzfrequenz38 MHz | MontageartSMT | – | – | – | – | – | Nennstrom0.18 A | – | – | – | |||
 | WL-SMCW SMT Mono-color Chip LED Waterclear, –, – | Downloads26 Dateien Strahldaten
| Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWL-SMCW SMT Mono-color Chip LED Waterclear | – | – | – | – | – | dominante Wellenlänge [typ.]625 nm | FarbeRot | Spitzen-Wellenlänge [typ.]630 nm | Lichtstärke [typ.]250 mcd | Durchlassspannung [typ.]2 V | ChiptechnologieAlInGaP | Abstrahlwinkel Phi 0° [typ.]140 ° | – | – | – | Bauform0603 | Betriebstemperatur -40 °C up to +85 °C | – | – | – | – | Länge1.6 mm | Breite0.8 mm | Höhe0.7 mm | – | VerpackungTape and Reel | – | – | – | – | MontageartSMT | – | – | – | – | – | – | – | – | – | |||
| WL-SMCW SMT Mono-color Chip LED Waterclear, –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWL-SMCW SMT Mono-color Chip LED Waterclear | – | – | – | – | – | dominante Wellenlänge [typ.]570 nm | FarbeHellgrün | Spitzen-Wellenlänge [typ.]572 nm | Lichtstärke [typ.]40 mcd | Durchlassspannung [typ.]2 V | ChiptechnologieAlInGaP | Abstrahlwinkel Phi 0° [typ.]140 ° | – | – | – | Bauform0603 | Betriebstemperatur -40 °C up to +85 °C | – | – | – | – | Länge1.6 mm | Breite0.8 mm | Höhe0.7 mm | – | VerpackungTape and Reel | – | – | – | – | MontageartSMT | – | – | – | – | – | – | – | – | – | ||||
 | WCAP-ATUL Aluminium-Elektrolytkondensatoren, –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-ATUL Aluminium-Elektrolytkondensatoren | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität47 µF | Kapazität±20% | Nennspannung100 V (DC) | – | – | – | Verlustfaktor9 % | – | – | Länge12.5 mm | – | – | – | VerpackungAmmopack | – | – | – | – | – | Endurance 7000 | Rippelstrom400 mA | Leckstrom47 µA | Raster5 mm | Durchmesser10 mm | – | – | – | – | ||||
| WCAP-CSGP MLCCs 50 V(DC), –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-CSGP MLCCs 50 V(DC) | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität1 pF | Kapazität±0.5pF | Nennspannung50 V (DC) | Bauform0603 | Betriebstemperatur -55 °C up to +125 °C | Güte420 % | – | Isolationswiderstand10 GΩ | KeramiktypNP0 Klasse I | Länge1.6 mm | Breite0.8 mm | Höhe0.8 mm | Pad Dimension0.4 mm | Verpackung7" Tape & Reel | – | – | – | – | – | – | – | – | – | – | – | – | – | – | |||||
| WCAP-CSGP MLCCs 16 V(DC), –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-CSGP MLCCs 16 V(DC) | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität100 nF | Kapazität±10% | Nennspannung16 V (DC) | Bauform0603 | Betriebstemperatur -55 °C up to +125 °C | – | Verlustfaktor3.5 % | Isolationswiderstand5 GΩ | KeramiktypX7R Klasse II | Länge1.6 mm | Breite0.8 mm | Höhe0.8 mm | Pad Dimension0.4 mm | Verpackung7" Tape & Reel | – | – | – | – | – | – | – | – | – | – | – | – | – | – | |||||
| WCAP-CSGP MLCCs 10 V(DC), –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-CSGP MLCCs 10 V(DC) | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität4.7 µF | Kapazität±10% | Nennspannung10 V (DC) | Bauform0805 | Betriebstemperatur -55 °C up to +125 °C | – | Verlustfaktor10 % | Isolationswiderstand0.02 GΩ | KeramiktypX7R Klasse II | Länge2 mm | Breite1.25 mm | Höhe1.25 mm | Pad Dimension0.5 mm | Verpackung7" Tape & Reel | – | – | – | – | – | – | – | – | – | – | – | – | – | – | |||||
| WCAP-CSGP MLCCs 100 V(DC), –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-CSGP MLCCs 100 V(DC) | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität100 nF | Kapazität±10% | Nennspannung100 V (DC) | Bauform0805 | Betriebstemperatur -55 °C up to +125 °C | – | Verlustfaktor2.5 % | Isolationswiderstand1 GΩ | KeramiktypX7R Klasse II | Länge2 mm | Breite1.25 mm | Höhe1.25 mm | Pad Dimension0.5 mm | Verpackung7" Tape & Reel | – | – | – | – | – | – | – | – | – | – | – | – | – | – | |||||
| WCAP-CSGP MLCCs 100 V(DC), –, – | Status Aktivi| Produktion ist aktiv. Erwartete Lebenszeit: >10 Jahre. | ProduktserieWCAP-CSGP MLCCs 100 V(DC) | – | – | – | – | – | – | – | – | – | – | – | – | Kapazität2.2 µF | Kapazität±10% | Nennspannung100 V (DC) | Bauform1210 | Betriebstemperatur -55 °C up to +125 °C | – | Verlustfaktor5 % | Isolationswiderstand0.05 GΩ | KeramiktypX7R Klasse II | Länge3.2 mm | Breite2.5 mm | Höhe2.5 mm | Pad Dimension0.75 mm | Verpackung7" Tape & Reel | – | – | – | – | – | – | – | – | – | – | – | – | – | – |