ALi M3901C规格书

AS3901ISM 433/315 MHz FSK/ASK Transmitter Data SheetRev. 06, August 2000Key Features•Supports the European 433 MHz ISM band.•No frequency pulling by (antenna) load variation due to PLL synthesizer.•Designed to be conform to EN 300 220-1 requirements.•Supports FSK (data rates 0…32 kb/s) or ASK modulation (data rates 0…20kb/s)•No data synchronization for FSK or ASK needed.•Supports clock and reset signals for the external µC.•Supports different power down modes, one without any running XTAL oscillator.•Wide supply range between 2.7 V to 5 V.•Only one XTAL and very few external elements required.•Wide operating temperature range from –40 C to +85 C.•Low TX current, typical 7 mA.General DescriptionThe AS3901 is a low power FSK/ (ASK) transmitter intended for the European 433 MHz and the US 315 MHz ISM band application. It uses a PLL stabilized oscillator whichavoids frequency pulling by approaching the antenna with objects as it occurs at SAW resonator based transmitters.FSK modulation is performed by an I/Q-based continuous phase FSK modulator with a well defined frequency deviation of 16 kHz. The FSK modulator is operating completely asynchronous to the TX data stream and therefore needs no data clock or other possible by switching the driving amplifier and FSK modulator on and off by an applied transmit data stream.The µC clock frequency and the FSK frequency deviation can be kept almost constant for both frequency bands by selecting the correct scaling factors by the 433/315 pin. As external components the AS3901 needs only a reference XTAL and 5 capacitors.Applications•Short range radio data transmission.•Remote keyless entry systems.•Security applications and alarm systems.•Domestic and consumer remote control units.•Remote metering.•Low power telemetry.This document contains information on products under development. Austria Mikro Systeme International AG reserves the right to change or discontinue this product without notice.1F u n c t i o n a l D e s c r i p t i o nThe AS3901 consists of a reference XTAL oscillator, a single channel RF- synthesizer, an I/Q based asynchronous continuos phase FSK modulator, a driving amplifier and a µC interface, including µC clock divider, and a power management circuitry.Figure 1: Block diagram of the AS3901.1.1RF SynthesizerThe RF synthesizer is a fully integrated single channel device with internal loop filter,generating the 433 MHz or 315 MHz transmit carrier frequency f RF by a fix, 32 times,multiplication of the reference XTAL frequency f XTAL.1.2Microprocessor ClockThe microprocesor clock frequency f CLK is generated by dividing the XTAL frequency f XTAL by 3 or 4, dependent on the 433/315 MHz selection pin to keep the µC clock frequencyf CLK almost constant for European and US applications.1.3ModulationThe FSK modulator is an I/Q modulator based continuos phase FSK modulator. Themodulating NRZ data may be in the range of 0 up to 32 kbit/s. The FSK frequencydeviation ∆f is ≈16 kHz, independent of the data rate. It is also kept almost constant for both transmit frequency bands by selecting proper frequency deviation multiplicationfactors of the XTAL reference frequency by the 433/315 MHz selection pin.The processing clock of the data source can be different from the AS3901 referenceXTAL or µC clock f CLK and no data synchronization of the FSK modulator is required.1.4Driving AmplifierThe driving amplifier has a differential open collector output optimized for driving ofsmall, symmetrical high-impedance loop antennas. The amplifier drives a nominal RFcurrent of 0.7 mA rms.The maximal differential voltage swing is about 4 V PP. Therefore the output power ist a function of the connected load impedance. With a 2 kΩ differentialload a nominal peak output power (to the antenna) of ≈1 mW is obtained. Please notethat the finally radiated power (from antenna) is lower and strongly dependent on theefficiency (function of the size) of the antenna to be used.1.5ASK ModulationASK modulation with a date rate upt to 20 kbits/s can be achieved by turning the driving amplifier and the FSK modulator by the TX/ASK pin on and off, where a TX/ASK = …H“means a turned on state.1.6Power Management and Operation ModesFor normal operation the switching between different operation modes follows a Grey-coded scheme to avoid unwanted switching between operation modes due to inaccurate occurrence of edges of STDBY and TX/ASK.Mode STDBY TX/ASK FunctionStandby11All OffClock generator operation10XTAL oscillator on and CLOCK outputactive.Transmit operation01XTAL oscillator, PLL, FSK modulatorrunning, (FSK operation or …H“transmittedat ASK).Turned off power00XTAL oscillator and PLL running, outputamplifier and FSK modulator off, (…L“transmitted at ASK).1.7µC Interface and TimingThe AS3901 contains a direct interface to a microcontroller (µC). The µC interface of the AS3901 consists of three input and two outputs pins:…Standby input“(STDBY).…Transmit / ASK input“(TX/ASK).…µC reset output (Active …L“)“(NRES).…µC clock output“(CLK).…FSK data input“(DATA).These lines support the µC with the required reset, clock and data signals. Lines 1 to 4 control the AS3901 internal power on/off circuit which wakes up and shuts down thewhole transmitter consisting of the AS3901 and the µC.Figure 2 shows a typical interconnection of the AS3901 with a typical µC. Figure 3presents a related timing for power up and down of the transmitter.AS3901STDBY DATA TX/ASK RESET NRES TX/ASK uCswitchSTDBY DATA CLKCLKFigure 2:Interconnection of the AS3901 with a typical µC.Note:At room temperature, resistor values of ≈10 k Ω are suggested for the µC interface.For other temperatures to be calculated from figure 5.TX/ASK CLK NRES STDBYFigure 3: µC interface timing for a transmission cycle.Note:Activating the transmit switch results in a …weak L state“ at TX/ASK. It can be overridden by the microcontroller so that the transmission cycle remains unaffected by the duration the switch is pressed. The STDBY and TX/ASK inputs have internal pullup resistors of ~100k Ω1.7.1Interface DescriptionWake-up sequence:TX/ASK=H, STDBY=H: Standby. All off low current state.TX/ASK→L, STDBY=H; → XTAL oscillator starts up. NRES goes L, resetting (starting) the µC for tXTON plus 3 clock cycles.NRES returns to H, µC initializes.After µC is initialized, it sets STDBY→L; PLL is turned on, after t PLLon a stable RF carrier is generated.TX/ASK→H, STDBY=L; →TX is turned on, t TXON later the RF signal is available and data can be transmitted.To switch the AS3901 …on“a …push button“with series resistance ~10-20 kΩ can beused to make TX/ASK = …L“. The …push-button“must be pushed long enough (typ. >3ms) for the µC to reset and sustain the TX/ASK …L“state.Standby procedure (for sleep-mode ( IDD1 <1µA):The µC outputs a …H“to TX/ASK and STDBY. After minimal 3 CLK cycles the XTALoscillator will be switched off. The pull-up resistors at the AS3901 TX/ASK and STDBY inputs will sustain the sleep mode.Note: Multiple …push buttons“for different functions can be used.2Electrical C h a r a c t e r i s t i c s2.1Absolute Maximum Ratings (non operating)Symbol Parameter Min Max Units Note VDD Positive supply voltage-0.57VGND Negative supply voltage00VV IN Voltage on input pins-0.5VDD+0.5VESD Electrostatic discharge1000V1) T STG Storage temperature-55125°CT LEAD Lead temperature260°C2) Note:1) HBM: R = 1.5 kΩ, C = 100 pF. The pins ANT1, ANT2, XTAL1 and XTAL2 have 500 V ESD protection.2) 260°C for 10 s (reflow and wave soldering), 360 °C for 3 s (manual soldering).2.2Operating ConditionsSymbol Parameter Min Typ Max Unit Note VDD Positive supply voltage 2.7 3.0 5.0VGND Negative supply voltage000V1µA1) IDD1Supply current,STDBY = ”H”, TX/ASK = ”H”IDD2Supply current,350850µA2) STDBY = ”H”, TX/ASK = ”L”79mA3) IDD3Supply current,STDBY = ”L”, TX/ASK = ”H”3.54.5mA4) IDD4Supply current,STDBY = ”L”, TX/ASK = ”L”T AMB Ambient temperature range-40+85°CNote:1) Standby:T AMB = 23 °C, Synthesizer and driving amplifier are turned off.2) Clock generator operation:T AMB = 23 °C XTAL oscillator and µC clock divider on. RF driving amplifier and PLL off, noexternal load connected to CLK pin.3)Transmit operation:T AMB = 23 °C, Synthesizer and driving amplifier are turned on.4)Turned off TX power:T AMB = 23 °C, XTAL oscillator and µC clock divider and PLL on RF driving amplifier off.2.3Transmit OperationT AMB = 23 °C, VDD = 3.0 V, unless specified otherwise.Symbol Parameter Conditions Min Typ Max Units Note f RF, EU Transmit frequency (Europe)f XTAL = 13.560 MHz433.920MHz1) f RF, US Transmit frequency (US)f XTAL = 9.84375 MHz315.000MHz1) f offset Frequency tolerance After t TXON, no XTALtolerance.2kHzf CLK, EUµC clock frequency (Europe)f XTAL = 13.560 MHz 3.390MHzf CLK, USµC clock frequency (US)f XTAL = 9.84375 MHz 3.28125MHzt TXon Transmitter turn on time FSK modulator anddriver amplifier20µst PLLon PLL turn on time t.b.d.msT XTon XTAL oscillator turn on time5msNote:1) XTAL tolerances will slightly change the typical transmit frequency.2.3.1 ASK OperationT AMB = 23 °C, VDD = 3.0 V, unless specified otherwise.Symbol Parameter Conditions Min Typ Max Units NoteP OUT,H Available peak outputpower In 2 kΩ, STDBY = ”L”,TX/ASK = ”H”-1.50 1.5dB m1) 3)P OUT,L Leakage peak outputpower In 2 kΩ, STDBY = ”L”,TX/ASK = ”L”-50dB mP OUT 3rd Radiated third harmonicoutput power Antenna attenuation>20 dB-39dB m2)P SP Spurious power In distance of f CLK orf XTAL from carrier. Noantenna selectivityassumed.-45-25dB C2) 3)R ASK ASK data rate range For a RF packet dutycycle ≥25 %.020Kb/sNote:1) Output power depends on load impedance, differential output current is typical 0.7 mA rms. Maximum differential voltage swingis typical 4 V PP.2) Measurement bandwidth (close to EN 300 220-1) see also figure 10.3) Actual E.R.P. depends on antenna efficiency2.3.2 FSK OperationT AMB = 23 °C, VDD = 3.0 V, unless specified otherwise.Symbol Parameter Conditions Min Typ Max Units NoteP OUT,FSK Available peak outputpower In 2 kΩ, STDBY = ”L”,TX/ASK = ”H”-1.50 1.5dB m1) 3)P OUT 3rd Radiated third harmonicoutput power Antenna and band passfilter attenuation> 20 dB-36dB m2)P SP Spurious power In distance of f CLK orf XTAL from carrier. Noantenna selectivityassumed.-45-25dB C2) 3)R FSK FSK data rate range032kb/s4)∆f FSK frequency deviation16kHzNote:1) Output power depends on load impedance, differential output current is typical 0.7 mA ms. Maximum differential voltageswing is typical 4 V PP.2) Measurement bandwidth (close to EN 300 220-1) see also figure 10.3) Actual E.R.P. depends on antenna efficiency4) Guaranteed by design2.4Digital Pin CharacteristicsT AMB = 23 °C, VDD = 3.0 V, unless specified otherwise. GND is the 0 V reference.Symbol Parameter Conditions Min Typ Max Units Note CLK (µC clock output)VOH High level output voltage IOH = -1 mA VDD-0.7-VDD VVOL Low level output voltage IOL = 1 mA GND- 1.2Vtr Rise time CLoad = 10 pF20nstd Fall time CLoad = 10 pF20nsjcc Cycle to cycle jitter+/-5%1) NRES (Inverted reset output)VOH High level output voltage IOH = -1 mA VDD-0.3-VDD VVOL Low level output voltage IOL = 1 mA GND-0.2Vtr Rise time CLoad = 10 pF20nstd Fall time CLoad = 10 pF20nsTX/ASK (Driving amplifier and FSK modulator on/off (ASK) input)VIH High level input voltage VDD-0.5-VDD VVIL Low level input voltage GND-0.3VIIH High level input current VIH = VDD1-40µA IIL Low level input current VIL = 0 V.internal pull-upDATA (FSK data input)VIH High level input voltage VDD-0.5-VDD VVIL Low level input voltage GND-0.3VIIH High level input current VIH = VDD1µAIIL Low level input current VIL = 0 V-1µA433/315 (Band selection (division ratio))VIH High level input voltage VDD-0.5-VDD V VIL Low level input voltage GND-0.3V IIH High level input current VIH = VDD1µA IIL Low level input current VIL = 0 V.-1µA STANDBY (Standby input)VIH High level input voltage VDD-0.5VDD V VIL Low level input voltage GND-0.3V IIH High level input current VIH = VDD1µA-40µA 1IIL Low level input current VIL = 0 V.internal pull-upNotes1) Guaranteed by design3P i n-o u t I n f o r m a t i o nPin #Pin Name Input / Output Description1STDBY Dig. Input, 100 kΩ pull up Power down for all functions 2CLK Dig. Output Clock output (CMOS level)3DATA Dig. Input Transmit data input (CMOS level)4TX/ASKon/off ASK Dig. Input, 100 kΩ pull up Power off for TX (PLL and XTAL working)ASK modulation5GND Power Ground6VDD Power Positive supply (2.7 V-5.0 V)7XTAL2Analog XTAL pin28XTAL1Analog XTAL pin19433/315Dig. Input Selects division factors for constant µCClock frequency and deviation10VDDRF Power Positive supply (2.7 V-5.0 V)11ANT2Analog open collector output To loop antenna12ANT1Analog open collector output To loop antenna13GNDRF Power Ground14NRESET Dig. Output Reset, …L“state resets a microcontroller4A p p l i c a t i o n S c h e m a t i c3PC5Figure 4:Basic application schematic of the AS3901.Figure 5:Pull Up characteristics for the TX/ASK pin.5Typical MeasurementsFigure 6:Narrow band output spectrum of the AS3901 FSK modulated with pseudoclose to the EN 300-220-1 recommendation for wide-band equipment, clause 8.6.Instead of 5 kHz video bandwidth (VBW) 10 kHz was used. The markers were setup to the band edges. (433.050 MHz, 434.790 MHz) The recommendation saysthat the spectrum should be observed at least 1MHz form the ISM band edges, butit was measured with larger frequency span.Figure 8:Modulation bandwidth of the AS3901 in AKS operation at 9.2 kbit/s, measured close to the EN 300-220-1 recommendatio for wide-band equipment, clause 8.6.Instead of 5 kHz video bandwidth (VBW) 10 kHz was used. The markers were setup to the band edges. (433.050 MHz, 434.790 MHz) The recommendation saysthat the spectrum should be observed at least 1 MHz from the ISM band edges,Figure 9:1Recommendation for wide-band equipment, clause 8.7, without modulation. (Onlydifference: 100 kHz RBW was used instead of 120 kHz). From the measurement it can beseen that the main critical spurious emission is generated by the 13.56 MHz clock frequency.The level of CLK spurious is near –48 dBM so the suppression is 45 dB for this component.Figure 10:Typical out spectrum in ASK 9.2 kb/s PRN modulation.Figure 11:Transmission power as function of time at ASK modulation with an 9.2 kbit/s 0101.. data pattern.6P a c k a g e I n f o r m a t i o nFigure 12:Physical dimensions of TSSOP-14.Common DimensionsSymbolMinimal (mm)Nominal (mm)Maximal (mm) A-- 1.20A10.05-0.15b0.19-0.30D 4.90- 5.10e0.65 BSCE- 6.40-E1 4.30- 4.50L0.45-0.75α0°-8°Copyright © 2000, Austria Mikro Systeme International AG, Schloß Premstätten, 8141 Unterpremstätten, Austria.Tel.: +43-(0)3136-500-0, Fax: +43-(0)3136-52501, E-Mail: info@All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing by the copyright holder. To the best of its knowledge, Austria Mikro Systeme International asserts that the information contained in this publication is accurate and correct.。

Freescale Semiconductor, Inc. User’s Guide Document Number: KT33901UGRev. 1.0, 2/2014KIT33901EFEVB Evaluation BoardFeaturing the MC33901 High Speed CAN TransceiverFigure 1. KIT33901EFEVB Evaluation BoardContents1 Kit Contents/Packing List. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22 Jump Start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23 Important Notice. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .34 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .45 Evaluation Board Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .46 MC33901 Device Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .47 Required Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .48 Evaluation Board Configuration with Single Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .59 Evaluation Board Configuration with Dual Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .610 Using the EVB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .711 Evaluation Board Hardware Configuration. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .812 Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1013 Board Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1114 Bill of Material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1215 References. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1416 Revision History. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15Kit Contents/Packing List1Kit Contents/Packing List•Assembled and tested evaluation board/module in anti-static bag•Warranty card2Jump Start•Go to /analogtools•Locate your kit•Review your Tool Summary Page•Look forJump Start Your Design•Download documents, software, and other informationImportant Notice3Important NoticeFreescale provides the enclosed product(s) under the following conditions:This evaluation kit is intended for use of ENGINEERING DEVELOPMENT OR EVALUATION PURPOSESONLY. It is provided as a sample IC pre-soldered to a printed circuit board to make it easier to access inputs,outputs, and supply terminals. This evaluation board may be used with any development system or othersource of I/O signals by simply connecting it to the host MCU or computer board via off-the-shelf cables. Thisevaluation board is not a Reference Design and is not intended to represent a final design recommendationfor any particular application. Final device in an application will be heavily dependent on proper printed circuitboard layout and heat sinking design as well as attention to supply filtering, transient suppression, and I/Osignal quality.The goods provided may not be complete in terms of required design, marketing, and or manufacturing relatedprotective considerations, including product safety measures typically found in the end product incorporatingthe goods. Due to the open construction of the product, it is the user's responsibility to take any and allappropriate precautions with regard to electrostatic discharge. In order to minimize risks associated with thecustomers applications, adequate design and operating safeguards must be provided by the customer tominimize inherent or procedural hazards. For any safety concerns, contact Freescale sales and technicalsupport services.Should this evaluation kit not meet the specifications indicated in the kit, it may be returned within 30 days fromthe date of delivery and will be replaced by a new kit.Freescale reserves the right to make changes without further notice to any products herein. Freescale makesno warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nordoes Freescale assume any liability arising out of the application or use of any product or circuit, andspecifically disclaims any and all liability, including without limitation consequential or incidental damages.“Typical” parameters can and do vary in different applications and actual performance may vary over time. Alloperating parameters, including “Typical”, must be validated for each customer application by customer’stechnical experts.Freescale does not convey any license under its patent rights nor the rights of others. Freescale products arenot designed, intended, or authorized for use as components in systems intended for surgical implant into thebody, or other applications intended to support or sustain life, or for any other application in which the failureof the Freescale product could create a situation where personal injury or death may occur.Should the Buyer purchase or use Freescale products for any such unintended or unauthorized application,the Buyer shall indemnify and hold Freescale and its officers, employees, subsidiaries, affiliates, anddistributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arisingout of, directly or indirectly, any claim of personal injury or death associated with such unintended orunauthorized use, even if such claim alleges that Freescale was negligent regarding the design or manufactureof the part. Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All otherproduct or service names are the property of their respective owners.© Freescale Semiconductor, Inc. 2014Introduction4IntroductionThis evaluation board allows the user to implement and test the functionalities of the MC33901, High SpeedCAN transceiver.5Evaluation Board FeaturesThe KIT33901EFEVB Evaluation Board is an easy-to-use circuit board that allows the user to exercise thefunction of the MC33901, High Speed CAN transceiver.•Supply from a single 5.0 V, or dual 5.0 V and 3.3 V supplies•Local switches for single or dual supply selection•Switches for device operating mode selection•Footprint for optional CAN bus filter and protection component•8-pin Single In Line connector to access MC33901 device pins•Two LEDs to display board and MC33901 state6MC33901 Device FeaturesThe MC33901 provides the physical interface between the CAN protocol controller of an MCU and the physicaldual wire CAN bus. They are packaged in an 8-pin SOIC with market standard pin out, and offer excellent EMC and ESD performance without the need for external filter components.•MC33901 is a standalone High Speed CAN transceiver•Available with several options and part numbers, for automotive and industrial applications•Operates with 5.0 V and 3.3 V MCU using VIO input pin•Normal and Low-power modes•Device version with bus wake-up, which reports wake-up on the RXD pin•Integrated TXD dominant protection (MC33901 version)Freescale analog ICs are manufactured using the SMARTMOS process, a combinational BiCMOSmanufacturing flow which integrates precision analog, power functions, and dense CMOS logic on a singlecost-effective die.7Required EquipmentTo use this kit you will need:• 5.0 V power supply, 150 mA capability• 3.3 V power supply, 50 mA capability. Usage of this second supply depends on the user requirement.•Signal generator, output frequency up to 1.0 MHz and output voltage at least 5.0 V•An optional oscilloscope to monitor the CAN signals•Cables with 2.0 mm banana plugsEvaluation Board Configuration with Single Power Supply8Evaluation Board Configuration with Single Power SupplyFigure 2. KIT33901EFEVB Board Setup with Single Power SupplyFigure 3. Output SignalsTXRXCAN HCAN LEvaluation Board Configuration with Dual Power Supply9Evaluation Board Configuration with Dual Power SupplyFigure 4. KIT33901EFEVB Board Setup with Dual Power SupplyUsing the EVB10Using the EVBThe KIT33901EFEVB and the MC33901 device can be used with a single 5.0 V supply, or with dual supplies5.0 V and 3.3 V.10.1Single Supply1.To use the board and device with a single supply, set the VIO SEL switch to left.2.Set the power supply to 5.0 V.3.To use the device in Normal mode, set the STB switch to right.•Connect a 0 - 5.0 V square signal to TX, frequency 250 kHz and duty cycle 50%.•Connect an oscilloscope to CANH, CANL, and RX terminals.•Observe CANH, CANL, and RX signals on the oscilloscope.4.To use the device in Standby mode, set the STB switch to left.•Observe TX signal on the oscilloscope. In Standby mode, TX signal is high.•Apply CAN signal on CANH and CANL.•RX reports bus state (dominant or recessive), once the wake-up filter criteria is met.10.2Dual Supply1.To use the board and device with dual supply, set the VIO SEL switch to right.2.Set the VDD power supply to 5.0 V, and the VIO power supply to3.3 V.3.To use the device in Normal mode, set the STB switch to right.•Connect a 0 - 3.3 V square signal to TX, frequency 250 kHz and duty cycle 50%.•Connect an oscilloscope to CANH, CANL, and RX terminals.•Observe CANH, CANL, and RX signals on the oscilloscope.4.To use the device in Standby mode, set the STB switch to left.•Observe TX signal on the oscilloscope. In Standby mode, TX signal is high.•Apply CAN signal on CANH and CANL.•RX reports bus state (dominant or recessive), once the wake-up filter criteria is met.Evaluation Board Hardware Configuration11Evaluation Board Hardware Configuration•The board is supplied from a unique 5.0 V supply, connected to the GND and VDD plugs. In this case, the VIO_SEL switch is positioned left.•An additional 3.3 V supply is connected to the GND and VIO plugs. In this case, the VIO_SEL jumper switch is positioned right.• A signal generator is connected to the GND and TX plugs.•An oscilloscope is connected to the CANH and CANL plugs, and optionally to RX ad TX.Figure 5. Jumper, Resistor, and Switch SettingsTable 1. Jumper and Switch SettingsDevice ModeBoard SupplySTB SwitchVIO_SEL SwitchD1 LEDD2 LEDCommentStandby Single Left Left ON OFF Device in Standby mode. Single 5.0 V supply for VDD and VIO. No CAN path from TX to bus. Bus wake-up reported on RX.Normal Single Right Left ON ON Device in Normal mode. Single 5.0 V supply for VDD and VIO. CAN path from TX to bus and from bus to RX.Standby Dual Left Right ON OFF Device in Standby mode. 5.0 V supply for VDD and 3.3 V for VIO. No CAN path from TX to bus. Bus wake-up reported on RX.NormalDualRightRightONONDevice in Normal mode. 5.0 V supply for VDD and 3.3 V for VIO. CAN path from TX to bus and from bus to RX.VIO_SEL Switch STB Switch CANH connector GND connector MC33901Single in line device pins repeaterVIO connector VDD connector Note: all connectors are 2mm banana plugsFoot print for CAN bus termination and optional filtersTXD connector RXD connectorCANL connectorBoard reference LED, D1LED, D2Evaluation Board Hardware Configuration11.1CAN Bus Termination ConfigurationThe board allows multiple variations for the mounting and usage of the external components. Figure 6 showsmultiple options.Figure 6. CAN Bus Termination11.2External Component DefinitionThis section defines the purpose and usage of the CAN bus termination components:•R2, R3, R4, and C2: bus termination option (no termination, 60 Ohm, 120 Ohm, or split termination)•R5, R6, and CMC1: common mode choke utilization•C4, C5, and D3: extra bus filter and ESD protectionTable 2. External Component DefinitionUse Case R2R3, R4, C2R5, R6, CMC C4, C5D3No termination DNP DNP---60 or 120 Ohm termination Populate with R2 = 120DNP - --or R2 = 60 Ohm---Split termination (R3, R4, C2)DNP Populate with R3 = R4=60 Ohm,C2 = 4.7 nF (exampleonly)- -No common mode choke- - Populate R5 & R6with zero OhmWith common mode choke--R5 and R6 DNP.--Populate CMC (ex51uH)Extra bus filter---Populate with-100pF (example)Extra ESD protection----Populate withNUP2105 (example) Notes1.DNP: Do not PopulateSchematic12SchematicFigure 7. Evaluation Board SchematicBoard Layout13Board Layout13.1Top Layer RoutingFigure 8. Top Layer Routing13.2Bottom Layer RoutingFigure 9. Bottom Layer RoutingBill of Material14Bill of MaterialQty Schematic Label Value Description Package Populate Freescale Component1U1-MC33901 SOIC8YesDiodes1D1LED0805LED0805Yes1D2LED0805LED0805Yes1PESD1CAN1PESD1CAN1Zener-DNP Capacitors1C11µF Capacitor0805Yes1C210nF Capacitor0805Yes1C31µF Capacitor0805Yes1C447pF Capacitor0805DNP1C547pF Capacitor0805DNPResistors1R1470 ohm Resistor0805Yes1R2120 ohm Resistor0805Yes1R360 ohm Resistor0805DNP1R460 ohm Resistor0805DNP1R50Resistor0805Yes1R60Resistor0805Yes1R7470 ohm Resistor0805YesBill of MaterialQty Schematic Label Value Description Package Populate Switches, Connectors, Jumpers and Test Points1RX2mm banana plug Connector- Yes1CAN_H12mm banana plug Connector- Yes1CAN_L12mm banana plug Connector- Yes1CMC1B82789_100µH Inductor- DNP1CONN1Connector 8-pin Connector Single In Line- Yes1GND12mm banana plug Connector- Yes1SW1Switch 2 positions Connector- Yes1SW2Switch 2 positions Connector- Yes1TX2mm banana plug Connector- Yes1VDD12mm banana plug Connector- Yes1VIO2mm banana plug Connector- YesNotes2.Freescale does not assume liability, endorse, or warrant components from external manufacturers that are referenced in circuit drawings or tables.While Freescale offers component recommendations in this configuration, it is the customer’s responsibility to validate their application.3.DNP: Do not PopulateReferences15ReferencesFollowing are URLs where you can obtain information on related Freescale products and application solutions:15.1SupportVisit /support for a list of phone numbers within your region.15.2WarrantyVisit /warranty for a list of phone numbers within your region. SupportPagesURLMC33901 Data Sheet /files/analog/doc/data_sheet/MC33901.pdfMC33901 Product Summary Page/webapp/sps/site/prod_summary.jsp?code=MC33901 AN2409 Application Note /files/analog/doc/app_note/AN2409.pdf Analog Home Page /analog Automotive Home Page/automotiveRevision History 16Revision HistoryRevision Date Description of Changes1.02/2014•Initial ReleaseDocument Number: KT33901UGRev. 1.02/2014Information in this document is provided solely to enable system and software implementers to use Freescale products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits based on the information in this document.Freescale reserves the right to make changes without further notice to any products herein. Freescale makes no warranty, representation, or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale 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 consequential or incidental damages. “Typical” parameters that may be provided in Freescale 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. Freescale does not convey any license under its patent rights nor the rights of others. Freescale sells products pursuant to standard terms and conditions of sale, which can be found at the following address: /SalesTermsandConditions .How to Reach Us:Home Page: Web Support:/supportFreescale and the Freescale logo are trademarks of Freescale Semiconductor, Inc., Reg. U.S. Pat. & Tm.Off.SMARTMOS is a trademark of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners.© 2014 Freescale Semiconductor, Inc.。

MiCO Documentation Working Group (MDWG)Jenny Liu Track Number: RM1001CN MXCHIP Co., Ltd Version: 1.32017.1.24. Category: Reference Manual OpenMiCOKit硬件手册摘要（Abstract）本文档主要描述MiCOKit系列开发套件的硬件组成及各功能模块电路原理图，旨在为MiCO-IoT物联网开发者提供与硬件相关的技术参考。

适用对象（Suitable Readers）本文适用于初级MiCOKit开发套件的开发者，并适合所有MiCO-物联网（IoT）设备开发者参考。

获取更多帮助（More Help）登录上海庆科官方网站：</>，获取公司最新产品信息。

登录MiCO开发者论坛：<http://mico.io/>，获取更多MiCO最新开发资料。

登录FogCloud开发者中心：< https://v2.fogcloud.io/ >，获取更多FogCloud云开发文档。

微信“扫一扫”关注：“MiCO总动员”公众号，获取MiCO团队小伙伴最新活动信息。

版权声明（Copyright Notice）Copyright (c) 2015 MDWG Trust and the persons identified as the document authors. All rights reserved.版本更新说明日期修改人版本更新内容2015-7-29Jenny Liu V1.0 1. 初始版本2015-8-18Jenny Liu V1.11. 增加MCU，Wi-Fi，SPI Flash部分相关内容2. 更适用于MiCOKit各种型号，MiCOKit-Nucleo除外2015-9-8Jenny Liu V1.2 1. 修订格式，及统一公司描述为：上海庆科2017-1-24Jenny Liu V1.3 1.修改部分参考网页链接地址目录MiCOKit硬件手册 (1)版本更新说明 (1)1.MiCOKit系列开发套件概述 (5)1.1.硬件 (5)1.2.软件 (6)1.3.开发者支持 (7)2.MiCOKit Wi-Fi主板详解 (8)2.1.电源 (9)B转UART (9)2.3.MCU (10)2.4.W I-F I模块型号 (11)2.4.1 MiCOKit-3165之Wi-Fi模块 (11)2.4.2 MiCOKi-F411之Wi-Fi模块 (11)2.4.3 MiCOKi-SAMG55之Wi-Fi模块 (12)2.4.4 MiCOKi-LPC54102之Wi-Fi模块 (12)2.4.5 MiCOKi-MK22之Wi-Fi模块 (12)2.5.SPI F LASH (12)2.6.LED指示灯 (13)2.7.运行状态选择 (13)2.8.按键 (14)2.9.JTAG调试接口 (14)2.10.A RDUINO接口 (15)3.MiCOKit扩展板详解 (16)3.1.OLED显示屏 (17)3.2.RGB三色LED (17)3.3.环境传感器（选配） (18)3.4.九轴运动传感器（选配） (19)3.5.苹果认证芯片（选配） (19)3.6.距离、光照传感器 (20)3.7.温湿度传感器 (21)3.8.红外反射开关 (21)3.9.光照传感器 (22)3.10.微型直流电动机 (22)3.11.标准A RDUINO接口 (23)3.12.A RDUINO传感器接口 (23)3.13.UART接口 (24)图目录图1.2 MiCOKit套件硬件框图 (6)图1.3 MiCOKit套件软件框图 (6)图2.1 主板功能模块示意图 (8)图2.2 电源电路原理图 (9)图 2.3 USB转UART部分电路原理图 (10)图 2.4 USB转出来的串口 (10)图 2.5 MiCOKit的两种MCU位置示意图 (10)图 2.6 EMW3165模块 (11)图 2.7 EMW1088/1062模块 (12)图 2.8 EMW1000 (12)图 2.9 SPI Flash部分原理图 (13)图 2.10 LED指示灯原理图 (13)图 2.11 工作模式选择部分原理图 (14)图 2.12 按键部分原理图 (14)图 2.13 JTAG接口部分原理图 (15)图 2.14 Arduino接口部分原理图 (15)图 3.1 MiCOKit扩展板功能图 (16)图 3.2 OLED显示屏电路原理图 (17)图 3.3 RGB驱动电路原理图 (18)图 3.4 P8913驱动时序图 (18)图 3.5 环境传感器电路原理图 (19)图 3.6 九轴运动传感器电路原理图 (19)图 3.7 苹果CP芯片电路原理图 (19)图 3.8 距离、光照检测电路原理图 (20)图 3.9 温湿度电路原理图 (21)图 3.10 DHT11时序图 (21)图 3.11 红外反射电路原理图 (22)图 3.12 光照传感器电路原理图 (22)图 3.13 直流电机电路原理图 (23)图 3.14 扩展板Arduino电路原理图 (23)图 3.15. Arduino传感器接口电路原理图 (23)表目录表2.1 各型号MiCOKit开发板MCU型号 (11)表2.2 工作模式选择 (14)1.MiCOKit系列开发套件概述MiCOKit是上海庆科（MXCHIP）推出的基于物联网操作系统（MiCO）系列开发套件，可用于物联网、智能硬件的原型机开发和Demo演示。

T1C产品硬件规格书说明V2.02016-07目录1T1C (3)1.1功能介绍 (3)1.2接口说明 (4)1.3连接示意 (4)1.4发送卡指示灯及按钮说明 (6)1.5控制卡尺寸、过孔（与接收卡相同） (8)2连接显示屏 (9)3测试节目 (9)4恢复出厂设置 (10)5电气参数 (10)1T1C1.1功能介绍图1.1.1 T1C控制卡T1C控制卡专为户外小型全彩显示屏设计，适用于公交车后窗、出租车顶屏、门头招牌屏等。

具有如下特点：1、支持windows、安卓和苹果系统控制端远程管理。

2、支持通讯类型：百兆网口、U盘3、板卡集成4个HUB75E接口，无需HUB转接板即可直接连接市面上大多数LED显示屏4、最大带载6.5536万点，单卡最高可带256点（32扫模组）5、灰度等级：最高65536级6、板载4G大容量内存，支持存储4小时以上视频节目7、支持USB声卡输出音频接口，建议外接有源功放设备，效果更佳8、支持启动渐亮功能，保护电源不受过大启动冲击9、宽电压输入，板卡支持4~6.5V电压输入，保证电压不稳定的情况卡控制卡正常工作。

10、选配模块：温湿度传感器、亮度传感器、外接GPS模块、IO扩展模块11、GPS定位，能够在地图上显示及查看当前车辆位置及状态信息12、GPS校准时钟，多终端同步播放显示内容13、支持广告定位投放，用户可以按区域指定播放广告1.2接口说明5V电源HUB75E接口百兆网口USB接口GPS接口温湿度传感器接口亮度传感器接口图1.1.1 控制卡T1C接口说明具体接口说明见表1.1.1：表1.1.1控制卡T1C接口说明接口数量说明5V电源 1 外接5V直流电源，正常使用供电范围4~6.8V 百兆网口 1 用于连接用户计算机、路由器、交换机等USB接口 1 用于连接U盘、USB声卡等，可使用USB_HUB GPS接口 1 用于连接GPS模块HUB75E接口 4 用户连接LED接口板温湿度传感器接口 1 用于连接温湿度传感器模块亮度传感器接口 1 用于连接亮度传感器模块，或者IO扩展模块1.3连接示意（1）、可以使用网线直接连接或者通过交换机/路由器连接控制卡和电脑。

产品规格书PRODUCT SPECIFICATION深圳云里物里科技股份有限公司VersionV4.1发布时间2018-04-25MODEL NO/DESCRIPTION 产品名称:蓝牙模块MS50SFA1C产品型号:MS50SFA1C版本说明目录版本说明 (2)1.概述 (4)2.应用领域 (5)3.电气参数 (5)4.模块尺寸图 (6)5.引脚定义 (6)6.模块配置 (7)6.1透传模块出厂默认值 (7)6.2蓝牙服务UUID (7)6.3UUID描述 (7)6.4工作模式 (7)6.5模块应用示意图 (8)7.透传数据【服务UUID：0xFFF0】(APP端) (8)8参数设置说明 (8)9.模块测试 (112)10.支持的设备 (14)11.PCB设计说明 (145)12.注意事项 (15)13.包装信息 (155)14.质量保证 (166)1.概述MS50SFA1C串口模块采用nRF52810芯片,通过UART(串口)操作可以实现模块与手机之间数据传输。

本模块从模块，具有命令控制可以修改模块的广播名称，修改广播间隔和连接间隔。

使用该模块用户可以快速把数据以蓝牙方式进行传输。

正面反面产品特征远距离：10-60米（空旷环境）BLE协议栈深度优化，睡眠功耗1uA以下传输速率最块可达7Kbps支持串口指令配置支持Android4.3+,7+无需MFi2.应用领域该模块主要用于短距离的数据无线传输领域。

可以方便的和PC机的蓝牙设备相连，也可以与智能手机之间的数据互通。

避免繁琐的线缆连接，能直接替代串口线。

※健身器材设备，如跑步机，健身器等※医疗器械设备，如脉博测量计，心率计等※家用休闲设备，如遥控器，玩具等※办公用品设备，如打印机，扫描仪等※商业设备，如收银机，二维码扫描器等※手机外设配件，如手机防丢器等※汽车设备，如汽车维修仪等※其它人机交互设备3.电气参数参数测试值备注工作电压 1.8-3.6V直流工作频率2400-2483MHz可编程频率误差+/-20KHz Null发射功率-40~+4dBm可调整接收灵敏度-96dBm Null接收电流 4.6mA标准模式发射电流 4.6mA发射功率为0dBm时睡眠功耗1uA以下Null遥控距离10-60米BER<0.1%,空旷天线50ohm Null模块尺寸16*12*2mm Null存储大小192KB4.模块尺寸图5.引脚定义引脚名称引脚定义功能描述备注VCC 电源正极GND 电源负极P0.04BRX 串口(UART)接收蓝牙模块的RX P0.09BTX 串口(UART)发送蓝牙模块的TXP0.17SLP 睡眠/唤醒睡眠为高电平（或悬空），唤醒为低电平P0.11LED1指示灯低电平有效，睡眠状态（灭灯）、空闲状态（一秒闪烁一次）、工作状态（常亮）空闲状态：只广播；工作状态：连接P0.18BTDATA模块发送数据输入信号作为数据发送请求（用来唤醒模块）0：主机有数据发送，模块将等待接收来自主机的数据,此时模块不睡眠1：主机无数据发送，或主机数据发送完6.模块配置6.1透传模块出厂默认值模块角色:从模块模块名称:Minew_V4模块串口波特率:9600bps,8N1广播时间：1s最小连接周期：10ms;最大连接周期：1s发射功率：0dBm6.2蓝牙服务UUID透传服务UUID：FFF0透传接收UUID：FFF1透传发送UUID：FFF26.3UUID描述透传服务：蓝牙转串口透传服务透传接收：以notify方式转发串口输入的数据发送给主设备；透传发送：Write方式接收主设备发来的BLE数据。

XMC1300 Boot KitPart Number: KIT_XMC13_BOOT_001Features∙XMC1300 Microcontroller with 200KB Flash∙Detachable SEGGER J-Link∙Motor control timer∙MATH co-processor∙Motor position interface∙Digital power conversionPLEASE SEE THE FOLLOWING PAGES FOR USERS MANUALXMC1300 CPU Card For XMC1000 FamilyCPU-13A-V1XMC1300 CPU CardBoard User's Manual Revision 2.0, 2013-12-18Edition 2013-12-18Published byInfineon Technologies AG81726 Munich, Germany© 2013 Infineon Technologies AGAll Rights Reserved.Legal DisclaimerThe information given in this document shall in no event be regarded as a guarantee of conditions or characteristics. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation, warranties of non-infringement of intellectual property rights of any third party.InformationFor further information on technology, delivery terms and conditions and prices, please contact the nearest Infineon Technologies Office ().WarningsDue to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office.Infineon Technologies components may be used in life-support devices or systems only with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or otherTrademarks of Infineon Technologies AGAURIX™, C166™, CanPAK™, CIPOS™, CIPURSE™, EconoPACK™, CoolMOS™, CoolSET™, CORECONTROL™, CROSSAVE™, DAVE™, DI-POL™, EasyPIM™, EconoBRIDGE™, EconoDUAL™, EconoPIM™,EconoPACK™,EiceDRIVER™, eupec™, FCOS™, HITFET™, HybridPACK™, I²RF™, ISOFACE™, IsoPACK™, MIPAQ™, ModSTACK™,my-d™, NovalithIC™, OptiMOS™, ORIGA™, POWERCODE™, PRIMARION™, PrimePACK™, PrimeSTACK™, PRO-SIL™, PROFET™, RASIC™, ReverSave™, SatRIC™, SIEGET™, SINDRION™, SIPMOS™, SmartLEWIS™, SOLID FLASH™, TEMPFET™, thinQ!™, TRENCHSTOP™, TriCore™.Other TrademarksAdvance Design System™ (ADS) of Agilent Technologies, AMBA™, ARM™, MULTI-ICE™, KEIL™, PRIMECELL™, REALVIEW™, THUMB™, µVision™ of ARM Limited, UK. AUTOSAR™ is licensed by AUTOSAR development partnership. Bluetooth™ of Bluetooth SIG Inc. CAT-iq™ of D ECT Forum. COLOSSUS™, FirstGPS™ of Trimble Navigation Ltd. EMV™ of EMVCo, LLC (Visa Holdings Inc.). EPCOS™ of Epcos AG. FLEXGO™ of Microsoft Corporation. FlexRay™ is licensed by FlexRay Consortium. HYPERTERMINAL™ of Hilgraeve Incorporated. IEC™ of Commission Electrotechnique Internationale. IrDA™ of Infrared Data Association Corporation. ISO™ of INTERNATIONAL ORGANIZATION FOR STANDARDIZATION. MATLAB™ of MathWorks, Inc. MAXIM™ of Maxim Integrated Products, Inc. MICROTEC™, NUCLEUS™ of Mentor Graphics Corporation. MIPI™ of MIPI Alliance, Inc. MIPS™ of MIPS Technologies, Inc., USA. muRata™ of MURATA MANUFACTURING CO., MICROWAVE OFFICE™ (MWO) of Applied Wave Research Inc., OmniVision™ of OmniVision Technologies, Inc. Openwave™ Openwave Systems Inc. RED HAT™ Red Hat, Inc. RFMD™ RF Micro Devices, Inc. SIRIUS™ of Sirius Satellite Radio Inc. SOLARIS™ of Sun Microsystems, Inc. SPANSION™ of Spansion LLC Ltd. Symbian™ of Symbian Software Limited. TAIYO YUDEN™ of Taiyo Yuden Co. TEAKLITE™ of CEVA, Inc. TEKTRONIX™ of Tektr onix Inc. TOKO™ of TOKO KABUSHIKI KAISHA TA. UNIX™ of X/Open Company Limited. VERILOG™, PALLADIUM™ of Cadence Design Systems, Inc. VLYNQ™ of Texas Instruments Incorporated. VXWORKS™, WIND RIVER™ of WIND RIVER SYSTEMS, INC. ZETEX™ of Diodes Zetex Limited.Last Trademarks Update 2011-11-11Table of Contents1Overview (7)1.1Key Features (7)1.2Block Diagram (7)2Hardware Description (8)2.1Power Supply (8)2.2Reset (9)2.3Clock Generation (9)2.4Boot Option (9)2.5Debug Interface and virtual com port (9)2.6LED (9)2.7Potentiometer (10)2.8Application Card connector (10)3Production Data (12)3.1Schematics (12)3.2Layout and Geometry (15)3.3Bill of Material (15)List of FiguresFigure 1Block Diagram of XMC1300 CPU Card (7)Figure 2XMC1300 CPU Card (8)Figure 3Power Supply circuit (8)Figure 4LEDs circuit (10)Figure 5Potentiometer Circuit (10)Figure 6Pinout of the 2x30 pin edge connector (11)Figure 7Schematic 1 of 2 XMC1300 CPU Card (13)Figure 8Schematic 2 of 2 XMC1300 CPU Card (14)Figure 9XMC1300 CPU Card layout and geometry (15)List of TablesTable 1Debug connector X201 (9)Table 2LEDs Pinout (10)Table 3XMC1300 CPU Card (15)IntroductionThis document describes the features and hardware details of the XMC1300 CPU Card. This board is mounted with ARM® Cortex TM-M0 based XMC1300 Microcontroller from Infineon Technologies AG. This board is part of Infineon’s XMC1000 Application Kits1 OverviewThe XMC1300 CPU board (CPU-13A-V1) houses the XMC1300 Microcontroller and a 2x30 pin edge for application expansion. The board along with application cards (e.g. Colour LED Card, White LED Card) demonstrates the capabilities of XMC1300. The main use case for this board is to demonstrate the generic features of XMC1300 device including tool chain. The focus is safe operation under evaluation conditions. The board is neither cost nor size optimized and does not serve as a reference design.1.1 Key FeaturesThe XMC1300 CPU Card is equipped with the following features∙XMC1300 (ARM®Cortex TM-M0 based) Microcontroller, TSSOP38∙Connection to XMC1300 application cards via card edge connector∙Detachable J-Link debugger and UART virtual COM port, with micro USB connector∙Six user LEDs∙Potentiometer, connected to analog input P2.5∙Power supply via Micro-USB connector1.2 Block DiagramFigure 1 shows the functional block diagram of the XMC1300 CPU Card.Features include:−On board Debugger, for downloading and debugging of application code−Virtual com port for uart communication with terminal program e.g. Hyperterminal.−2x30 card edge connector, for extension to application card e.g. Colour LED Card and White LED Card.− 6 User LEDs connected to GPIO P0.0, P0.1, P0.6, P0.7, P0.8 and P0.9−Variable resistor R110 connected to Analog input P2.5−All the pins of XMC1300 are accessible via the connector JP101, JP102, JP103 and JP104Figure 1 Block Diagram of XMC1300 CPU Card2 Hardware DescriptionThe following sections give a detailed description of the hardware and how it can be used.Figure 2 XMC1300 CPU Card2.1 Power SupplyXMC1300 CPU Card is powered from the micro USB connector (5V); however, there is a current limit that can be drawn from the host PC through USB. If the CPU-13A-V1 board is used to drive other application board (e.g. Colour LED Card, White LED Card) and the total current required exceeds 500mA, then the board needs to be powered by external power supply connected to VDD and GND connection on board.The XMC1300 device can operate by power supply of 1.8V till 5.5Vdc. On this board, 5Vdc is used to power the XMC1300 device. However, if user wants to power the XMC1300 device with 3.3Vdc, then, set Jumper at JP201 to 3.3V side.Figure 3 Power Supply circuit2.2 ResetXMC1300 does not have a reset pin, hence, user can unplug and replug the USB cable to achieve power-on master reset.2.3 Clock GenerationNo external clock source is required. XMC1300 has two internal oscillators DCO1 and DCO2. DCO1 has a clock output of 64MHz. DCO2 is used to generate the standby clock running at 32.768KHz which used for Real Time Clock too. The main clock, MCLK and fast peripherial clock, PCLK, are generated from DCO1’s output.2.4 Boot OptionAfter power-on reset with master reset, XMC1300 device will enter different boot mode depend on the BMI (Boot Mode Index) value stored in XMC1300’s f lash configuration sector 0 (CS0). The BMI value pre-programmed on the XMC1300 device on CPU Card is User mode with debug enabled, hence, the XMC1300 device will start to run the application code in its embedded Flash after power on reset.2.5 Debug Interface and virtual com portXMC1300 CPU Card has on-board debugger which supports Serial Wire Debug (SWD) and Single Pin Debug (SPD) as debug interface. SPD is a proprietary debugging protocol from Infineon Technologies and it requires only 1 pin for debug communication. The debugger also provides a virtual COM port which support UART communication via P1.3 (rx-in) and P1.2 (tx-out) of XMC1300. There is a 2x5 pins Header Debug connector X201.Table 1 Debug connector X2012.6 LEDThe port pins P0.0, P0.1, P0.6, P0.7, P0.8 and P0.9 are connected to LED101, LED102, LED103, LED104, LED105 and LED106 respectively. The LED is turn on by output ‘L ow’ at the port pin.Figure 4 LEDs circuit2.7 PotentiometerXMC1300 CPU Card provides a potentiometer R110 for ease of use and testing of the on-chip analog to digital converter. The potentiometer is connected to the analog input P2.5. The analog output of the potentiometer is the same the VDDP voltage supplied to the XMC1300 device.Figure 5 Potentiometer Circuit2.8 Application Card connectorXMC1300 CPU Card has a 2x30 pins card edge connector. The mating connector is SAMTEC HSEC8-130-01-L-RA-XX.Figure 6 Pinout of the 2x30 pin edge connector3 Production Data3.1 SchematicsThis chapter contains the schematics for the XMC1300 CPU Card:∙Figure 7: CPU, Pin Headers, Potentiometer and LED and 60pin Edge connector ∙Figure 8: On-board Debugger, Power Supply3.2 Layout and GeometryFigure 9 XMC1300 CPU Card layout and geometry 3.3 Bill of Materialw w w.i n f i n e o n.c o m。

T h e i n f o r m a t i o n p r o v i d e d i n t h i s d o c u m e n t a t i o n c o n t a i n s g e n e r a l d e s c r i p t i o n s a n d /o r t e c h n i c a l c h a r a c t e r i s t i c s o f t h e p e r f o r m a n c e o f t h e p r o d u c t s c o n t a i n e d h e r e i n .T h i s d o c u m e n t a t i o n i s n o t i n t e n d e d a s a s u b s t i t u t e f o r a n d i s n o t t o b e u s e d f o r d e t e r m i n i n g s u i t a b i l i t y o r r e l i a b i l i t y o f t h e s e p r o d u c t s f o r s p e c i f i c u s e r a p p l i c a t i o n s .I t i s t h e d u t y o f a n y s u c h u s e r o r i n t e g r a t o r t o p e r f o r m t h e a p p r o p r i a t e a n d c o m p l e t e r i s k a n a l y s i s , e v a l u a t i o n a n d t e s t i n g o f t h e p r o d u c t s w i t h r e s p e c t t o t h e r e l e v a n t s p e c i f i c a p p l i c a t i o n o r u s e t h e r e o f .N e i t h e r S c h n e i d e r E l e c t r i c I n d u s t r i e s S A S n o r a n y o f i t s a f f i l i a t e s o r s u b s i d i a r i e s s h a l l b e r e s p o n s i b l e o r l i a b l e f o r m i s u s e o f t h e i n f o r m a t i o n c o n t a i n e d h e r e i n .Product data sheetCharacteristicsABLM1A12021Regulated Power Supply, 100-240 V AC, 12 V2.1 A, single phase, ModularMainRange of product Modicon Power Supply Product or component typePower supplyPower supply type Regulated switch mode Variant option ModularNominal input voltage 100...240 V AC single phase 100...240 V AC 2 phases Input voltage limits 90...264 V AC Kw Rating 25 W Output voltage 12 V DC Power supply output current2.1 AComplementaryNominal network frequency 50…60 Hz Network system compatibilityTN TT ITMaximum leakage current 0.25 mA 240 V ACInput protection typeIntegrated fuse (not interchangeable) 3.15 A External protection (recommended) 20 A B External protection (recommended) 20 A C External protection (recommended) 4 A B External protection (recommended) 4 A C Inrush current25 A 115 V 50 A 230 V [Ue] rated operational voltage 115 V AC 0.48230 V AC 0.38Efficiency85 % 115 V AC 85 % 230 V AC Output voltage adjustment 12...15 V Power dissipation in W 4.6 WCurrent consumption < 0.8 A 115 V AC < 0.6 A 230 V AC Turn-on time < 2 sHolding time> 20 ms 115 V AC > 60 ms 230 V AC Startup with capacitive loads 3000 µF Residual ripple< 100 mV Expected capacitor life time 10 year(s)Meantime between failure [MTBF]5000000 H at 77 °F (25 °C), full load 1000000 h at 131 °F (55 °C), 80 % loadOutput protection typeAgainst overload and short-circuits automatic reset Against over temperature manual reset Against overvoltage manual resetConnections - terminals Screw connection 0.5...1.5 mm², AWG 20...AWG 16) without wire end ferrule Screw connection 0.5...1 mm², AWG 20...AWG 18) with wire end ferrule Line and load regulation < 0.5 %line < 1 %loadStatus LED Output voltage 1 LED Green)Depth2.19 in (55.6 mm)Maximum Height3.58 in (91 mm)Width1.42 in (36 mm)Net weight0.37 lb(US) (0.170 kg)Output coupling SerialMounting support Top hat type TH35-15 rail IEC 60715Top hat type TH35-7.5 rail IEC 60715Double-profile DIN railPanel mountingEnvironmentStandards EN 62368-1EN/IEC 61010-1EN 61010-2-201EN/IEC 61204-3EN 61000-6-1EN 61000-6-2EN 61000-6-3EN 61000-6-4EN 61000-3-2EN 61000-3-3EN 61000-4-3UL 1310UL 62368-1UL 61010-2-201UL 61010-1-201CSA C22.2 No 62368-1CSA C22.2 No 61010-2-201CSA C22.2 No 61010-1-201Product certifications CECUL ListedCUL RecognizedRCMCB SchemeOperating altitude< 6561.68 ft (2000 m) overvoltage category III2000 m...5000 m overvoltage category IIShock resistance100 m/s² 11 msIP degree of protection IP20Ambient air temperature for operation-13…131 °F (-25…55 °C) without current derating)131…158 °F (55…70 °C) with current derating of 2.67 % per °C)Ambient air temperature for storage-40…185 °F (-40…85 °C)Relative humidity0…95 % without condensationElectrical shock protection class Class II without PE connectionPollution degree2Vibration resistance 3 mm 2…9 Hz)IEC 60721-3-310 m/s² 9…200 Hz)IEC 60721-3-3Electromagnetic immunity Immunity to electrostatic discharge 6 kV contact discharge) EN/IEC 61000-4-2Immunity to electrostatic discharge 9 kV air discharge) EN/IEC 61000-4-2Electromagnetic field immunity test 10 V/m 80 MHz...2 GHz) EN/IEC 61000-4-3Electromagnetic field immunity test 5 V/m 2...2.7 GHz) EN/IEC 61000-4-3Electromagnetic field immunity test 3 V/m 2.7...6 GHz) EN/IEC 61000-4-3Immunity to fast transients 4 kV on input-output) EN/IEC 61000-4-4Surge immunity test 3 kV between power supply and earth) EN/IEC 61000-4-5Surge immunity test 1.5 kV between phases) EN/IEC 61000-4-5Immunity to conducted disturbances 10 Vrms 0.15...80 MHz) EN/IEC 61000-4-6Immunity to magnetic fields 30 A/m 50...60 Hz) EN/IEC 61000-4-8Immunity to voltage dips 100 % 1 cycle) EN/IEC 61000-4-11Immunity to voltage dips 60 % 10 cycles) EN/IEC 61000-4-11Immunity to voltage dips 30 % 25 cycles) EN/IEC 61000-4-11Disturbing field emission IEC 55016-2-3Limits for harmonic current emissions IEC 61000-3-3Micro-cuts and voltage fluctuation IEC 55016-1-2Micro-cuts and voltage fluctuation IEC 55016-2-1Electromagnetic emission Conducted emissions EN 61000-6-3Radiated emissions EN 61000-6-4Dielectric strength3000 V AC input/outputOffer SustainabilityREACh free of SVHC YesEU RoHS Directive Pro-active compliance (Product out of EU RoHS legal scope)EU RoHSDeclarationMercury free YesRoHS exemption information YesChina RoHS Regulation China RoHS DeclarationWEEE The product must be disposed on European Union markets following specificwaste collection and never end up in rubbish bins.Dimensions DrawingsElectrical Safety●If the unit is use in a manner not specified by the manufacturer, the protection provided by the equipment may be impaired.●For means of disconnection a switch or circuit breaker, located near the product, must be included in the installation. A marking asdisconnecting device for the product is required.●The device has an internal fuse. The unit is tested and approved with branch circuit protective device up to 20A. This circuit breaker canbe used as disconnecting device.DimensionsSide and Rear ViewConnections and SchemaRegulated Switch Mode Power Supplies Correct Parallel Connection(1) :LoadIncorrect Parallel Connection(1) :LoadABLx1Axxxxx-1 = ABLx1Axxxxx-2max 2 x ABLx1AxxxxxL1 = L2∆V max 25 mVL Load < 90% 2 x L nomSeries Connection(1) :V out1(2) :V out2(3) : 2 x Diode, V RPM> 2 x V out1/2, L F > 2 x L nom1/2(4) :V Load = 2 x V out(5) :LoadOutput Voltage Balancing(1) :R Load1(2) :R Load2R Load1= R Load2L1= L 2= ~ L nomPerformance Curves Performance CurveX :Ambient Temperature (ºC) Y :Percentage of Max Load (%)1 :Mounting A2 :Mounting BMounting and Clearance Mounting(1) :Mounting A(2) :Mounting BIncorrect Mounting。

IMC-C1000-SFP SeriesFeaturesCompact 10/100/1000TX to 100/1000Fx Industrial Gigabit Media Converter with SFP Slot Socket► Compact Industrial Grade Design ► UTP to Fiber Media Converter► RJ-45 Port Support Auto MDI/MDI-X Function ► Auto Negotiation Speed, Half/Full Duplex ► Store-and-Forward Switching Architecture► Built-in Link Fault Pass Through (LFP) & Far End Fault (FEF)► Jumbo Frame Support: 10Kbytes► Wide-Range Redundant Power Design ► Redundant Power Input: 12~48VDC ► Power Polarity Reverse Protection ► Overload Current Protection ► DIN-Rail or Wall Mountable ► IP30 Protection ► 5-Year WarrantyAntaira Technologies’ IMC-C1000-SFP series is a compact IP30 rated gigabit Ethernet-to-Fiber media converter featuring a 10/100/1000TX Ethernet port and a dual rate 100/1000 SFP slot. It is perfectly designed to fulfill industrial applications that require distance extension and high bandwidth capabilities. This small form factor is ideal for saving space in outdoorapplications such as factory automation, security, ITS transportation, power/utility, water wastewater treatment plants, and any other extreme ambient weather environments.The IMC-C1000-SFP series has a built-in “Link Fault Pass Through” (LFP) and “Far End Fault” (FEF) function with 12~48VDC redundant power inputs with reverse polarity and overload current protection. This product series supports DIN-rail as well as wall mountable orientations and provides operating temperature range models in STD: -10°C to 70°C and EOT: -40°C to 80°C.INTRODUCTIONDIMENSIONSTechnologyStandardIEEE 802.3 10BaseT EthernetIEEE 802.3u 100BaseTX Fast Ethernet IEEE 802.3ab 1000BaseTIEEE 802.3z 1000Base-X Gigabit Fiber Switch PropertiesProtocolCSMA/CDData Process Store and forward Packet Buffer 1 Mbits MAC Table 8KJumbo Frame 10K bytesFlow ControlIEEE 802.3x for full duplex mode, back pressure for half duplex modePort InterfaceEthernet Port 1*10/100/1000BaseT(X), auto negotiation speed, Full/Half duplex mode, and auto MDI/MDI-X connection Fiber Port1*100/1000 SFP SlotFiber Wavelength Dependent on SFP moduleDIP Switch DIP Switch 1: LFP(Link Fault Pass) Enable/DisableDIP Switch 2: 1000Mbps / 100Mbps LED IndicatorsPower (PWR): On/OffEthernet: On-Link/Flashing- Data Transmitting SFP: Link & ActiveMechanical CharacteristicsCasing IP30 Metal CaseWeightUnit: 0.55lbs Shipping: 1.0lbs Dimensions 26 x 95 x 75 mmInstallation DIN-Rail/Wall Mountable Power RequirementPower InputDC 12 ~ 48V Redundant power w/4pins removable terminal block Power Consumption1.8 Watts Reverse Polarity Protection Present Overload Current ProtectionPresentEnvironment LimitOperating Temperature STD: -10° to 70° C EOT: -40° to 80° C Storage Temperature-40°C ~ 85°CAmbient Relative Humidity5 to 95%, (non-condensing) Regulatory ApprovalsEMI FCC Class AEMS EN6100-4-2,3,4,5,6,8 Free Fall IEC60068-2-32 Shock IEC60068-2-27 Vibration IEC60068-2-6 Green RoHS Compliant Certifications FCC, CE,UL-61010-1, 61010-2-201 Compliance NEMA TS1/TS2 Warranty5 YearsIMC-C1000-SFP Compact 10/100/1000Tx to 100/1000Fx Industrial Gigabit Media Converter with SFP SocketIMC-C1000-SFP-T Compact 10/100/1000Tx to 100/1000Fx Industrial Gigabit Media Converter with SFP Socket, EOT: -40 to 80 COptional AccessoriesDR-15-12 15W Industrial DIN-Rail Power Supply, 12VDC MDR-20-24 20W Industrial DIN-Rail Power Supply, 24VDC MDR-40-48 40W Industrial DIN-Rail Power Supply, 48VDC MDR-60-48 60W Industrial DIN-Rail Power Supply, 48VDC DR-75-48 75W Industrial DIN-Rail Power Supply, 48VDC SFP-M SFP Module, Multi-Mode, 550m SFP-S10SFP Module, Single-Mode, 10KmSPECIFICATIONSORDERING INFO。