SIM800H-TE_Schematic and PCB_Reference Design_V1.00

SIM800 Series _Bluetooth_ Application Note_V1.02Document Title SIM800 Series_Bluetooth_Application NoteVersion 1.02Date 2014-06-30Status ReleaseDocument Control ID SIM800 Series_Bluetooth_Application Note_V1.02General NotesSimcom offers this information as a service to its customers, to support application and engineering efforts that use the products designed by Simcom. The information provided is based upon requirements specifically provided to Simcom by the customers. Simcom has not undertaken any independent search for additional relevant information, including any information that may be in the customer’s possession. Furthermore, system validation of this product designed by SIMCOM within a larger electronic system remains the responsibility of the customer or the customer’s system integrator. All specifications supplied herein are subject to change.CopyrightThis document contains proprietary technical information which is the property of SIMCOM Limited., copying of this document and giving it to others and the using or communication of the contents thereof, are forbidden without express authority. Offenders are liable to the payment of damages. All rights reserved in the event of grant of a patent or the registration of a utility model or design. All specification supplied herein are subject to change without notice at any time.Copyright © SIMCom Wireless Solutions Ltd. 2014ContentVersion History (5)1.Bluetooth Function (6)1.1. Bluetooth Introduction (6)1.2. Bluetooth Profile (6)1.3. Bluetooth Device Address (6)1.4. AT Interface for Bluetooth Function (6)2.AT Command (8)2.1. AT+BTHOST Inquiry and set host device name (8)2.2. AT+BTSTATUS Inquiry current BT device status (9)2.3. AT+BTPOWER Power on/off BT radio (10)2.4. AT+BTPAIR Pair BT device (10)2.5. AT+BTUNPAIR Unpair BT device (12)2.6. AT+BTSCAN Scan surrounding BT device (12)2.7. AT+BTCONNECT Connect paired BT device (13)2.8. AT+BTDISCONN Disconnect BT connection (13)2.9. AT+BTGETPROF Get profile provided by paired device (14)2.10. AT+BTACPT Accept connecting request (14)2.11. AT+BTOPPACPT Accept OPP service (15)2.12. AT+BTOPPPUSH Push OPP object to paired device (16)2.13. AT+BTSPPGET Get data based on SPP service (16)2.14. AT+BTSPPSEND Send data based on SPP service (17)2.15. AT+BTATA Answer incoming call (18)2.16. AT+BTATDL Redial last number (18)2.17. AT+BTATH Hung up voice call (19)2.18. AT+BTVGS Configure voice volume (19)2.19. AT+BTVGM Configure MIC gain level (19)2.20. AT+BTATD Dial voice call (20)2.21. AT+BTRSSI Get RSSI of connected BT device (20)2.22. AT+BTVTS Send DTMF tone (21)2.23. AT+BTCIND Get status of smartphone (21)2.24. AT+BTCLCC Get call’s status of smartphone (22)2.25. AT+BTPBSYNC Sync phonebook from remote by BT (23)2.26. AT+BTPBF Find name or number from remote by BT (25)2.27. AT+BTA VRCOP A VRCP operation (27)2.28. AT+BTVIS Set visibility of BT (27)2.29. AT+BTSPPCFG SPP configuration (28)2.30. AT+BTPAIRCFG Set BT pairing mode (28)2.31. AT+CPBFEX Find name or number in module phonebook (29)2.32. AT+BTRING Control ring playing transferred from phone (30)3.CME Error Code (31)4.Examples (33)4.1. Accept request from other BT device (33)4.2. Send pairing request to other BT device (33)4.3. Get the profile provided by paired device (34)4.4. Connect service (35)4.5. Accept file from paired device (35)4.6. Send file to other paired BT device (35)4.7. Create SPP’s link as a client (35)4.8. SPP’s link be create as a server (36)4.9. Configurate SPP (36)4.10. Send data as a SPP’s client (37)4.11. As a SPP’s server worked in AT mode (37)4.12. As a SPP’s server worked in APP mode (38)4.13. Sync phonebook from remote by BT (39)4.14. Find name or number from remote by BT (39)4.15. Play music and so on by A VRCP (40)4.16. Add phonebook records to ME or SM phonebook from VCARD file (41)4.17. Set BT pairing mode (42)5.Differences between bluetooth version and the standard Version (44)5.1. ATD<str> (44)5.2. AT+CPBF (44)5.3. AT+CMUX (44)5.4. AT+CNUM (44)5.5. AT+CMGS (45)5.6. AT+CMSS (45)5.7. AT+CPMS (45)5.8. AT+CHFA (45)5.9. TTS function (45)Appendix (46)A. Reference (46)B. Profile (46)C. Glossary and Abbreviation (47)Version History DateVersion Description Author 2013-11-071.00 Original Ping Zhang Chapter 1.4, Add “power-saving mode” descriptionChapter 2.6, AT+BTSCAN add <rssi> parameterChapter 2.13, Modify AT+BTSPPGET parameterChapter 2.14, Modify AT+BTSPPSEND parameterChapter 2.22, Add AT+BTVTS commandChapter 2.23, Add AT+BTCIND commandChapter 2.24, Add AT+BTCLCC commandChapter 2.25, Add AT+BTPBSYNC commandChapter 2.26, Add AT+BTPBF commandChapter 2.27, Add AT+BTA VRCOP commandChapter 2.28, Add AT+BTVIS commandChapter 2.29, Add AT+BTSPPCFG commandChapter 2.30, Add AT+BTPAIRCFG commandChapter 3, Add Error Code 1051,1056--1058,10602014-03-26 1.01 Chapter 4, Add 4.7----4.17Ping Zhang Chapter 2.13, Modify AT+BTSPPGET and <command> descriptionChapter 2.31,Add AT+CPBFEX commandChapter 2.32,Add AT+BTRING commandChapter 4.12,Modify demo2014-06-30 1.02 Chapter 5, AddPing ZhangScopeThis document describes how to use the AT command about Bluetooth and some applicationnote.The document can apply to SIM800, SIM800-WB64, SIM808, SIM800H Series version withBluetooth fuction.1.Bluetooth Function1.1.Bluetooth IntroductionBluetooth is a wireless technology standard for exchanging data over short distances (usingshort-wavelength radio transmissions in the ISM band from 2400–2480 MHz) from fixed and mobile devices, creating prsonal area networks (PANs) with high levels of security.Bluetooth was standardized as IEEE 802.15.11.2.Bluetooth ProfileTo use Bluetooth wireless technology, a device has to be able to interpret certain Bluetooth profiles, which are definitions of possible applications and specify general behaviors that Bluetooth enabled devices use to communicate with other Bluetooth devices. These profiles include settings to parametrize and to control the communication from start. Adherence to profiles saves the time for transmitting the parameters anew before the bi-directional link becomes effective. There are a wide range of Bluetooth profiles that describe many different types of applications or use cases for devices.Besides of all profiles, there have four basic ones, they are GAP/SDAP/SPP/GOEP Profile.1.3.Bluetooth Device AddressThe Bluetooth device address stores the network address of a Bluetooth–enabled device. It is used to identify a particular device during operations such as connecting to, pairing with, or activating the device.A Bluetooth–enabled device address is a unique, 48 bits address containing the following three fields:•LAP field: lower part of the address containing 24 bits.•UAP field: upper part of the address containing 8 bits.•NAP field: non–significant part of the address containing 16 bits.The LAP and the UAP represent the significant address part (SAP) of the Bluetooth device address.1.4.AT Interface for Bluetooth FunctionAs module solution, we provide series of AT interface to operate Bluetooth function, including pairing, bonding, pushing or receiving file.Also including interface for SPP service, which could communicate between Bluetooth device and others via serial port.When the module as a Bluetooth headset role, we provide a set of AT commands to control theremote smart phones, such as phone calls, turn on or hang up calls and so on.By default, the module operates in power-saving mode, which means that the module can besimultaneously connected to a Bluetooth device. When the module to establish a connection with adevice, other devices can not be scanned into the module, the module can not get Profile, will notbe able to establish new connections and modules. If the customer's application scenario, themodule needs to be multiple Bluetooth devices (currently up to three) connection, you need to usethe AT + BTSPPCFG = 1 command to turn off the power saving mode. It should be noted that thepower saving mode does not affect the module initiative to connect to other Bluetooth devices.2. AT Command CommandDescription AT+BTHOST Inquiry and set host device name AT+BTSTATUSInquiry current BT device status AT+BTPOWERPower on or power off BT radio AT+BTPAIRPair BT deviceAT+BTSCANScan surrounding BT device AT+BTUNPAIRUnpair BT deviceAT+BTCONNECTConnect paired BT deviceAT+BTDISCONNDisconnect BT device AT+BTGETPROFGet profile provided by paired deviceAT+BTACPTAccept connecting requestAT+BTOPPACPTAccept OPP serviceAT+BTOPPPUSHPush OPP object to paired deviceAT+BTSPPSENDSend data based on SPP service AT+BTSPPGETGet data based on SPP service AT+BTATAAnswer incoming call AT+BTATDLRedial last number AT+BTATHHung up voice call AT+BTVGSConfigure voice volume AT+BTVGMConfigure MIC volume AT+BTATDDial up a voice call AT+BTRSSIGet RSSI of connected device AT+BTVTSSend DTMF tone AT+BTCINDGet status of smartphone AT+BTCLCCGet call’s status of smartphone AT+BTPBSYNCSync phonebook from remote by BT AT+BTPBFFind name or number from remote by BT AT+BTA VRCOPA VRCP Operation AT+BTVISSet visibility of BT AT+BTSPPCFGSPP’s config AT+BTPAIRCFGSet BT pairing mode AT+CPBFEXFind name or number in module phonebook AT+BTRINGControl ring playing transferered from phone2.1. AT+BTHOST Inquiry and set host device nameAT+BTHOST Inquiry and set host device nameResponse+BTHOST: (1-18)OKTest commandAT+BTHOST=?ParametersSee Write CommandResponse+BTHOST: <name>, <address>OKRead commandAT+BTHOST?ParametersSee Write CommandResponseOKWrite commandAT+BTHOST=<name> Parameters<name> device name<address> device addressNote Max length of <name> is 18 bytes,and display in UTF-8 code.2.2.AT+BTSTATUS Inquiry current BT device statusAT+BTSTATUS Inquiry current BT device statusResponseOKTest CommandAT+BTSTATUS=? ParametersSee Read CommandResponseIf unpaired before:+BTSTATUS: <status>If paired before but unconnected:+BTSTATUS: <status>P: <paired id>, <name> <address>If paired and connected:+BTSTATUS: <status>P: <paired id>, <name> <address>C: <connected id>,<name>,<address>,<profile name>OKRead CommandAT+BTSTATUS?Parameters<status> 0 Initial1Disactivating2Activating5 Idle6 Scanning7Inquiry_Res_Ind8 stopping scanning9Bonding12Connecting13Unpairing14 Deleting paired device15 Deleting all paired device16Disconnecting19 Pairing confirm while passive pairing20 Waiting for remote confirm while passive pairing25Acceptingconnection26 SDC Refreshing29 Setting host name30 Releasing all connection31 Releasing connection36Activatingservice<paired id> paired device ID<connected id> connected device ID<name> device name<address> device address<profile name> profileNote Max length of <name> is 18 bytes, 18 bytes in UTF-8 code2.3.AT+BTPOWER Power on/off BT radioAT+BTPOWER Power on/off BT radioResponse+BTPOWER: (list of supported <n>s)OKTest CommandAT+BTPOWER=?ParametersSee Write CommandResponseOKWrite CommandAT+BTPOWER=<n>parameter<n> 0 power off BT radio1 power on BT radioNote After power off BT radio, should wait 25s at least to re-power on BTradio.2.4.AT+BTPAIR Pair BT deviceAT+BTPAIR Pair BT deviceResponse +BTPAIR: 0,(list of supported <device ID>s )+BTPAIR: 1,(list of supported <confirm>s )+BTPAIR: 2,( length of supported <passkey>s )OKTest CommandAT+BTPAIR=? ParametersSee Write CommandResponse OK If digital key exchanged +BTPAIRING: <name>,<address>,<passcode> If passkey exchanged: +BTPAIRING: <name>,<address> If passive mode with succees: +BTPAIR: <id>,<name>,<address> If passive mode with failure: +BTPAIR: 0 Parameters <device ID> BT device ID <confirm> 1 accept0 reject<passkey> passkey, length is （4-16）<id> 0 paired failed>=1 paired deivce ID<name > BT device name<address > BT device address<passcode> Digital passwordWrite Command1) activeAT+BTPAIR=0,<device ID>2) passive withdigital key requestAT+BTPAIR=1,<confirm>3) passive withpasskey requestAT+BTPAIR=2,<passkey> URCIf there is incoming request:+BTPAIRING: <name>,<address>,<passcode>or+BTPAIRING: <name>,<address>Parameters<name > device name<address > device address<passcode> digital passwordNote1. Max length of <name> is 18 bytes, 18 bytes in UTF-8 code2. Pairing timeout is around 15s each side2.5.AT+BTUNPAIR Unpair BT deviceAT+BTUNPAIR Unpair BT deviceResponse+BTUNPAIR: (list of supported <device ID>s)OKTest CommandAT+BTUNPAIR=?ParameterSee Write CommandResponseOKWrite CommandAT+BTUNPAIR=<device ID>Parameter<device ID> Paired Device ID.0 delete all the paired device1 delete the the paired device corresponding to ID2.6.AT+BTSCAN Scan surrounding BT deviceAT+BTSCAN Scan surrounding BT deviceResponse+BTSCAN: (list of supported <switch>s), (list of supported <Timer>s)OKTest CommandAT+BTSCAN=?ParametersSee Write CommandResponseOKIf BT device scanned:+BTSCAN: <status>,<device ID>,<name>,<address>,<rssi>If terminate:+BTSCAN: <status>Wrtie CommandAT+BTSCAN=<switch>[,<Timer>]Parameters<switch> 1 start0 stop<status> 0 BT device found1 scanning finished2 scanning stop3 scanning failed<Timer> scanning time 10-60s<device ID> BT device ID scanned<name> BT device name<address> BT device address<rssi> -127…0 RSSI value of BT deviceNote 1．Max length of <name> is 18 bytes, 18 bytes in UTF-8 code2．If <timer> ommited, the default value is 30s2.7.AT+BTCONNECT Connect paired BT deviceAT+BTCONNECT Connect paired BT deviceResponse+BTCONNECT: (list of supported <device ID>s), (list of supported<profile ID>s)OKTest CommandAT+BTCONNECT=?ParametersSee Write CommandResponseOKIf OK:+BTCONNECT: <id>,<name>,<address>,<profile name>If failed:+BTCONNECT: 0Write CommandAT+BTCONNECT=<deviceID>,<profile ID>Parameters<device ID> ID of paired BT device< profile ID> BT profile ID<id> ID of connected BT device<name> BT device name<address> BT device adress<profile name> BT device service nameNote 1. Max length of <name> is 18 bytes, 18 bytes in UTF-8 code2. Connection timeout is around 20s3. if incoming request, there will be URC+BTCONNECING: <address>,<profile name>2.8.AT+BTDISCONN Disconnect BT connectionAT+BTDISCONN Disconnect BT connectionResponse+BTDISCONN: (list of supported <device ID>s)OKTest CommandAT+BTDISCONN=?ParametersSee Write CommandWrite CommandAT+BTDISCONN=<device ID>ResponseOK+BTDISCONN: <name>,<address>,<profile name>Parameters<device ID> connected device ID<name > device name<address > devie address<profile name> profile serviceNote1． Max length of <name> is 18 bytes, 18 bytes in UTF-8 code 2． If disconnected by remote, there still be URC: +BTDISCONN2.9. AT+BTGETPROF Get profile provided by paired deviceAT+BTGETPROF Get profile provided by paired deviceResponse +BTGETPROF: (list of supported <device ID>s )OKTest CommandAT+BTGETPROF=? ParametersSee Write CommandResponse OK+BTGETPROF: <profile ID>,<profile name>Write CommandAT+BTGETPROF=<device ID> Parameters<device ID> Paired Device ID<profile ID> profile ID<profile name> profile name2.10. AT+BTACPT Accept connecting requestAT+BTACPT Accept connecting requestResponse +BTACPT: (list of supported <confirm>s )OKTest CommandAT+BTACPT=?Response OKIf connected successfully, then will report:+BTCONNECT: <id>,<name>,<address>,<profile name>If connecting failed:+ BTDISCONN: <name>,<address>,<profile name>Write CommandAT+BTACPT=<confirm> Parameters<confirm> 1 accept0 reject<id> >0 connected device ID<name > device name<address > device address<profile name> profile nameURCIf incoming connecting request:+BTCONNECTING: <address>, <profile name>Parameters<address > device address<profile name> profile nameNoteMax length of <name> is 18 bytes, 18 bytes in UTF-8 code2.11. AT+BTOPPACPT Accept OPP serviceAT+BTOPPACPT Accept OPP serviceResponse +BTOPPACPT: (list of supported <confirm>s ),(list of supported<drv >)OKTest CommandAT+BTOPPACPT=?Response OK +BTOPPPUSH: <status>Parameters<confirm> 1 Accept0 Reject<drv> 0 internal flash memory1 external memory card<status> 0 failed1 successfulWrite CommandAT+BTOPPACPT=<confirm>[,<drv>] URC:If there has an incoming opp file, there will be a URC report.+BTOPPPUSHING: <name>, <file name>Parameters<name > device name<file name> file nameNote 1. Max length of <name> is 18 bytes, 18 bytes in UTF-8 code2．File is stored in path: C:\User\BtReceived\ for internal memory card,D:\BtReceived\ for external memory card. At the first time to use SDcard, customer must execute “AT+SD2PCM=0” and “AT&W”, thenreboot the module.2.12.AT+BTOPPPUSH Push OPP object to paired deviceAT+BTOPPPUSH Push OPP object to paired deviceResponse+BTOPPPUSH: (list of supported <device ID>s), (length of supported<string>s)OKTest CommandAT+BTOPPPUSH=?ParametersSee Write CommandResponseOK+BTOPPPUSH: <para>Write CommandAT+BTOPPPUSH=<device ID>,<string>Parameters<device ID> Paired Device ID<string> file name include complete path, lenght（4-259）<para> 0 Send failed1 Send successfully2ServerissueNote2.13.AT+BTSPPGET Get data based on SPP serviceAT+BTSPPGET Get data based on SPP serviceResponse+BTSPPGET: (list of supported <command>s), (list of supported<connectId>), (list of supported <reqLength>s), (list of supported<showWithHex>s)OKTest CommandAT+BTSPPGET=?ParametersSee Write CommandResponse+BTSPPGET: <command>OKRead CommandAT+BTSPPGET?ParametersSee Write CommandResponseOKorERRORIf command value is 2,return:+BTSPPGET: <connectId>,<cnfLen1>OKIf command value is 3,return:+BTSPPGET: <connectId>,<cnfLen1>[,<data string>]OKWrite Command1).IfAT+BTSPPCFG=”MC”,2 response1(Enablemulti-connect)AT+BTSPPGET=<command>[,<connectId>][,<reqLength>][,<showWithHex>]2).IfAT+BTSPPCFG=”MC”,2 response0(Disablemulti-connect)AT+BTSPPGET=<command>[,<reqLength>][,<showWithHex>]Parameters<command> 0 Auto mode. Data will be output in decimal system.1 Manual mode. There will be an indication when firstpackage arrives.2 Inquiry data length in manual mode.If multi-connectenabled,this command need parameter <connectId>.3 Getting data in manual mode. If multi-connectenabled,this command need parameter <connectId>.You can inputparams of <reqLength> and <showWithHex> when you need.<reqLength> 1-1024 , the length of data requested, only valid in manualmode<showWithHex> 1, displayed in hex, only valid in manual mode<connectId> connection`s ID<cnfLen1> 0-1024, character length<data string> string printedNote URCWhen the module receives data by SPP,there will be URC report:1. Auto mode+BTSPPDATA: <connectId>,<cnfLen2>,<data string>2. Manual mode+BTSPPMAN: <connectId>Parameter<cnfLen2> 1-1024, length of printed character2.14.AT+BTSPPSEND Send data based on SPP serviceAT+BTSPPSEND Send data based on SPP serviceWrite Command1).IfResponse>If successful, SEND OK If failed, SEND FAIL Or if this connectId is not allowed to send data, ERROR AT+BTSPPCFG=”MC”,2 response1(Enablemulti-connect)AT+BTSPPSEND=<connectId>,<length>2).IfAT+BTSPPCFG=”MC”,2 response0(Disablemulti-connect)AT+BTSPPSEND=<length>Parameters <connectId > connection`s ID.If disable multi-connection, this param is no need. <length> 1-1024, the length of data will be sent. When the length of inputing data is up to <length> specified, the package will be sent out automatically. Press ESC key will quit the process. Response > If successful, SEND OKOr failed,SEND FAILOr if this connectId is not allowed to send data,ERRORExecuteCommandAT+BTSPPSEND 1.If multi-connection function is enabled, this command will be disabled.2.In this mode, <Ctrl+z> will send the package immediately, and ESC will quit the process.2.15. AT+BTATA Answer incoming callAT+BTATA Answer incoming callResponse OKExecute CommandAT+BTATA URCIf there is incoming Call on remote phone, will report below:BTRINGNoteWhen module connected with smartphone as an earphone,if here comes incoming call,the call would be answered through this command2.16. AT+BTATDL Redial last numberAT+BTATDL Redial last numberExecute CommandAT+BTATDLResponse OK Note When module connected with smartphone as an earphone,would rediallast number through this command2.17. AT+BTATH Hung up voice callAT+BTATH Hung up voice callExecute CommandAT+BTATHResponse OK NoteWhen module connected with smartphone as an earphone, the incoming call would be hung up through this command2.18. AT+BTVGS Configure voice volumeAT+BTVGS Configure voice volumeResponse +BTVGS: (<gain> range )OKTest CommandAT+BTVGS=? Module is Earphone modeResponse +BTVGS: <gain>OKRead CommnadAT+BTVGS?Response OK Write CommandAT+BTVGS=<gain> Parameter<gain > volumeThis command is used configure call volume when the module isconnected with smartphone as an earphoneNoteFor some smartphone,after connected with BT earphone,the current callvolume may not be transmitted to earphone,thus the return value of theread command may be 0.But after setting once,the value would be correct.2.19. AT+BTVGM Configure MIC gain levelAT+BTVGM Configure MIC gain levelResponse +BTVGM: (<gain> range )OKTest CommandAT+BTVGM=?Read CommandAT+BTVGM? Response +BTVGM: <gain>OKResponse OK Write CommandAT+BTVGM=<gain> Parameter<gain > MIC gain levelThis command is used set MIC volume when the module is connectedwith smartphone as an earphoneNoteFor some smartphone,after connected with BT earphone,the current MICvolume may not be transmitted to earphone,thus the return value of theread command may be 0.But after setting once,the value would be correct. 2.20. AT+BTATD Dial voice callAT+BTATD Dial voice callResponse +BTATD: (<number> length range )OKTest CommandAT+BTATD=?Response OK Write CommandAT+BTATD=<number> Parameter<number > phone numberModule as earphone connected to smartphone, this command could makean outgoing callNote2.21. AT+BTRSSI Get RSSI of connected BT deviceAT+BTRSSI Get RSSI of connected BT deviceResponse +BTRSSI: (list of supported <device ID>s )OKTest CommandAT+BTRSSI=?Response +BTRSSI: <rssi>OKWrite CommandAT+BTRSSI=<device ID> Parameters<device ID> Connected Device ID<rssi> -127…0 RSSI value of BT deviceNote RSSI value is negative, the smaller value represents the worse signal2.22.AT+BTVTS Send DTMF toneAT+BTVTS Send DTMF toneResponse+BTVTS: (<dtmf>’s cope)OKTest CommandAT+BTVTS=?ResponseOKWrite CommandAT+BTVTS=<dtmf> Parameter<dtmf> DTMF toneNote When module connected with smartphone as an earphone,would send DTMF tone through this command2.23.AT+BTCIND Get status of smartphoneAT+BTCIND Get status of smartphoneResponse+BTCIND: (0,1)OKTest CommandAT+BTCIND=?ResponseOKParameter<mode> 1 auto report open0 auto report closeWrite CommandAT+BTCIND=<mode>Unsolicited Result CodeWhen <mode>=1, any changed in<service>,<call>,<call_setup>,<held>,<signal>,<roam>,<battchg> , anunsolicited result code is returnd：+BTCIND:1,<service>,<call>,<call_setup>,<held>,<signal>,<roam>,<battchg>Read CommandAT+BTCIND?Response+BTCIND:<mode>,<service>,<call>,<call_setup>,<held>,<signal>,<roam>,<battchg>OKParameters<service> 0 no net service1 net service is normal<call> 0not active1 active<call_setup> 0 set up complete1 incoming call2 outgoing call3 remote alert<held> 0 no held call1 active calls be placed or switched2 active calls be palced and no active call<signal> 0..5 net work signal<roam> 0 no roaming1 in roaming<battchg> 0..5 power levelNote When module connected with smartphone as an earphone, these statuses can be getted.2.24.AT+BTCLCC Get call’s status of smartphoneAT+BTCLCC Get call’s status of smartphoneResponseOKTest CommandAT+BTCLCC=?ResponseOKWhen call is active:+BTCLCC: <index>,<dir>,<stat>,<mode>,<mpty>,<number>,<type>…When no call:+BTCLCC: 0Read CommandAT+BTCLCC?Parameters<id x> 1..7 Call identification number<dir>0 Mobile originated (MO) call1 Mobile terminated (MT) call<stat>State of the call:Active1Held2Dialing(MOcall)3 Alerting (Mo call)4Incoming(MTcall)5 Waiting (MT call)。

SIM808开发板蓝牙SPP功能调试笔记注意：只有SIM808蓝牙版本才具备该功能。

1、AT+BTPOWER=1 //打开蓝牙电源正常返回”OK”，如果模块蓝牙电源原本已经打开，那么将返回ERROR。

2、AT+BTHOST? //查询模块名称和地址返回:AT+BTHOST?+BTHOST: Niren,27:a7:2c:90:62:60OK也可以通过该指令修改蓝牙设备名称3、AT+BTSCAN=1,10 //收索蓝牙附件设备，收索时间10S返回:AT+BTSCAN=1,10OK+BTSCAN: 0,1,"MEIZU MX3",22:22:4e:73:13:84,-45 //收索到的设备，设备ID:1+BTSCAN: 1 //收索结束注意：这里需要等待返回+BTSCAN: 1才代表收索结束。

4、AT+BTPAIR=0,1 //主动请求匹配设置ID：1蓝牙设置AT+BTPAIR=0,1OK+BTPAIRING: "MEIZU MX3",22:22:4e:73:13:84,573342注意:这时手机就会收到模块提交的配对请求，手机确认配对即可5、AT+BTPAIR=1,1 //响应连接请求AT+BTPAIR=1,1OK+BTPAIR: 1,"MEIZU MX3",22:22:4e:73:13:846、AT+BTGETPROF=1 //获取配对的蓝牙设备提供的服务返回：AT+BTGETPROF=1AT+BTGETPROF=1+BTGETPROF: 10,"PBAP"+BTGETPROF: 1,"A2DP(Source)"+BTGETPROF: 2,"HFP(AG)"+BTGETPROF: 8,"AVRCP(Target)"OK注意：这里费服务列表中没有我们需要的SPP服务，这需要，先打开手机的蓝牙串口助手，打开蓝牙助手后再重新获取一次服务。

P R O D U C T A P P L I C A T I O N N O T E S16MMIC SWITCH DRIVER TECHNIQUESFigure 1: Floating Ground Driver for the HMC182S14 SP4T Switch.Positive Voltage Control of MMICMulti-Throw Switches with Floating Ground TechniqueHittite Microwave Corporation devel-oped multi-throw switches with on-The Hittite Microwave SPNT switch product line includes non-refl ective and refl ective switches in standard confi guratoins of HMC165S14 SP4T , HMC182S14 SP4T SP6T , and HMC183QS24 SP8T . All are plastic encapsulated devices in industry standard SOIC and QSOP packages, readily used in automated assembly environments.The decoder-on-board technology developed by Hittite Microwave pro-vides the user with the advantage of a simplifi ed control interface. Decoder topologies for each switch style are as follows: 2:4 decoder for the SP4T , 3:6 decoder for the SP6T , and 3:8 decoder for the SP8T switch. This directly sim-plifi es board layout by reducing the number of driver lines required to con-trol the switch. The reduction of con-trol lines on the PCB serves directly to reduce pathways for RF crosstalkon the bias & control lines and ingress of signal from one channel to another thus enhancing isolation performance of the multi-throw switch. There is a −Vee bias requirement (-5.0 to -6.5 Vdc +/-10%) for each SPNT switch and the control lines accept negative logic voltages of; Low = 0.0 to -1.0 Vdc & High = Vee +/-0.25 Vdc.The RF performance using Hittite Microwave proprietary driver & RF circuitry has inherently low loss & linear performance. The active ele-ments of the circuit are depletionmode MESFET’s (Metal Semiconduc-tor Field Effect T ransistor) or “FETs”,a voltage controlled device. In stan-dard operation, the drain & source ofeach FET is held at DC ground withthe potential at the gate of the FETheld at 0 volts placing the FET in thelow loss or “on” state, and the potential of the gate held at -5 volts for the high impedance or “off” state.The system designer may not have negative voltage bias & control signals readily available. The fl oating ground switch dri8ver method described below can be used to enable positive bias & control opera-tion of the GaAs multi-throw switch. By the use of blocking capacitors,pull-up resistors, and careful attention to layout details of the PCB, the fl oating ground switch driver approach can be used with good results and a minimum of additional circuitry. Because the FET is a voltage controlled deivce there must be apotential difference of >-3.5 Vdc to <- 7 Vdc between the gate and drain-source channel to establish the certain pinch-off of the channel, thereforacheiving the high loss or “off” state in the FET . This can be accom-plished by holding the source and drain at +5 Vdc +/-10% and togglingthe gate between 0 and +5 Vdc +/- 10% to change the state of the FET .All DC bias points and control signals are therefore raised +5Vdc fromtheir normal potentials.An example of this floating ground technique using microstrip trans-mission lines is shown in Figure 1 for the HMC182S14 SP4T non-re-16P R O D U C T A P P L I C A T I O N N O T E SMMIC SWITCH DRIVER TECHNIQUESfl ective switch. Please note that the use of coplanar waveguide (CPW) ciruit techniques will save space and enhance RF performance, lower loss and higher iso-lation. See Hittite Microwave catalog application note, “Design T echniques Enhance Isolation in Switch Assem-blies” page 8-24, for further deiscussion of the use of CPW transmission lines and printed circuit board design techniques.In Figure 1, the internal switch shunt FET sources are pulled to +5 volts through the 270 nH inductor (L1) applying bias to the fl oating ground plane. The internal switch FET drains are held at +5 volts potential via the 10 Kohm resistor (R1) and capacitor (C9) arrangement shown at the RF Common Node. The 10 Kohm resistor is critical for reducing RF crosstalk, with capacitor C9 providing a path to ground for stray RF signals. It is criti-cal in all cases for capacitors to be placed as closely as possible to the body of the switch for best RF per-formance. The 10 Kohm resistor should be placed on the RF trace without use of a “stub” landing solder pad for the resistor on the trace. If a resistor landing pad is required for PCB manufacturing yield issues then it’ssize should be minimized to reduce RF signal loss. The con-nections to hard RF/DC ground must have many via holes to ensure a low impedance path to ground at the highest RF frequency of operation.High Q capacitors should be used for best perfor-mance in all cases, C1-C10. DC block, decoupling & bypass applications shoulduse 100 pF to 0.01 uF capac-itors. For a typical operating range of 10 - 1500 MHz, the 0.01 uF capacitor provides for a low resistance path to ground for RF in the decoupling & bypass functions and a low insertion loss element in the DC block func-tion. Switch users at predomnantly higher frequencies (through 2 GHz) may wish to substitute lower value capacitors as 100 to 330 pF for Dc block, decoupling and bypass functions. In Figure 1, the bypass capac-itors C1-C4 should be placed as clost to the fl oating ground plane as possilbe to minimize ground inductance and maximize isolation. For broadband operation of this circuit, 10-2000 MHz, it is recommended that a com-bination of 0.01 uF capacitors (C2 & C4) and 100 pF capacitors (C1 & C3) be used bor the bypass function on the RF circuit ground.The bias pin, Vee, of the HMC182S14 must now be held to Vdc (DC ground) versus it’s normal non-fl oating bias of -5 to -6.5 Vdc. Direct connection to the HMC182S14 switch A & B control lines by the +5 Vdc biased 74HCT04 hex inverter (or any positive logic HCT TTL logic driver device) is now possible. Table I shows the truth table of the HMC182S14in positve bias operation for the fl oating ground cir-cuit topology of Figure 1.TABLE 1P R O D U C T A P P L I C A T I O N N O T E S16Notes:MMIC SWITCH DRIVER TECHNIQUES16P R O D U C T A P P L I C A T I O N N O T E SNotes:MMIC SWITCH DRIVER TECHNIQUES。

Contents1. GENERAL DESCRIPTION2. MOUNTING INSTRUCTIONS3. REPLACING FUSES4. ASSEMBLY5. CURRENT INPUTS6. CONNECTING TRANSMITTERS TO THE MULTIPLEXER7. CONNECTING Pt-100 TO THE MULTIPLEXER8. CONNECTING THE MULTIPLEXER TO A PLC9. CONTROL9.1 Enable9.2 Address9.3 Address Polarity9.4 Control Tables10. CALIBRATION10.1 Calibration Procedure10.2 Calibration Tables10.2.1 "ZERO" - Coarse Calibration Tables10.2.2 "SPAN" - Coarse Calibration Tables11. MULTIDROP CONFIGURATION12. SPECIFICATIONS11. GENERAL DESCRIPTION2WARNING: Never install a fuse rated more than 800mA The DRA-RTM-8 is a multiplexer for 16 analog inputs - eight of which, marked 1-8, are direct inputs for Pt-100 sensors, while the remaining (9-16), are for 4-20mA current loops.The DRA-RTM-8 output format is a 4-20mA current loop, with a 28mA limitation.Each Pt-100 input has its own signal conditioner, allowing each input to be calibrated separately. Each signal conditioner includes six DIP switches for coarse calibration and two potentiometers for fine tuning.2. MOUNTING INSTRUCTIONSThe DRA-RTM-8 is designed for standard DIN rail mounting.Place the unit on the upper part of the mounting rail with the fastening tab facing down. Using a suitable flat screwdriver loosen the tab slightly and attach the unit to the rail. Once the tab is loosened, ensure that the unit is fastened securely in place.3. REPLACING FUSESTo replace a blown fuse, disassemble the unit as follows:a. Take off both terminal strips by removing the four screws at the edges. Note: This does not require disconnecting the cables connected to the strips.b. Remove the front panel using a suitable flat screwdriver. Press down gently on the plastic springloaded tabs located in the slots on either side of the unit.c. Disconnect the flat connectors which connects the front panel printed circuit.d. Replace the blown fuse.4. ASSEMBLYThe DRA-RTM-8 unit includes two printed circuit cards designated as P.N 7020 and P.N 7021. The two printed circuit cards should occupy the slots in the enclosure according to fig 1.3Insert the two printed cards into their slots.Connect the flat cable between them.Connect the front panel flat cables. Thepanel must be inserted into the grooves onboth sides of the case while pressing downuntil a distinct "click" is heard. Assembly iscompleted by laying the terminal strips inplace.Note: The terminal strips are polarized and must not be placed backwards.5. CURRENT INPUTSThe eight 4-20mA current inputs are marked as channels 9-16. These inputs are for current only. The "COM" input is the return for all the current channels. It is possible to connect any current source, as long as a closed loop is maintained.Figure 1.6. CONNECTING TRANSMITTERS TO THE MULTIPLEXER6.1 TWO WIRE TRANSMITTERA Two-Wire transmitter is connected so that itspositive terminal is connected to the positiveterminal of the power supply, and its negativeterminal is connected to the "I" terminal.(see fig 2)Figure 2.6.2 FOUR WIRE TRANSMITTERA Four-Wire transmitter is connected so that itspositive terminal is connected to the "I" terminal,and its negative terminal is connected to the"COM" terminal. (see fig 3)Figure 3.WARNING: Voltage sources should not be connected to the current inputs,as permanent damage might occur.4Figure 4.7. CONNECTING Pt-100 TO THE MULTIPLEXERThe Pt-100 probe should be connected according to fig 4. Thethree wires connecting the probe should be identical.The distance of the probe can be up to 200 meters.A shielded cable is recommended.The shield should be grounded at one point. When possible,connect the ground at the multiplexer's end.8. CONNECTING THE DRA-RTM-8 TO A PLCThe multiplexer output should be connected to 4-20mA input of the PLC analog module (see fig 5).The DRA-RTM-8 multiplexer generates the output current, therefore the PLC analog module should be configured for four wire transmitter connection.WARNING: NEVER apply 24Vdc to the DRA-RTM-8's +Io terminal as in two-wire connection, and make sure that the PLC's analog module is configured as a passive input.9. CONTROLThe DRA-RTM-8 unit is controlled via fouraddress lines and one E (Enable) line.The control terminals (Address andEnable), were designed to receive controlsignals from TTL levels up to 60V so thatalmost any PLC's DC output module canbe used. (see fig 5)Figure 5.9.1 ENABLEThe unit is enabled when a logical "1" (5V < E < 60V) is connected to the E Terminal. In a disabled state, the DRA-RTM-8 outputs no current and reflects a Hi-Z state. This feature allows the connection of several DRA-RTM-8 units by tying their outputs and control in parallel and addressing them by controlling the individual Enable terminals.9.2 ADDRESSThe required channel is selected byfour address lines.The operating voltages are:Logical "1" 5V < Vi < 60VLogical "0" 0V < Vi< 0.5V9.3 ADDRESS POLARITY (see fig 6)Address polarity is controlled by three internal pins and a jumper over two of them, located on PN 7021 printed circuit board, accessible behind the Enable terminal. The unit is supplied with the jumper set for "true high" control logic, i.e. "0000" selects channel #1, and "1111" selects channel #16.Moving the jumper to the second alternative, reverses the logic.Figure 6.Note: If the address contros voltages are generated from different power supplies, then its negative terminal should be connected to theDRA-TM-8's "COM" terminal.9.4 CONTROL TABLES9.4.1 "TRUE LOW" SETTINGADDRESS BUS E OUTPUTCHANNELA0A1A2A31 1 1 1 101111111111876541 1 1 x 111x11x11x111321NO OUTPUTADDRESS BUS E OUTPUTCHANNELA0A1A2A30 0 0 0 00111111111116151413120 0 0 x 111x11x11x11111109NO OUTPUT5ADDRESS BUS E/T OUTPUTCHANNELA0A1A2A31 1 1 1 1011111111119101112131 1 1 x 111x11x11x111141516TEST MODEADDRESS BUS E/T OUTPUTCHANNELA0A1A2A30 0 0 0 001111111111123450 0 0 x 111x11x11x111678TEST MODE9.4.2 "TRUE HIGH" SETTINGNote: The unit includes three internal potentiometers. These potentiometers are carefully adjusted and sealed in the factory. It is not recommended to alter these calibration potentiometers.10. CALIBRATIONTo calibrate the DRA-RTM-8, the limits must be defined.Tmin is the temperature at which the output current is 4mA.Tmax is the temperature at which the output current is 20mA.Tspan is the difference between Tmax and Tmin.10.1 CALIBRATION PROCEDUREa. Remove the terminal strips to get access to the coarse calibration switches.b. Set the channels DIP switches to the desired calibration ranges according to thecalibration tables.c. Re-install the terminals strips. The terminal strips are polarized and should bereturned to their original position.d. Connect a Pt-100 calibrator* set for Tmin to the proper input terminals.e. Apply the proper channel selection code by connecting those which accordingthe table should be "1" to the +PWR terminal.f. Start calibrating by adjusting the proper "Z" potentiometer to obtain an outputcurrent of 4.000mA.g. Set the calibrator for Tmax and adjust the "S" potentiometer to obtain an outputcurrent of 20.000mA.h. Repeat this procedure until satisfactory results are obtained.6* The calibrator is set according to DIN 43760 Pt-100 table (a = 0.00385)10.2 CALIBRATION TABLESNote: Logic state of "0" is when the DIP switch lever is down.10.2.1 "ZERO" - COARSE CALIBRATION TABLESZERO TEMP CCHANNELS 1-4SW5SW4 SW6-50 (10)8 (75)74 (140)139 (206)205 (272)270 (338)336 (404)401 (4701)1111111111100CHANNELS 5-8SW2SW3SW11111111111110010.2.2 "SPAN" - COARSE CALIBRATION TABLESSPAN CCHANNELS 1-4SW2SW3 SW150 (76)65 (115)110 (180)135 (225)215 (440)400 (8001)11111111CHANNELS 5-8SW5SW4SW6111111111i. Change the address to the next channel to be calibrated.j. Repeat steps b to h7RETURN REQUESTS / INQUIRIESDirect all warranty and repair requests/inquiries to the OMEGA Customer Service Department.BEFORE RETURNING ANY PRODUCT(S) TO OMEGA, PURCHASER MUST OBTAIN AN AUTHORIZED RETURN (AR) NUMBER FROM OMEGA’S CUSTOMER SERVICE DEPARTMENT (IN ORDER TO AVOID PROCESSING DELAYS). The assigned AR number should then be marked on the outside of the return package and on any correspondence.The purchaser is responsible for shipping charges, freight, insurance and proper packaging to prevent breakage in transit.OMEGA’s policy is to make running changes, not model changes, whenever an improvement is possible.This affords our customers the latest in technology and engineering.OMEGA is a registered trademark of OMEGA ENGINEERING, INC.© Copyright 1996 OMEGA ENGINEERING, INC. All rights reserved. This document may not be copied,photocopied, reproduced, translated, or reduced to any electronic medium or machine-readable form, i n w h o l e o r i n p a r t , w i t h o u t p r i o r w r i t t e n c o n s e n t o f O M E G A E N G I N E E R I N G , I N C.FOR WARRANTY RETURNS, please have thefollowing information available BEFORE contactingOMEGA:1. P .O. number under which the product wasPURCHASED,2. Model and serial number of the product underwarranty, and3. Repair instructions and/or specific problemsrelative to the product.FOR NON-WARRANTY REPAIRS, consult OMEGA for current repair charges. Have the following information available BEFORE contacting OMEGA:1. P .O. number to cover the COST of the repair,2. Model and serial number of product, and 3. Repair instructions and/or specific problems relative to the product.WARRANTY/DISCLAIMEROMEGA ENGINEERING, INC. warrants this unit to be free of defects in materials and workmanship for a period of 13 months from date of purchase. OMEGA Warranty adds an additional one (1) month grace period to the normal one (1) year product warranty to cover handling and shipping time. This ensures that OMEGA’s customers receive maximum coverage on each product. If the unit should malfunction,it must be returned to the factory for evaluation. OMEGA’s Customer Service Department will issue an Authorized Return (AR) number immediately upon phone or written request. Upon examination by OMEGA, if the unit is found to be defective it will be repaired or replaced at no charge. OMEGA’s WARRANTY does not apply to defects resulting from any action of the purchaser, including but not limited to mishandling, improper interfacing,operation outside of design limits, improper repair, or unauthorized modification. This WARRANTY is VOID if the unit shows evidence of having been tampered with or shows evidence of being damaged as a result of excessive corrosion; or current, heat, moisture or vibration; improper specification; misapplication; misuse or other operating conditions outside of OMEGA’s control. Components which wear are not warranted, including but not limited to contact points, fuses, and triacs.OMEGA is pleased to offer suggestions on the use of its various products. However,OMEGA neither assumes responsibility for any omissions or errors nor assumes liability for any damages that result from the use of its products in accordance with information provided by OMEGA, either verbal or written. OMEGA warrants only that the parts manufactured by it will be as specified and free of defects.OMEGA MAKES NO OTHER WARRANTIES OR REPRESENTATIONS OF ANY KIND WHATSOEVER, EXPRESSED OR IMPLIED, EXCEPT THAT OF TITLE, AND ALL IMPLIED WARRANTIES INCLUDING ANY WARRANTY OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE HEREBY DISCLAIMED. LIMITATION OF LIABILITY: The remedies of purchaser set forth herein are exclusive and the total liability of OMEGA with respect to this order, whether based on contract,warranty, negligence, indemnification, strict liability or otherwise, shall not exceed the purchase price of the component upon which liability is based. In no event shall OMEGA be liable for consequential, incidental or special damages.CONDITIONS: Equipment sold by OMEGA is not intended to be used, nor shall it be used: (1) as a “Basic Component” under 10 CFR 21 (NRC), used in or with any nuclear installation or activity; or (2) in medical applications or used on humans. Should any Product(s) be used in or with any nuclear installation or activity,medical application, used on humans, or misused in any way, OMEGA assumes no responsibility as set forth in our basic WARRANTY / DISCLAIMER language, and additionally, purchaser will indemnify OMEGA and hold OMEGA harmless from any liability or d a m a g e w h a t s o e v e r a r i s i n g o u t o f t h e u s e o f t h e P r o d u c t (s ) i n s u c h a m a n n e r.Where Do I Find Everything I Need forProcess Measurement and Control?OMEGA…Of Course!TEMPERATUREߜ Thermocouple, RTD & Thermistor Probes,Connectors, Panels & Assembliesߜ Wire: Thermocouple, RTD & Thermistorߜ Calibrators & Ice Point Referencesߜ Recorders, Controllers & Process Monitorsߜ Infrared PyrometersPRESSURE, STRAIN AND FORCEߜ Transducers & Strain Gaugesߜ Load Cells & Pressure Gaugesߜ Displacement Transducersߜ Instrumentation & AccessoriesFLOW/LEVELߜ Rotameters, Gas Mass Flowmeters & Flow Computersߜ Air Velocity Indicatorsߜ Turbine/Paddlewheel Systemsߜ Totalizers & Batch ControllerspH/CONDUCTIVITYߜ pH Electrodes, Testers & Accessoriesߜ Benchtop/Laboratory Metersߜ Controllers, Calibrators, Simulators & Pumpsߜ Industrial pH & Conductivity EquipmentDATA ACQUISITIONߜ Data Acquisition & Engineering Softwareߜ Communications-Based Acquisition Systemsߜ Plug-in Cards for Apple, IBM & Compatiblesߜ Datalogging Systemsߜ Recorders, Printers & PlottersHEATERSߜ Heating Cableߜ Cartridge & Strip Heatersߜ Immersion & Band Heatersߜ Flexible Heatersߜ Laboratory HeatersENVIRONMENTALMONITORING AND CONTROLߜ Metering & Control Instrumentationߜ Refractometersߜ Pumps & Tubingߜ Air, Soil & Water Monitorsߜ Industrial Water & Wastewater Treatmentߜ pH, Conductivity & Dissolved Oxygen Instruments M2614/0197。

SIM800H_硬件设计手册_V1.01文档名称：SIM800H 硬件设计手册 版本：1.01 日期：2013-05-23 状态：发布 文档控制号： SIM800H_硬件设计手册_V1.01前言感谢使用SIMCom 提供的SIM800H 系列模块。

本产品具有标准AT 命令接口，可以提供GSM 语音、短消息等业务。

使用前请仔细阅读用户手册，您将领略其完善的功能和简洁的操作方法。

此模块主要用于语音或者数据通讯，本公司不承担由于用户不正常操作造成的财产损失或者人身伤害责任。

请用户按照手册中的技术规格和参考设计开发相应的产品。

同时注意使用移动产品特别是GSM 产品应该关注的一般安全事项。

在未声明之前，本公司有权根据技术发展的需要对本手册内容进行修改。

版权声明本手册版权属于SIMCom ，任何人未经我公司书面同意复制、引用或者修改本手册都将承担法律责任 Copyright © Shanghai SIMCom Wireless Solutions Ltd. 2013。

目录1.绪论 (10)2.模块综述 (10)2.1. 模块主要特性 (10)2.2. 工作模式 (12)2.3. 模块功能框图 (13)3.模块封装 (14)3.1. 引脚分布图 (14)3.2. 模块引脚描述 (15)3.3. 机械尺寸 (18)4.接口应用 (20)4.1. 供电 (20)4.1.1. 电源引脚 (21)4.1.2. 电源监测 (22)4.2. 开机关机 (22)4.2.1. 模块开机 (22)4.2.2. 模块关机 (23)4.2.3. 模块复位 (25)4.3. 省电模式 (26)4.3.1. 最小功能模式 (26)4.3.2. 休眠模式 (26)4.3.3. 从休眠模式唤醒模块 (26)4.4. RTC电源 (27)4.5. 串口、USB口 (27)4.5.1. 调试接口 (29)4.5.2. 串口功能 (29)4.5.3. 软件升级 (30)4.6. RI电平状态 (31)4.7. 音频接口 (32)4.7.1. 受话器接口电路 (33)4.7.2. 麦克风接口电路 (33)4.7.3. 音频相关电气参数 (34)4.8. SIM卡接口 (34)4.8.1. SIM卡接口 (34)4.8.2. SIM 卡座的选择 (35)4.9. PCM接口 (37)4.9.1. 复用功能 (38)4.10. 键盘接口 (38)4.10.1. 键盘复用功能 (41)4.11. I2C总线 (41)4.11.1. I2C复用功能 (41)4.12. 通用输入输出接口(GPIO) (41)4.13. 模数转换器（ADC） (42)4.14. PWM (42)4.14.1. PWM复用功能 (43)4.15. 网络状态指示灯 (43)4.15.1. 复用功能 (44)4.16. 状态指示灯 (44)4.16.1. 状态指示灯复用功能 (44)4.17. LED 接口 (44)4.18. RF 发射同步信号 (45)4.19. 天线接口 (46)4.19.1. GSM 天线接口 (46)4.19.2. 蓝牙天线接口 (47)4.19.3. FM 天线接口 (48)5. 电气，可靠性和射频特性 (49)5.1 绝对最大值 (49)5.2 工作温度 (49)5.3 数字接口特性 (49)5.4 SIM 卡接口特性 (50)5.5 SIM_VDD 特性 (50)5.6 VDD_EXT 特性 (50)5.7 VRTC 特性 (50)5.8 耗流(VBAT=4.0V) (51)5.9 静电防护 (52)5.10 射频特性 (52)5.10.1. 模块传导射频输出功率 (52)5.11 模块传导接收灵敏度 (53)5.12 模块工作频段 (53)6. 生产 (54)6.1. 模块的顶视图和底视图 (54)6.2. 推荐焊接炉温曲线图 (54)7. 附录 (55)I. 相关文档 (55)II. 复用功能表 (56)III. 术语和解释 (57)IV . 安全警告 (59)表格索引表1：模块主要特性 (10)表2：编码格式和最大网络数据速度率 (12)表3：工作模式 (12)表4：引脚描述 (15)表5：推荐的齐纳二极管型号 (20)表6： AT+CFUN不同设置下的耗流(BS-PA-MFRMS=5) (26)表7：串口引脚定义 (27)表8：串口逻辑电平 (28)表9：串口复用功能 (30)表10：RI信号线电平状态 (31)表 11：音频功放参数 (32)表 12：音频输入参数 (34)表 13：音频输出参数 (34)表14：SIM卡接口引脚定义 (34)表 15：引脚描述(AMPHENOL SIM卡座) (36)表 16：引脚描述(AMPHENOL SIM卡座) (37)表17：PCM接口引脚定义 (38)表 18： PCM复用功能： (38)表19：键盘接口引脚信号定义 (40)表 20： I2C总线接口引脚定义 (41)表 21： I2C复用功能 (41)表22：GPIO接口引脚定义 (42)表 23： ADC接口引脚定义 (42)表24：ADC参数 (42)表25：PWM引脚定义 (42)表26： BUZZER 输出特性 (43)表27：PWM复用功能 (43)表28：NETLIGHT引脚定义 (43)表29：NETLIGHT工作状态 (43)表30：NETLIGHT复用功能 (44)表31：STATUS引脚定义 (44)表32：STATUS复用功能 (44)表33：LED引脚定义 (45)表34：LED引脚参数 (45)表35：BPI_BUS1引脚定义 (45)表 36：绝对最大值 (49)表 37：模块工作温度 (49)表 38：数字接口特性 (49)表 39： SIM卡接口特性 (50)表 40： SIM_VDD 特性 (50)表 41： VDD_EXT特性 (50)表 42： VRTC特性 (50)表 43：耗流 (51)表 44： ESD 性能参数（温度：25℃，湿度：45%） (52)表 45： GSM850、EGSM900传导输出功率 (52)表 46： DCS1800、PCS1900传导输出功率 (53)表 47： 传导接收灵敏度 (53)表 48： 模块工作频段 (53)表 49： 相关文档 (55)表 50： 复用功能列表 (56)表 51： 术语和解释 (57)表 51：安全警告 (59)图片索引图1：模块功能框图 (13)图2：模块引脚图(顶视图) (14)图3：三维尺寸（单位：毫米） (18)图4：推荐PCB封装尺寸（单位：毫米） (19)图5：VBAT 输入参考电路 (20)图6：LDO供电参考电路 (20)图7： DC-DC电源参考电路 (21)图8：突发时VBAT的跌落 (21)图9：VBAT跌落的最低电压 (21)图10：使用PWRKEY驱动电路开机 (22)图11：使用PWKEY按键开机 (22)图12：使用PWRKEY开机时序图 (23)图13：使用PWRKEY关机时序图 (24)图14：复位电路 (25)图15：复位时序图 (25)图16：外部电容给RTC供电 (27)图17：不可充电电池给RTC供电 (27)图18：可充电电池给RTC供电 (27)图19：串口连接图 (28)图20：TX连接图 (29)图21：RX连接图 (29)图22：软件升级接口 (31)图23：模块作为被叫当接收到语音呼叫时RI上的电平变化 (31)图24：模块作为被叫当接收到数据呼叫（CSD）时RI上的电平变化 (32)图25：模块接收到短信息（SMS）或者串口主动上报（URC）RI上的电平变化 (32)图26：模块作为主叫时RI上的电平变化 (32)图27：受话器接口电路 (33)图28：麦克风接口电路 (33)图29：8引脚SIM卡座的接口推荐电路 (35)图30：6引脚SIM卡座的接口推荐电路 (35)图31： MOLEX 91228 SIM卡座 (36)图32：AMPHENOL C707 10M006 5122 SIM卡座尺寸图 (37)图33：键盘接口参考电路1 (39)图34：键盘接口参考电路2 (39)图35：键盘接口参考电路3 (40)图36：键盘接口说明 (40)图37：PWM参考电路 (43)图38：NETLIGHT参考设计电路 (44)图39：LED驱动电路连接示意图 (45)图40：发射同步信号时序图 (46)图41： GSM天线接口连接电路 (46)图42： GSM天线接口简化连接电路 (47)图43：蓝牙天线接口连接电路 (47)图44： FM天线接口连接电路 (48)图45：以耳机GND管脚作为FM天线的接口连接电路 (48)图46：模块顶视图和底视图 (54)图 47： 模块推荐焊接炉温曲线图 (54)版本历史 日期版本 变更描述 作者 2013-05-101.00 初版 宋家林,李亚 2013-05-23 1.01 更新图2、图3、图12、图13、图15、图40；表6、表18、表43；增加附录II ；增加了休眠章节注意事项宋家林1. 绪论本文档描述了模块的硬件应用接口，包括相关应用场合的电路连接以及射频接口等。

MPI Probe Selection GuideWith a critical understanding of the numerous measurement challenges associated with today’s RF ap-plications, MPI Corporation has developed TITAN™ RF Probes, a product series specifically optimized for these complex applications centered upon the requirements of advanced RF customers.TITAN™ Probes provide the latest in technology and manufacturing advancements within the field of RF testing. They are derived from the technology transfer that accompanied the acquisition of Allstron, then significantly enhanced by MPI’s highly experienced RF testing team and subsequently produced utilizing MPI’s world class MEMS technology. Precisely manufactured, the TITAN™ Probes include matched 50 Ohm MEMS contact tips with improved probe electrical characteristics which allow the realization of unmat -ched calibration results over a wide frequency range. The patented protrusion tip design enables small passivation window bond pad probing, while significantly reducing probe skate thus providing the out -standing contact repeatability required in today’s extreme measurement environments. TITAN TM Probes with all their features are accompanied by a truly affordable price.The TITAN™ Probe series are available in single-ended and dual tip configurations, with pitch range from 50 micron to 1250 micron and frequencies from 26 GHz to 110 GHz. TITAN™ RF Probes are the ideal choice for on-wafer S-parameter measurements of RF, mm-wave devices and circuits up to 110 GHz as well as for the characterization of RF power devices requiring up to 10 Watts of continuous power. Finally, customers can benefit from both long product life and unbeatable cost of ownership which they have desired foryears.Unique design of the MEMS coplanar contacttip of the TITAN™ probe series.DC-needle-alike visibility of the contact point and the minimal paddamage due to the unique design of the tipAC2-2 Thru S11 Repeatability. Semi-Automated System.-100-80-60-40-200 S 11 E r r o r M a g n i t u d e (d B )Frequency (GHz)Another advantage of the TITAN™ probe is its superior contact repeatability, which is comparable with the entire system trace noise when measured on the semi-automated system and on gold contact pads.CROSSTALKCrosstalk of TITAN™ probes on the short and the bare ceramic open standard of 150 micron spacing compared to conventional 110 GHz probe technologies. Results are corrected by the multiline TRL calibration. All probes are of GSG configuration and 100 micron pitch.-80-60-40-200Crosstalk on Open. Multiline TRL Calibration.M a g (S21) (d B )Frequency (GHz)-80-60-40-200Crosstalk on Short. Multiline TRL Calibration.M a g (S21) (d B )Frequency (GHz)The maximal probe c ontac t repeatability error of the c alibrate S11-parameter of the AC2-2 thru standard by T110 probes. Semi-automated system. Ten contact circles.Cantilever needle material Ni alloy Body materialAl alloy Contact pressure @2 mils overtravel 20 g Lifetime, touchdowns> 1,000,000Ground and signal alignment error [1]± 3 µm [1]Planarity error [1] ± 3 µm [1]Contact footprint width < 30 µm Contact resistance on Au < 3 mΩThermal range-60 to 175 °CMechanical CharacteristicsAC2-2 Thru S21 Repeatability. Manual TS50 System.-100-80-60-40-200S 21 E r r o r M a g n i t u d e (d B )Frequency (GHz)MECHANICAL CHARACTERISTICSThe maximal probe c ontac t repeatability error of the c alibrate S21-parameter of the AC2-2 thru standard by T50 probes. Manual probe system TS50.26 GHZ PROBES FOR WIRELESS APPLICATIONSUnderstanding customer needs to reduce the cost of development and product testing for the high competitive wireless application market, MPI offers low-cost yet high-performance RF probes. The specifically developed SMA connector and its outstanding transmission of electro-magnetic waves through the probe design make these probes suitable for applications frequencies up to 26 GHz. The available pitch range is from 50 micron to 1250 micron with GS/SG and GSG probe tip configurations. TITAN™ 26 GHz probes are the ideal choice for measurement needs when developing components for WiFi, Bluetooth, and 3G/4G commercial wireless applications as well as for student education.Characteristic Impedance 50 ΩFrequency rangeDC to 26 GHz Insertion loss (GSG configuration)1< 0.4 dB Return loss (GSG configuration)1> 16 dB DC current ≤ 1 A DC voltage ≤ 100 V RF power, @10 GHz≤ 5 WTypical Electrical Characteristics26 GHz Probe Model: T26Connector SMAPitch range50 µm to 1250 µm Standard pitch step from 50 µm to 450 µm from 500 µm to 1250 µm25 µm step 50 µm stepAvailable for 90 µm pitch Tip configurations GSG, GS, SG Connector angleV-Style: 90-degree A-Style: 45-degreeMechanical CharacteristicsT26 probe, A-Style of the connectorTypical Electrical Characteristics: 26 GHz GSG probe, 250 micron pitchPROBES FOR DEVICE AND IC CHARACTERIZATION UP TO 110 GHZTITAN™ probes realize a unique combination of the micro-coaxial cable based probe technology and MEMS fabricated probe tip. A perfectly matched characteristic impedance of the coplanar probe tips and optimized signal transmission across the entire probe down to the pads of the device under test (DUT) result in excellent probe electrical characteristics. At the same time, the unique design of the probe tip provides minimal probe forward skate on any type of pad metallization material, therefo -re achieving accurate and repeatable measurement up to 110 GHz. TITAN™ probes are suitable for probing on small pads with long probe lifetime and low cost of ownership.The TITAN™ probe family contains dual probes for engineering and design debug of RF and mm-wave IC’s as well as high-end mm-wave range probes for S-parameter characterization up to 110 GHz for modeling of high-performance microwave devices.Characteristic Impedance 50 ΩFrequency rangeDC to 40 GHz Insertion loss (GSG configuration)1< 0.6 dB Return loss (GSG configuration)1> 18 dB DC current ≤ 1 A DC voltage ≤ 100 V RF power, @10 GHz≤ 5 WTypical Electrical Characteristics40 GHz Probe Model: T40Connector K (2.92 mm)Pitch range50 µm to 500 µmStandard pitch step For GSG configuration:from 50 µm to 450 µm from 500 µm to 800 µmFor GS/SG configuration:from 50 µm to 450 µm 25 µm step 50 µm stepAvailable for 90 µm pitch25 µm stepAvailable for 90/500 µm pitch Tip configurations GSG, GS, SG Connector angleV-Style: 90-degree A-Style: 45-degreeMechanical CharacteristicsTypical Electrical Characteristics: 40 GHz GSG probe, 150 micron pitchT40 probe, A-Style of the connectorCharacteristic Impedance50 ΩFrequency range DC to 50 GHz Insertion loss (GSG configuration)1< 0.6 dB Return loss (GSG configuration)1> 17 dBDC current≤ 1 ADC voltage≤ 100 VRF power, @10 GHz≤ 5 W Typical Electrical Characteristics Connector Q (2.4 mm)Pitch range50 µm to 250 µm Standard pitch stepFor GSG configuration: from 50 µm to 450 µm For GS/SG configuration: from 50 µm to 450 µm 25 µm stepAvailable for 90/500/550 µm pitch 25 µm stepAvailable for 90/500 µm pitchTip configurations GSG, GS, SG Connector angle V-Style: 90-degreeA-Style: 45-degreeMechanical CharacteristicsT50 probe, A-Style of the connectorTypical Electrical Characteristics: 50 GHz GSG probe, 150 micron pitchCharacteristic Impedance50 ΩFrequency range DC to 67 GHz Insertion loss (GSG configuration)1< 0.8 dB Return loss (GSG configuration)1> 16 dBDC current≤ 1 ADC voltage≤ 100 VRF power, @10 GHz≤ 5 W Typical Electrical Characteristics Connector V (1.85 mm)Pitch range50 µm to 250 µm Standard pitch stepFor GSG configuration: from 50 µm to 400 µm For GS/SG configuration: from 50 µm to 250 µm 25 µm step Available for 90 µm pitch25 µm step Available for 90 µm pitchTip configurations GSG Connector angle V-Style: 90-degreeA-Style: 45-degreeMechanical CharacteristicsT67 probe, A-Style of the connectorTypical Electrical Characteristics: 67 GHz GSG probe, 100 micron pitchCharacteristic Impedance 50 ΩFrequency rangeDC to 110 GHz Insertion loss (GSG configuration)1< 1.2 dB Return loss (GSG configuration)1> 14 dB DC current ≤ 1 A DC voltage ≤ 100 V RF power, @10 GHz≤ 5 WTypical Electrical CharacteristicsMechanical CharacteristicsTypical Electrical Characteristics: 110 GHz GSG probe, 100 micron pitchT110 probe, A-Style of the connectorCharacteristic impedance50 ΩFrequency range DC to 220 GHz Insertion loss (GSG configuration)1< 5 dB Connector end return loss(GSG configuration)1> 9 dBTip end return loss(GSG configuration)1> 13 dBDC current≤ 1.5 ADC voltage≤ 50 V Typical Electrical CharacteristicsConnector Broadband interface Pitch range50/75/90/100/125 µm Temperature range -40 ~ 150 ºC Contact width15 µmquadrant compatible(allowing corner pads)Yes recommended pad size20 µm x 20 µm recommended OT (overtravel)15 µmcontact resistance(on Al at 20 ºC using 15 µm OT)< 45 mΩlifetime touchdowns(on Al at 20 ºC using 15 µm OT)> 200,000Mechanical CharacteristicsT220 probe, broadband interface Typical Performance (at 20 ºC for 100 µm pitch)BODY DIMENSIONS PROBES Single-Ended V-StyleT220 GHz Probe1.161.1628.328437.455.6512.5527.73Single-Ended A-StyleCALIBRATION SUBSTRATESAC-series of calibration standard substrates offers up to 26 standard sets for wafer-level SOL T, LRM probe-tip cali -bration for GS/SG and GSG probes. Five coplanar lines provide the broadband reference multiline TRL calibration as well as accurate verification of conventional methods. Right-angled reciprocal elements are added to support the SOLR calibration of the system with the right-angled configuration of RF probes. A calibration substrate for wide-pitch probes is also available.Material Alumina Elements designCoplanarSupported calibration methods SOLT, LRM, SOLR, TRL and multiline TRL Thickness 635 µmSizeAC2-2 : 16.5 x 12.5 mm AC3 : 16.5 x 12.5 mm AC5 : 22.5 x 15 mm Effective velocity factor @20 GHz0.45Nominal line characteristic impedance @20 GHz 50 ΩNominal resistance of the load 50 ΩTypical load trimming accuracy error ± 0.3 %Open standardAu pads on substrate Calibration verification elements Yes Ruler scale 0 to 3 mm Ruler step size100 µmCalibration substrate AC2-2Probe Configuration GSGSupported probe pitch100 to 250 µm Number of SOL T standard groups 26Number of verification and calibration lines5Calibration substrate AC-3Probe Configuration GS/SG Supported probe pitch50 to 250 µm Number of SOL T standard groups 26Number of verification and calibration lines5Calibration substrate AC-5Probe Configuration GSG, GS/SG Supported probe pitch250 to 1250 µm Number of SOL T standard groups GSG : 7GS : 7SG : 7Open standardOn bare ceramic Number of verification and calibration linesGSG : 2GS : 1Typical characteristics of the coplanar line standard of AC2-2 calibration substrate measured using T110-GSG100 probes, and methods recommended by the National Institute of Standard and Technologies [2, 3].2468(d B /c m )F requency (G Hz)α-6-4-202I m a g (Z 0) ()F requency (G Hz)AC2-2 W#006 and T110A-GSG100Ω2.202.222.242.262.282.30 (u n i t l e s s )F requency (G Hz)β/βо4045505560R e a l (Z 0) ()F requency (G Hz)ΩTypical Electrical CharacteristicsMPI QAlibria® RF CALIBRATION SOFTWAREMPI QAlibria® RF calibration software has been designed to simplify complex and tedious RF system calibration tasks. By implementing a progressive disclosure methodology and realizing intuitive touch operation, QAlibria® provides crisp and clear guidance to the RF calibration process, minimizing con-figuration mistakes and helping to obtain accurate calibration results in fastest time. In addition, its concept of multiple GUI’s offers full access to all configuration settings and tweaks for advanced users. QAlibria® offers industry standard and advanced calibration methods. Furthermore, QAlibria® is integrated with the NIST StatistiCal™ calibration packages, ensuring easy access to the NIST mul-tiline TRL metrology-level calibration and uncertainty analysis.MPI Qalibria® supports a multi-language GUI, eliminating any evitable operation risks and inconvenience.SpecificationsRF AND MICROWAVE CABLESMPI offers an excellent selection of flexible cables and acces-sories for RF and mm-wave measurement applications forcomplete RF probe system integration.CablesHigh-quality cable assemblies with SMA and 3.5 mm connectorsprovide the best value for money, completing the entry-level RFsystems for measurement applications up to 26 GHz. Phase stab-le high-end flexible cable assemblies with high-precision 2.92, 2.4, 1.85 and 1 mm connectors guarantee high stability, accuracy and repeatability of the calibration and measurement for DC applications up to 110 GHz.MPI offers these cable assemblies in two standard lengths of 120 and 80 cm, matching the probe system’s footprint and the location of the VNA.Cables Ordering InformationMRC-18SMA-MF-80018 GHz SMA flex cable SMA (male) - SMA (female), 80 cmMRC-18SMA-MF-120018 GHz SMA flex cable SMA (male) - SMA (female), 120 cmMRC-26SMA-MF-80026 GHz SMA flex cable SMA (male) - SMA (female), 80 cmMRC-26SMA-MF-120026 GHz SMA flex cable SMA (male) - SMA (female), 120 cmMRC-40K-MF-80040 GHz flex cable 2.92 mm (K) connector, male-female, 80 cm longMRC-40K-MF-120040 GHz flex cable 2.92 mm (K) connector, male-female, 120 cm longMRC-50Q-MF-80050 GHz flex cable 2.4 mm (Q) connector, male-female , 80 cm longMRC-50Q-MF-120050 GHz flex cable 2.4 mm (Q) connector, male-female , 120 cm longMRC-67V-MF-80067 GHz flex cable 1.85 mm (V) connector, male-female, 80 cm longMRC-67V-MF-120067 GHz flex cable 1.85 mm (V) connector, male-female, 120 cm longMMC-40K-MF-80040 GHz precision flex cable 2.92 mm (K) connector, male-female, 80 cm long MMC-40K-MF-120040 GHz precision flex cable 2.92 mm (K) connector, male-female, 120 cm long MMC-50Q-MF-80050 GHz precision flex cable 2.4 mm (Q) connector, male-female , 80 cm long MMC-50Q-MF-120050 GHz precision flex cable 2.4 mm (Q) connector, male-female , 120 cm long MMC-67V-MF-80067 GHz precision flex cable 1.85 mm (V) connector, male-female, 80 cm long MMC-67V-MF-120067 GHz precision flex cable 1.85 mm (V) connector, male-female, 120 cm long MMC-110A-MF-250110 GHz precision flex cable 1 mm (A) connector, male-female, 25 cm longMPI Global PresenceDirect contact:Asia region: ****************************EMEA region: ******************************America region: ********************************MPI global presence: for your local support, please find the right contact here:/ast/support/local-support-worldwide© 2023 Copyright MPI Corporation. All rights reserved.[1] [2][3] REFERENCESParameter may vary depending upon tip configuration and pitch.R. B. Marks and D. F. Williams, "Characteristic impedance determination using propagation constant measu -rement," IEEE Microwave and Guided Wave Letters, vol. 1, pp. 141-143, June 1991.D. F. Williams and R. B. Marks, "Transmission line capacitance measurement," Microwave and Guided WaveLetters, IEEE, vol. 1, pp. 243-245, 1991.AdaptersHigh-In addition, high-quality RF and high-end mm-wave range adapters are offered to address challenges ofregular system reconfiguration and integration with different type of test instrumentation. MRA-NM-350F RF 11 GHz adapter N(male) - 3.5 (male), straight MRA-NM-350M RF 11 GHz adapter N(male) - 3.5 (female), straightMPA-350M-350F Precision 26 GHz adapter 3.5 mm (male) - 3.5 mm (female), straight MPA-350F-350F Precision 26 GHz adapter 3.5 mm (female) - 3.5 mm (female), straight MPA-350M-350M Precision 26 GHz adapter 3.5 mm (male) - 3.5 mm (male), straight MPA-292M-240F Precision 40 GHz adapter 2.92 mm (male) - 2.4 mm (female), straight MPA-292F-240M Precision 40 GHz adapter 2.92 mm (female) - 2.4 mm (male), straight MPA-292M-292F Precision 40 GHz adapter 2.92 mm (male) - 2.92 mm (female), straight MPA-292F-292F Precision 40 GHz adapter 2.92 mm (female) - 2.92 mm (female), straight MPA-292M-292M Precision 40 GHz adapter 2.92 mm (male) - 2.92 mm (male), straight MPA-240M-240F Precision 50 GHz adapter 2.4 mm (male) - 2.4 mm (female), straight MPA-240F-240F Precision 50 GHz adapter 2.4 mm (female) - 2.4 mm (female), straight MPA-240M-240M Precision 50 GHz adapter 2.4 mm (male) - 2.4 mm (male), straight MPA-185M-185F Precision 67 GHz adapter 1.85 mm (male) -1.85 mm (female), straight MPA-185F-185F Precision 67 GHz adapter 1.85 mm (female) -1.85 mm (female), straight MPA-185M-185M Precision 67 GHz adapter 1.85 mm (male) -1.85 mm (male), straight MPA-185M-100FPrecision 67 GHz adapter 1.85 mm (male) -1.00 mm (female), straightDisclaimer: TITAN Probe, QAlibria are trademarks of MPI Corporation, Taiwan. StatistiCal is a trademark of National Institute of Standards and Technology (NIST), USA. All other trademarks are the property of their respective owners. Data subject to change without notice.。

SIM900B_Hardware Design_V2.03Document Title SIM900B Hardware DesignVersion 2.03Date2013-03-25Status ReleaseDocument Control ID SIM900B_Hardware Design_V2.03General NotesSIMCom offers this information as a service to its customers, to support application and engineering efforts that use the products designed by SIMCom. The information provided is based upon requirements specifically provided to SIMCom by the customers. SIMCom has not undertaken any independent search for additional relevant information, including any information that may be in the customer’s possession. Furthermore, system validation of this product designed by SIMCom within a larger electronic system remains the responsibility of the customer or the customer’s system integrator. All specifications supplied herein are subject to change.CopyrightThis document contains proprietary technical information which is the property of SIMCom Limited, copying of this document and giving it to others and the using or communication of the contents thereof, are forbidden without express authority. Offenders are liable to the payment of damages. All rights reserved in the event of grant of a patent or the registration of a utility model or design. All specification supplied herein are subject to change without notice at any time.Copyright © Shanghai SIMCom Wireless Solutions Ltd. 2013ContentsContents (3)Version History (7)1Introduction (8)2SIM900B Overview (8)2.1 SIM900B Key Features (8)2.2 Operating Modes (10)2.3 SIM900B Functional Diagram (11)3Application Interface (12)3.1 Pin Description (12)3.2 Power Supply (14)3.2.1 Minimizing Voltage Drop of VBAT (15)3.2.2 Monitoring Power Supply (15)3.3 Power on/down Scenarios (15)3.3.1 Power on SIM900B (15)3.3.1.1Turn on SIM900B Using the PWRKEY Pin (Power on) (15)3.3.2 Power down SIM900B (16)3.3.2.1Power down SIM900B by the PWRKEY Pin (17)3.3.2.2Power down of SIM900B by AT Command (17)3.3.2.3Over-voltage or Under-voltage Power down (17)3.3.2.4Over-temperature or Under-temperature Power down (18)3.3.3 Restart SIM900B by PWRKEY Pin (18)3.4 Power Saving Mode (19)3.4.1 Minimum Functionality Mode (19)3.4.2 Sleep Mode 1 (AT+CSCLK=1) (19)3.4.3 Wake Up SIM900B from Sleep Mode 1 (AT+CSCLK=1) (19)3.4.4 Sleep Mode 2 (AT+CSCLK=2) (20)3.4.5 Wake Up SIM900B from Sleep Mode 2 (AT+CSCLK=2) (20)3.5 RTC Backup (20)3.6 Serial Interfaces (21)3.6.1 Function of Serial Port and Debug Port (22)3.6.2 Software Upgrade and Debug (23)3.7 Audio Interfaces (23)3.7.1 Speaker Interface Configuration (24)3.7.2 Microphone Interfaces Configuration (25)3.7.3 Earphone Interface Configuration (25)3.7.4 Audio Electronic Characteristics (25)3.8 SIM Card Interface (26)3.8.1 SIM Card Application (26)3.8.2 Design Considerations for SIM Card Holder (27)3.9 LCD Display/SPI Interface (29)3.10 ADC (30)3.11 RI Behaviors (30)3.12 Network Status Indication (31)3.13 General Purpose Input/Output (GPIO) (32)3.14 Keypad Interface (32)3.15 Buzzer (33)3.16 Antenna Interface (33)4Electrical, Reliability and Radio Characteristics (35)4.1 Absolute Maximum Ratings (35)4.2 Recommended Operating Conditions (35)4.3 Digital Interface Characteristics (35)4.4 SIM Card Interface Characteristics (35)4.5 SIM_VDD Characteristics (36)4.6 VRTC Characteristics (36)4.7 Current Consumption (VBAT = 3.8V) (36)4.8 Electro-Static Discharge (37)4.9 Radio Characteristics (38)4.9.1 Module RF Output Power (38)4.9.2 Module RF Receive Sensitivity (39)4.9.3 Module Operating Frequencies (40)5Manufacturing (41)5.1 Mechanical Dimensions of SIM900B (41)5.2 Mounting SIM900B onto the application platform (42)5.3 Board-to-board connector (42)5.4 Mechanical dimensions of the LIQIANG BB530-06001-20R (43)5.5 RF connector (44)5.6 Top and Bottom View of the SIM900B (45)5.7 PIN Assignment of SIM900B (46)Appendix (47)A. Related Documents (47)B. Terms and Abbreviations (48)C. Safety Caution (49)Table 2: Coding schemes and maximum net data rates over air interface (10)Table 3: Overview of operating modes (10)Table 4: Pin description (12)Table 5:The Current consumption of Minimum Functionality Mode (19)Table 6: Microphone Input Characteristics (26)Table 7: Audio Output Characteristics (26)Table 8: Pin description (Amphenol SIM card holder) (28)Table 9: Pin description (Molex SIM card holder) (29)Table 10: ADC specification (30)Table 11: RI Behaviors (30)Table 12: Status of the NETLIGHT pin (31)Table 13: Pin definition of the keypad interface (32)Table 14: Absolute maximum ratings (35)Table 15: Recommended operating conditions (35)Table 16: Digital interface characteristics (35)Table 17: SIM card interface characteristics (35)Table 18: SIM_VDD characteristics (36)Table 19: VRTC characteristics (36)Table 20: Current consumption (36)Table 21: The ESD characteristics (Temperature: 25℃, Humidity: 45 %) (37)Table 22: SIM900B GSM 900 and GSM 850 conducted RF output power (38)Table 23: SIM900B DCS 1800 and PCS 1900 conducted RF output power (38)Table 24: SIM900B conducted RF receive sensitivity (39)Table 25: SIM900B operating frequencies (40)Table 26: PIN assignment (46)Table 27: Related documents (47)Table 28: Terms and Abbreviations (48)Table 29: Safety caution (49)Figure 2: Reference circuit of the LDO power supply (14)Figure 3: Reference circuit of the DC-DC power supply (14)Figure 4: VBAT voltage drop during transmit burst (15)Figure 5: The minimal VBAT voltage requirement at VBAT drop (15)Figure 6: Powered on/down module using transistor (15)Figure 7: Powered on/down module using button (16)Figure 8: Timing of power on module (16)Figure 9: Timing of power down SIM900B by PWRKEY (17)Figure 10: Timing of restart SIM900B (18)Figure 11: RTC supply from capacitor (20)Figure 12: RTC supply from non-chargeable battery (21)Figure 13: RTC supply from rechargeable battery (21)Figure 14: Seiko XH414H-IV01E Charge-Discharge Characteristic (21)Figure 15: Connection of the serial interfaces (22)Figure 16: Connection of RXD and TXD only (22)Figure 17: Connection for software upgrading and debugging (23)Figure 18: Speaker reference circuit (24)Figure 19: Speaker with amplifier reference circuit (24)Figure 20: Microphone reference circuit (25)Figure 21: Earphone reference circuit (25)Figure 22: Reference circuit of the 8-pin SIM card holder (27)Figure 23: Reference circuit of the 6-pin SIM card holder (27)Figure 24: Amphenol C707 10M006 5122 SIM card holder (28)Figure 25: Molex 91228 SIM card holder (29)Figure 26: RI behaviour of voice calling as a receiver (30)Figure 27: RI behaviour of data calling as a receiver (31)Figure 28: RI behaviour of URC or receive SMS (31)Figure 29: RI behaviour as a caller (31)Figure 30: Reference circuit of NETLIGHT (32)Figure 31: Reference circuit of the keypad interface (33)Figure 32 : The RF interface of module (34)Figure 33: Top an Side Mechanical dimensions of module （Unit: mm） (41)Figure 34: Recommended PCB footprint outline（Unit: mm） (42)Figure 35: BB530-06001-20R board-to-board connector (43)Figure 36 : Board-to-board connector physical photo (43)Figure 37: U.FL-R-SMT (44)Figure 38: U.FL series RF adapter cable (44)Figure 39: Top view of the SIM900B (45)Figure 40: Bottom view of the SIM900B (45)Smart Machine Smart Decision Version History DateVersion Description of change Author 2010-04-081.01 Origin Huangqiuju 2010-05-311.02 Modify voltage domain ，current consumption and figure37 Huangqiuju 2010-06-23 1.03 §2.1, §3.3. §3.4 Modify the power supply range from3.2V~4.8V to 3.1V~4.8V§3.7, Modify the VRTC pin connection when RTCbackup is not needed. Huangqiuju2010-08-19 1.04 Modify the power supply range to 3.2v~4.8v.§3.3.2 Add Figure 6:The minimal VBAT voltage atVBAT drop.§3.4 Modify figure 7.§3.4 Add table 7.§3.5 Add 3.5.4 and 3.5.5 description.Delete chapter 3.6.Add figure 29,figure 30,figure 31,figure 32Modified figure 39 and B2B connector’s manufactureHuangqiuju 2011-02-09 2.00 Arrange the structure of document.Huangqiuju 2012-05-07 2.01 Add illustration of SIM900 module information andsome notes in chapter 5.Juntao.zhao 2012-05-07 2.01 Add some notes in chapter 4.Juntao.zhao 2012-08-06 2.02 Modified figure 39 and B2B connector’s manufactureSunshengwu 2012-03-25 2.03Add §3.16 Lili.teng1IntroductionThis document describes SIM900B hardware interface in great detail.This document can help user to quickly understand SIM900B interface specifications, electrical and mechanical details. With the help of this document and other SIM900B application notes, user guide, users can use SIM900B to design various applications quickly.2SIM900B OverviewDesigned for global market, SIM900B is a quad-band GSM/GPRS module that works on frequencies GSM850MHz, EGSM 900MHz, DCS 1800MHz and PCS 1900MHz. SIM900B features GPRS multi-slot class 10/ class 8 (optional) and supports the GPRS coding schemes CS-1, CS-2, CS-3 and CS-4.With a tiny configuration of 40mm*33mm *3mm, SIM900B can meet almost all the space requirements in user applications, such as M2M, smart phone, PDA, FWP, and other mobile devices.The physical interface to the mobile application is a 60-pin board-to-board connector, which provides all hardware interfaces between the module and customers’ boards except the RF antenna interface.z Serial port and Debug port can help user easily develop the applications.z Two audio channels include two microphone inputs and two speaker outputs.z Programmable general purpose input and output.z The keypad and SPI display interface will give user the flexibility to develop customized applications.SIM900B integrates TCP/IP protocol and extended TCP/IP AT commands which are very useful for data transfer applications. For details about TCP/IP applications, please refer to document [2].2.1SIM900B Key FeaturesTable 1: SIM900B key featuresFeature ImplementationPower supply 3.2V ~ 4.8VPower saving Typical power consumption in sleep mode is 1.0mA ( BS-PA-MFRMS=9 )Frequency bands z SIM900B Quad-band: GSM 850, EGSM 900, DCS 1800, PCS 1900.SIM900B can search the 4 frequency bands automatically. The frequency bands also can be set by AT command “AT+CBAND”. For details, please refer to document [1].z Compliant to GSM Phase 2/2+Transmitting power z Class 4 (2W) at GSM 850 and EGSM 900 z Class 1 (1W) at DCS 1800 and PCS 1900GPRS connectivity z GPRS multi-slot class 10（default）z GPRS multi-slot class 8 (option)Temperature range z Normal operation:-30°C ~ +80°Cz Restricted operation: -40°C ~ -30°C and +80 °C ~ +85°C *z Storage temperature -45°C ~ +90°CData GPRSzGPRS data downlink transfer: max. 85.6 kbps zGPRS data uplink transfer: max. 42.8 kbps zCoding scheme: CS-1, CS-2, CS-3 and CS-4 zIntegrate the TCP/IP protocol. z Support Packet Broadcast Control Channel (PBCCH) CSDz Support CSD transmission USSDz Unstructured Supplementary Services Data (USSD) support SMSz MT, MO, CB, Text and PDU mode z SMS storage: SIM card FAXGroup 3 Class 1 SIM interfaceSupport SIM card: 1.8V, 3V External antenna Antenna padAudio features Speech codec modes:z Half Rate (ETS 06.20)z Full Rate (ETS 06.10)z Enhanced Full Rate (ETS 06.50 / 06.60 / 06.80)z Adaptive multi rate (AMR)z Echo Cancellationz Noise SuppressionSerial port and debug portSerial port: zFull modem interface with status and control lines, unbalanced, asynchronous. z1200bps to 115200bps. zCan be used for AT commands or data stream. zSupport RTS/CTS hardware handshake and software ON/OFF flow control. zMultiplex ability according to GSM 07.10 Multiplexer Protocol. zAutobauding supports baud rate from 1200 bps to 57600bps. Debug port: zNull modem interface DBG_TXD and DBG_RXD. z Can be used for debugging and upgrading firmware. Phonebook managementSupport phonebook types: SM, FD, LD, RC, ON, MC. SIM application toolkitGSM 11.14 Release 99 Real time clockSupport RTC Physical characteristicsSize: 40mm * 33mm*3mm Weight: 7g Firmware upgradeFirmware upgradeable by debug port. *SIM900B does work at this temperature, but some radio frequency characteristics may deviate from the GSM specification.Table 2: Coding schemes and maximum net data rates over air interface Coding scheme1 timeslot2 timeslot 4 timeslot CS-19.05kbps 18.1kbps 36.2kbps CS-213.4kbps 26.8kbps 53.6kbps CS-315.6kbps 31.2kbps 62.4kbps CS-4 21.4kbps 42.8kbps 85.6kbps2.2 Operating ModesThe table below summarizes the various operating modes of SIM900B.Table 3: Overview of operating modes Mode FunctionGSM/GPRS SLEEP Module will automatically go into sleep mode if the conditions of sleepmode are enabling and there is no on air and no hardware interrupt (such asGPIO interrupt or data on serial port).In this case, the current consumption of module will reduce to the minimallevel.In sleep mode, the module can still receive paging message and SMS.GSM IDLE Software is active. Module registered to the GSM network, and the moduleis ready to communicate.GSM TALK Connection between two subscribers is in progress. In this case, the powerconsumption depends on network settings such as DTX off/on,FR/EFR/HR, hopping sequences, antenna.GPRS STANDBY Module is ready for GPRS data transfer, but no data is currently sent orreceived. In this case, power consumption depends on network settings andGPRS configuration.Normal operation GPRS DATAThere is GPRS data transfer (PPP or TCP or UDP) in progress. In this case,power consumption is related with network settings (e.g. power controllevel); uplink/downlink data rates and GPRS configuration (e.g. usedmulti-slot settings). Power down Normal power down by sending the AT command “AT+CPOWD=1” or using the PWRKEY. The power management unit shuts down the power supply for the baseband part of themodule, and only the power supply for the RTC is remained. Software is not active. Theserial port is not accessible. Power supply (connected to VBAT) remains applied.Minimum functionality modeAT command “AT+CFUN” can be used to set the module to a minimum functionality modewithout removing the power supply. In this mode, the RF part of the module will not work orthe SIM card will not be accessible, or both RF part and SIM card will be closed, and theserial port is still accessible. The power consumption in this mode is lower than normalmode.2.3 SIM900B Functional DiagramThe following figure shows a functional diagram of SIM900B: z The GSM baseband engine z Flash and SRAMz The GSM radio frequency part z The antenna interfacez The board-to-board interface z The Other interfacesBaseband EngineLCD KEYPADSSIM POWERBoard-to-board ConnectorFigure 1: SIM900B functional diagram3Application Interface3.1Pin DescriptionTable 4: Pin descriptionPin name Pin number I/O Description CommentPower supplyVBAT 1,2,3,4,5,6,7,8 I Power supplyVRTC 15 I/O Power supply for RTCIt is recommended toconnect with a battery ora capacitor (e.g. 4.7uF).VDD_EXT 17 O 2.8V output power supply If it is unused, keep open.AGND 50，51 Analog groundSeparate groundconnection for externalaudio circuits. If unusedconnect to GNDdirectory.GND9,10,11,12,13,14GroundPower on/downPWRKEY 34 IPWRKEY should be pulled low at least1 second and then released to poweron/down the module.VILmax=0.9VVIHmin=2.6VVImax=3.3VVILmin= 0VIt has been pulled upinternally (3V).Audio interfacesMIC1P 53MIC1N 55I Differential audio inputSPK1P 54SPK1N 56O Differential audio outputMIC2P 57MIC2N 59I Differential audio inputSPK2P 58SPK2N 60O Differential audio outputIf these pins are unused,keep open.StatusNETLIGHT 30 O Network statusLCD interfaceDISP _CLK 20 ODISP_DATA 18 I/ODISP _D/C 24 ODisplay interface If these pins are unused,keep open.DISP _CS 22 ODISP_RST 26 OKeypad interface / GPIOsGPIO1/KBC4 35 I/OGPIO2/KBC3 33 I/OGPIO3/KBC2 31 I/OGPIO4/KBC1 29 I/OGPIO6/KBR3 45 I/OGPIO7/KBR4 43 I/OGPIO8/KBR2 41 I/OGPIO9/KBR1 39 I/ODefaults are as GPIO, they can bemultiplexed as keypadIf these pins areunused ,keep openGPIO5/KBC027GPIO10/KBR0 37I/OGPIOJust can be used asGPIO, if these pins areunused, keep openSerial portRXD 40 I Receive data This pin should bepulled up to 3Vexternally.TXD42 O Transmit dataRTS44 I Request to sendCTS 46 O Clear to sendRI 48 O Ring indicatorDCD 28 O Data carry detectDTR 38 I Data terminal ReadyIf these pins are unused,keep open.Debug interfaceDBG_TXD 49 ODBG_RXD 47 ISerial interface for debugging andfirmware upgradeIf these pins are unused,keep open.SIM interfaceSIM_VDD 19 O V oltage supply for SIM card. Support1.8V or 3V SIM cardSIM_DATA 21 I/O SIM data input/outputSIM_CLK 23 O SIM clockSIM_RST 25 O SIM resetSIM_PRESENCE16 I SIM card detectionAll signals of SIMinterface should beprotected against ESDwith a TVS diode array.If SIM_PRESENCE isunused, just keep open ADCADC0 52 I General purpose analog to digitalconverter. Input voltage range: 0V ~2.8VIf it is unused ,keep openPulse Width ModulationBUZZER 36 O PWM Output If it is unused, keep openSmart Machine Smart Decision3.2 Power SupplyThe power supply range of SIM900B is from 3.2V to 4.8V. The transmitting burst will cause voltage drop and the power supply must be able to provide sufficient current up to 2A. For the VBAT input, a bypass capacitor (low ESR) such as a 100 µF is strongly recommended; this capacitor should be placed as close as possible to SIM900B VBAT pins. The following figure is the reference design of +5V input power supply. The designed output for the power supply is 4.1V, thus a linear regulator can be used.G N DFigure 2: Reference circuit of the LDO power supplyIf there is a high drop-out between the input and the desired output (VBAT), a DC-DC power supply will be preferable because of its better efficiency especially with the 2A peak current in burst mode of the module. The following figure is the reference circuit.Figure 3: Reference circuit of the DC-DC power supplyThe single 3.6V Li-ion cell battery can be connected to SIM900B VBAT pins directly. But the Ni-Cd or Ni-MH battery must be used carefully, since their maximum voltage can rise over the absolute maximum voltage of the module and damage it.When battery is used, the total impedance between battery and VBAT pins should be less than 150m Ω.The following figure shows the VBAT voltage drop at the maximum power transmit phase, and the test condition is as following:VBAT=4.0V,A VBAT bypass capacitor C A =100µF tantalum capacitor (ESR=0.7Ω), Another VBAT bypass capacitor CB =1µF.Figure 4: VBAT voltage drop during transmit burst3.2.1Minimizing Voltage Drop of VBATWhen designing the power supply in user’s application, pay special attention to power losses. Ensure that the input voltage never drops below 3.1V even when current consumption rises to 2A in the transmit burst. If thepower voltage drops below 3.1V , the module may be shut down automatically. The PCB traces from the VBAT pins to the power supply must be wide enough (at least 60mil) to decrease voltage drops in the transmit burst. The power IC and the bypass capacitor should be placed to the module as close as possible.Figure 5: The minimal VBAT voltage requirement at VBAT drop3.2.2Monitoring Power SupplyThe AT command “AT+CBC” can be used to monitor the VBAT voltage. For detail, please refer todocument [1].3.3 Power on/down Scenarios3.3.1 Power on SIM900B3.3.1.1Turn on SIM900B Using the PWRKEY Pin (Power on)User can power on SIM900B by pulling down the PWRKEY pin for at least 1 second and release. This pin is already pulled up to 3V in the module internal, so external pull up is not necessary. Reference circuit is shown as below.Figure 6: Powered on/down module using transistorFigure 7: Powered on/down module using buttonThe power on scenarios is illustrated as following figure.> 2.55VVBAT PWRKEY (INPUT)Delay > 2.2sVDD_EXTSerial PortUndefinedFigure 8: Timing of power on moduleWhen power on procedure is completed, SIM900B will send following URC to indicate that the module is ready to operate at fixed baud rate. RDYThis URC does not appear when autobauding function is active.Note: User can use AT command “AT+IPR=x” to set a fixed baud rate and save the configuration to non-volatile flash memory. After the configuration is saved as fixed baud rate, the Code “RDY” should be received from the serial port every time when SIM900B is powered on. For details, please refer to the chapter “AT+IPR” in document [1].3.3.2 Power down SIM900BSIM900B will be powered down in the following situations ：z Normal power down procedure: power down SIM900B by the PWRKEY pin.z Normal power down procedure: power down SIM900B by AT command “AT+CPOWD=1”. z Abnormal power down: over-voltage or under-voltage automatic power down.z Abnormal power down: over-temperature or under-temperature automatic power down.3.3.2.1 Power down SIM900B by the PWRKEY PinUser can power down SIM900B by pulling down the PWRKEY pin for at least 1 second and release. Please refer to the power on circuit. The power down scenario is illustrated in the following figure.VDD_EXT （OUTPUT PWRKEY (INPUT)Figure 9: Timing of power down SIM900B by PWRKEYThis procedure makes the module log off from the network and allows the software to enter into a secure state to save data before completely shut down.Before the completion of the power down procedure, the module will send URC:NORMAL POWER DOWNAt this moment, AT commands can not be executed any more, and only the RTC is still active. Power down mode can also be indicated by STATUS pin, which is at low level at this time. 3.3.2.2Power down of SIM900B by AT CommandSIM900B can be powered down by AT command “AT+CPOWD=1”. This procedure makes the module log off from the network and allows the software to enter into a secure state to save data before completely shut down.Before the completion of the power down procedure, the module will send URC:NORMAL POWER DOWNAt this moment, AT commands can not be executed any more, and only the RTC is still active. Power down mode can also be indicated by STATUS pin, which is at low level at this time.For detail about the AT command “AT+CPOWD”, please refer to document [1] 3.3.2.3Over-voltage or Under-voltage Power downThe module software monitors the VBAT voltage constantly. If the voltage ≤ 3.3V , the following URC will be reported: UNDER-VOLTAGE WARNNINGIf the voltage ≥ 4.7V , the following URC will be reported: OVER-VOLTAGE WARNNINGIf the voltage < 3.2V , the following URC will be reported, and the module will be automatically powered down.UNDER-VOLTAGE POWER DOWNIf the voltage > 4.8V, the following URC will be reported, and the module will be automatically powered down.OVER-VOLTAGE POWER DOWNAt this moment, AT commands can not be executed any more, and only the RTC is still active. Power down mode can also be indicated by STATUS pin, which is at low level at this time.3.3.2.4Over-temperature or Under-temperature Power downThe module will constantly monitor the temperature of the module,If the temperature > +80℃, the following URC will be reported:+CMTE: 1If the temperature < -30℃, the following URC will be reported:+CMTE:-1If the temperature > +85℃, the following URC will be reported, and the module will be automatically powered down.+CMTE: 2If the temperature <-40℃, the following URC will be reported, and the module will be automatically powered down.+CMTE:-2At this moment, AT commands can not be executed any more, and only the RTC is still active. Power down mode can also be indicated by STATUS pin, which is at low level at this time.The AT command “AT+CMTE” could be used to read the temperature when the module is running.For details please refer to document [1].3.3.3Restart SIM900B by PWRKEY PinWhen the module works normally, if the user wants to restart the module, follow the procedure below:1)Power down the module.2)Wait for at least 800mS after STATUS pin changed to low level.3)Power on the module.VDD_EXT（OUTPUTPWRKEY（INPUT）Figure 10: Timing of restart SIM900B3.4Power Saving ModeSIM900B has two sleep modes: sleep mode 1 is enabled by hardware pin DTR; sleep mode 2 is only enabled by serial port regardless of the DTR. In sleep mode, the current consumption of the module is very low. The AT command “AT+CFUN=<fun>” can be used to set SIM900B into minimum functionality. When SIM900B is in sleep mode and minimum functionality, the current of module is the lowest.3.4.1Minimum Functionality ModeThere are three functionality modes, which could be set by the AT command “AT+CFUN=<fun>”. The command provides the choice of the functionality levels <fun>=0,1,4.z0: minimum functionality.z1: full functionality (default).z4: flight mode (disable RF function).Minimum functionality mode minimizes the current consumption to the lowest level. If SIM900B is set to minimum functionality by “AT+CFUN=0”, the RF function and SIM card function will be disabled. In this case, the serial port is still accessible, but all AT commands correlative with RF function and SIM card function will not be accessible.For detailed information about the AT Command “AT+CFUN=<fun>”, please refer to document [1].Table 5:The Current consumption of Minimum Functionality Mode<fun> Current consumption(uA) (sleep mode)0 6511 10004 7153.4.2Sleep Mode 1 (AT+CSCLK=1)User can control SIM900B module to enter or exit the sleep mode 1 (AT+CSCLK=1) by DTR signal. When DTR is in high level and without interrupt (on air and hardware such as GPIO interrupt or data in serial port), SIM900B will enter sleep mode 1 automatically. In this mode, SIM900B can still receive paging or SMS from network but the serial port is not accessible.Note: For SIM900B, it is requested to set AT command “AT+CSCLK=1” and to ensure DTR at high level to enable the sleep mode 1; the default value is 0, which can not make the module to go into sleep mode. For more details please refer to document [1].3.4.3Wake Up SIM900B from Sleep Mode 1 (AT+CSCLK=1)When SIM900B is in sleep mode 1 (AT+CSCLK=1), the following methods can wake up the module:z Pull down DTR pin.The serial port will be active after DTR pin is pulled to low level for about 50ms.z Receive a voice or data call from network. z Receive a SMS from network. 3.4.4Sleep Mode 2 (AT+CSCLK=2)In this mode, SIM900B will continuously monitor the serial port data signal. When there is no data transfer over 5 seconds on the RXD signal and there is no on air and hardware interrupts (such as GPIO interrupt), SIM900B will enter sleep mode 2 automatically. In this mode, SIM900B can still receive paging or SMS from network but the serial port is not accessible.Note: For SIM900B, It is requested to set AT command “AT+CSCLK=2” to enable the sleep mode 2; the default value is 0, which can not make the module to enter sleep mode. For more details please refer to document [1].3.4.5 Wake Up SIM900B from Sleep Mode 2 (AT+CSCLK=2)When SIM900B is in sleep mode 2 (AT+CSCLK=2), the following methods can wake up the module: z Send data to SIM900B via main serial port. *z Receive a voice or data call from network.z Receive a SMS from network.Note: The first byte of the user’s data will not be recognized.3.5 RTC BackupCurrent input for RTC when the VBAT is not supplied for the system. Current output for backup battery when the VBAT power supply is in present and the backup battery is in low voltage state. The RTC power supply of the module can be provided by an external capacitor or a battery (non-chargeable or rechargeable) through the VRTC. The following figures show various reference circuits for RTC back up.z External capacitor backupFigure 11: RTC supply from capacitorz Non-chargeable battery backup。

EFM8 Laser BeeEFM8LB1 ErrataThis document contains information on the EFM8LB1 errata. The latest available revision of this device is revision C. Note that revi-sion C devices omit the crystal oscillator. Applications requiring a crystal should specify a revision B part number.Errata that have been resolved remain documented and can be referenced for previous revisions of this device.The device data sheet explains how to identify the chip revision, either from the package marking or electronically.Errata effective date: November, 2022.Errata Summary 1. Errata SummaryThe table below lists all known errata for the EFM8LB1 and all unresolved errata of the EFM8LB1.Table 1.1. Errata Overview2. Current Errata Descriptions2.1 DAC_E101 – DAC1 and DAC3 outputs are not updated2.2 TEMP_E102 – Inaccurate Temperature Sensor Calibration2.3 TIMER_E102 – High Byte Overflow Flag and Low Byte Overflow Flag are not cleared2.4 UART1_E101 – Some Data Patterns Cause Inadvertent LIN Break Detection2.7 XOSC_E101 – Crystal Mode in External Oscillator Not Available3. Resolved Errata DescriptionsThis section contains previous errata for EFM8LB1 devices. Note that revision C devices omit the crystal oscillator. Applications requir-ing a crystal should specify a revision B part number.For errata on the latest revision, refer to the beginning of this document. The device data sheet explains how to identify chip revision, either from package marking or electronically.3.1 CLU_E101 – CLU Wake-Up Sources are Level Triggered3.2 I2CSLAVE_E101 – I2CSLAVE0 Cannot Distinguish Between Multiple Addresses3.3 PKG_E101 – Top Marking Right JustifiedEFM8EFM8 3.4 PKG_E102 – Devices Marked as G Grade3.5 POR_E102 – P0.3 Drives Low During Startup3.6 RST_E101 – VREF/P0.0 Not Retained through Power-On Reset3.7 TEST_E101 – Devices Tested to 85 °CResolved Errata Descriptions 3.8 TIMER_E101 – Timer 3/4 Chaining Mode in Suspend3.9 XOSC_E102 – External Oscillator XFCN = 111 Setting Unavailable when XOSCMD = CMOS_DIV_2 | Building a more connected world.Rev. 1.2 | 114. Revision HistoryRevision 1.2November, 2022•Corrected affected revisions for POR_E102, UART1_E101, and XOSC_E101.•Added DAC_E101, TEMP_E102, TIMER_E102 and XOSC_E102.•Migrated to new errata document format.Revision 1.1May, 2019•Added UART1_E101.•Updated XOSC_E101 to reflect that only revision B is fixed. The crystal oscillator is not present on revision C.Revision 1.0December, 2018•Updated latest revision to C.•Table 1.1 Errata Overview on page 2 now reflects the presence of POR_E102 on revision A devices.•Moved POR_E102 from the errata to the errata history and changed XTAL2 pin reference to EXTOSC in order to conform with revi-sion C documentation.Revision 0.9November, 2018•Added WDT_E102.Revision 0.8August, 2018•Merged errata history and errata into one document.•Updated the second workaround in WDT_E101.•Updated Knowledge Base article link in WDT_E101.•Added POR_E102.Revision 0.7September, 2016•Added WDT_E101.Revision 0.6February, 2016•Updated latest revision to B.•Moved CLU_E101, I2CSLAVE_E101, PKG_E101, RST_E101, TIMER_E101, and XOSC_E101 from the errata to the errata history. Revision 0.5January, 2016•Updated the affected revision date codes for PKG_E102.Revision 0.4November, 2015•Added PKG_E102 and TEST_E101.Revision 0.3October, 2015•Updated RST_E101, TIMER_E101, and XOSC_E101 with errata designators.•Added CLU_E101, I2CSLAVE_E101, and PKG_E101.Revision 0.1June, 2015•Initial release.Silicon Laboratories Inc.400 West Cesar Chavez Austin, TX 78701USA IoT Portfolio /IoT SW/HW /simplicity Quality /quality Support & Community /communityDisclaimerSilicon Labs intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software imple-menters using or intending to use the Silicon Labs products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and “Typical” parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Labs reserves the right to make changes without further notice to the product information, specifications, and descriptions herein, and does not give warranties as to the accuracy or completeness of the included information. Without prior notification, Silicon Labs may update product firmware during the manufacturing process for security or reliability reasons. Such changes will not alter the specifications or the performance of the product. Silicon Labs shall have no liability for the consequences of use of the infor -mation supplied in this document. This document does not imply or expressly grant any license to design or fabricate any integrated circuits. The products are not designed or authorized to be used within any FDA Class III devices, applications for which FDA premarket approval is required or Life Support Systems without the specific written consent of Silicon Labs. A “Life Support System” is any product or system intended to support or sustain life and/or health, which, if it fails, can be reasonably expected to result in significant personal injury or death. Silicon Labs products are not designed or authorized for military applications. Silicon Labs products shall under no circumstances be used in weapons of mass destruction including (but not limited to) nuclear, biological or chemical weapons, or missiles capable of delivering such weapons. Silicon Labs disclaims all express and implied warranties and shall not be responsible or liable for any injuries or damages related to use of a Silicon Labs product in such unauthorized applications. Note: This content may contain offensive terminology that is now obsolete. Silicon Labs is replacing these terms with inclusive language wherever possible. For more information, visit /about-us/inclusive-lexicon-projectTrademark InformationSilicon Laboratories Inc.®, Silicon Laboratories ®, Silicon Labs ®, SiLabs ® and the Silicon Labs logo ®, Bluegiga ®, Bluegiga Logo ®, EFM ®, EFM32®, EFR, Ember ®, Energy Micro, Energy Micro logo and combinations thereof, “the world’s most energy friendly microcontrollers”, Redpine Signals ®, WiSeConnect , n-Link, ThreadArch ®, EZLink ®, EZRadio ®, EZRadioPRO ®, Gecko ®, Gecko OS, Gecko OS Studio, Precision32®, Simplicity Studio ®, Telegesis, the Telegesis Logo ®, USBXpress ® , Zentri, the Zentri logo and Zentri DMS, Z-Wave ®, and others are trademarks or registered trademarks of Silicon Labs. ARM, CORTEX, Cortex-M3 and THUMB are trademarks or registered trademarks of ARM Holdings. Keil is a registered trademark of ARM Limited. Wi-Fi is a registered trademark of the Wi-Fi Alliance. All other products or brand names mentioned herein are trademarks of their respective holders.。

SIM800/SIM800A模块用户手册Tzw-SIM800/SIM800A模块开发板是一款高性能高性价比工业级的GSM/GPRS 模块（开发板）。

本模块采用SIMCOM公司的工业级SIM800/SIM800A 芯片, 可以低功耗实现语音、SMS、数据和传真信息的传输。

注：SIM800支持4频，通俗讲就是可以全球使用，SIM800A支持双频，大陆使用。

1.1 主要参数模块支持TTL接口控制，可以方便的使用电脑或者单片机控制实现GSM/GPRS 功能。

TTL电平支持3.3v/5v系统。

模块DC接口外部输入工作电压 DC5-15v（能保证给SIM800提供 2A 电流（注1），因为兼容5V，所以可以用USB转TTL或者5V单片机系统直接供电（很多同行不行）。

注1：这里指的2A 是指经过模块板载DC-DC 变换后的4v电压，供给SIM800模块用的电流，不是指外部输入电源一定要2A，外部电压越高，需要的电流就越小。

比如12V 1A 的电源，按90%的效率计算，可以提供2.7A@4V 的电流，所以用12V 1A 的电源给YIXIN_SIM800模块供电是已经足够的。

综上所诉，使用DC9V以上使用1A的电源已经足够，如果使用DC9V以下电压的电源，请至少选择2A的电流参数。

这里讲的1A都是足A的，不能是劣质电源（劣质电源写的1A可能实际500mA都没），若电源不能保证质量很好足A，可以选择电流大一点的电源。

1.2 模块的接口介绍注2：VIN为模块的供电电压（如单片机/PC TXD RXD端口高电平是5V，可以直接用跳线帽与VMCU短接）宽电压供电：5~15V DC电源供电，灵活适应不同供电电压的系统，一般我们建议用5V。

VMCU为TXD RXD的端口高电平电压（单片机/PC T XD RXD端口高电平是5V的就接5V，是3.3V的就接3.3V）。

SIM卡座为小卡座，支持移动、联通，不支持电信。

2.1 PC调试按模块上的示意图插好卡后，我们选择用USB转TTL给模块做电脑调试。

使用SIM800A替换SIM900A 模块的注意事项---2015/11/12SIM800A 模块是SIMCOM 基于MT6261芯片平台设计的新一代GSM/GPRS SIM800A 模块介绍工业模块，该模块可以用于直接替换SIM900A 模块。

SIM800A 是一歀性价比更具有竞争力的GSM/GPRS 工业模块，提供了更多:的功能接口: 如可配置双串口，PCM 音频接口，以及USB 接口等，同时支持蓝牙功能。

经对比测试, SIM800A 在低功耗和抗静电干扰性能方面，较SIM900A 有更好的提升。

本文档主要提示“SIM900A ”和“SIM800A”的引脚接口差异：“SIM800A 硬件设计手册”更多SIM800A 的设计参数细节, 建议参与阅 SIM800A_硬件设计手册“SIM800 Series_AT Command Manual ”，以及更多相关系列的“SIM800A 模块应用手册”2SIM800A 与SIM900A 功能上的差异功能SIM800A SIM900A 蓝牙功能支持(特定版本)不支持PCM/SPI接口全都支持（可复用）只支持SPI中断功能部分GPIO可配置为中断所有GPIO都可配置为中断USB 接口支持不支持USB调试下载端口USB接口调试DEBUG_TXD/RXDCSD通讯功能不支持支持射频同步信号支持（GPIO11可复用）不支持注意：由于两模块平台不同，音频参数也不相同，需要另行调整。

详细请参考“SIM900ASIM800A音频调试文档”。

3SIM800A 与SIM900A 引脚定义上的差别引脚编号SIM800A SIM900A 2GND NC23KPLED NC24VBUS NC27USB_DP DBG_TXD28USB_DM DBG_RXD53[1]ANT_BT GND注[1]：SIM800A的蓝牙功能默认为关闭状态，可以直接替换SIM900A，即在模快的脚接地的情况下不可开启蓝牙否则损伤模块PIN53脚接地的情况下，不可开启蓝牙，否则损伤模块。

SIM800H_硬件设计手册_V1.00文档名称：SIM800H 硬件设计手册 版本：1.00 日期：2013-05-10 状态：草稿 文档控制号： SIM800H_硬件设计手册_V1.00前言感谢使用SIMCom 提供的SIM800H 系列模块。

本产品具有标准AT 命令接口，可以提供GSM 语音、短消息等业务。

使用前请仔细阅读用户手册，您将领略其完善的功能和简洁的操作方法。

此模块主要用于语音或者数据通讯，本公司不承担由于用户不正常操作造成的财产损失或者人身伤害责任。

请用户按照手册中的技术规格和参考设计开发相应的产品。

同时注意使用移动产品特别是GSM 产品应该关注的一般安全事项。

在未声明之前，本公司有权根据技术发展的需要对本手册内容进行修改。

版权声明本手册版权属于SIMCom ，任何人未经我公司书面同意复制、引用或者修改本手册都将承担法律责任 Copyright © Shanghai SIMCom Wireless Solutions Ltd. 2013。

目录1.绪论 (10)2.模块综述 (10)2.1. 模块主要特性 (10)2.2. 工作模式 (12)2.3. 模块功能框图 (13)3.模块封装 (14)3.1. 引脚分布图 (14)3.2. 模块引脚描述 (15)3.3. 机械尺寸 (18)4.接口应用 (20)4.1. 供电 (20)4.1.1. 电源引脚 (21)4.1.2. 电源监测 (22)4.2. 开机关机 (22)4.2.1. 模块开机 (22)4.2.2. 模块关机 (23)4.2.3. 模块复位 (25)4.3. 省电模式 (26)4.3.1. 最小功能模式 (26)4.3.2. 休眠模式 (27)4.3.3. 从休眠模式唤醒模块 (27)4.4. RTC电源 (27)4.5. 串口 (28)4.5.1. 调试接口 (30)4.5.2. 串口功能 (30)4.5.3. 软件升级 (31)4.6. RI电平状态 (32)4.7. 音频接口 (33)4.7.1. 受话器接口电路 (34)4.7.2. 麦克风接口电路 (34)4.7.3. 相关电气参数 (35)4.8. SIM卡接口 (35)4.8.1. SIM卡接口 (35)4.8.2. SIM 卡座的选择 (36)4.9. PCM接口 (38)4.9.1. 复用功能 (39)4.10. 键盘接口 (39)4.10.1. 键盘复用功能 (42)4.11. I2C总线 (42)4.11.1. I2C复用功能 (42)4.12. 通用输入输出接口(GPIO) (42)4.13. 模数转换器（ADC） (43)4.14. PWM (43)4.14.1. PWM复用功能 (44)4.15. 网络状态指示灯 (44)4.15.1. 复用功能 (45)4.16. 状态指示灯 (45)4.16.1. 状态指示灯复用功能 (45)4.17. LED 接口 (46)4.18. RF 发射同步信号 (46)4.19. 天线接口 (47)4.19.1. GSM 天线接口 (47)4.19.2. 蓝牙天线接口 (48)4.19.3. FM 天线接口 (49)5. 电气，可靠性和射频特性 (51)5.1 绝对最大值 (51)5.2 工作温度 (51)5.3 数字接口特性 (51)5.4 SIM 卡接口特性 (52)5.5 SIM_VDD 特性 (52)5.6 VDD_EXT 特性 (52)5.7 VRTC 特性 (52)5.8 耗流(VBAT=4.0V) (53)5.9 静电防护 (53)5.10 射频特性 (54)5.10.1. 模块传导射频输出功率 (54)5.10.2. 模块传导接收灵敏度 (55)5.10.3. 模块工作频段 (55)6. 生产 (56)6.1. 模块的顶视图和底视图 (56)6.2. 推荐焊接炉温曲线图 (56)7. 附录 (57)I. 相关文档 (57)II. 术语和解释 (58)III. 安全警告 (60)表格索引表1：模块主要特性 (10)表2：编码格式和最大网络数据速度率 (12)表3：工作模式 (12)表4：引脚描述 (15)表5：推荐的齐纳二极管型号 (20)表6： AT+CFUN不同设置下的耗流(BS-PA-MFRMS=5) (26)表7：串口引脚定义 (28)表8：串口逻辑电平 (29)表9：串口复用功能 (31)表10：RI信号线电平状态 (32)表 11：音频功放参数 (33)表 12：音频输入参数 (35)表 13：音频输出参数 (35)表14：SIM卡接口引脚定义 (35)表 15：引脚描述(AMPHENOL SIM卡座) (37)表 16：引脚描述(AMPHENOL SIM卡座) (38)表17：PCM接口引脚定义 (39)表 18： PCM复用功能： (39)表19：键盘接口引脚信号定义 (41)表 20： I2C总线接口引脚定义 (42)表 21： I2C复用功能 (42)表22：GPIO接口引脚定义 (43)表 23： ADC接口引脚定义 (43)表24：ADC参数 (43)表25：PWM引脚定义 (43)表26： BUZZER 输出特性 (44)表27：PWM复用功能 (44)表28：NETLIGHT引脚定义 (44)表29：NETLIGHT工作状态 (44)表30：NETLIGHT复用功能 (45)表31：STATUS引脚定义 (45)表32：STATUS复用功能 (45)表33：LED引脚定义 (46)表34：LED引脚参数 (46)表35：BPI_BUS1引脚定义 (47)表 36：绝对最大值 (51)表 37：模块工作温度 (51)表 38：数字接口特性 (51)表 39： SIM卡接口特性 (52)表 40： SIM_VDD 特性 (52)表 41： VDD_EXT特性 (52)表 42： VRTC特性 (52)表 43：耗流 (53)表 44： ESD 性能参数（温度：25℃，湿度：45%） (54)表 45： GSM850、EGSM900传导输出功率 (54)表 46： DCS1800、PCS1900传导输出功率 (54)表 47： 传导接收灵敏度 (55)表 48： 模块工作频段 (55)表 49： 相关文档 (57)表 50： 术语和解释 (58)表 51：安全警告 (60)图片索引图1：模块功能框图 (13)图2：模块引脚图(顶视图) (14)图3：三维尺寸（单位：毫米） (18)图4：推荐PCB封装尺寸（单位：毫米） (19)图5：VBAT 输入参考电路 (20)图6：LDO供电参考电路 (21)图7： DC-DC电源参考电路 (21)图8：突发时VBAT的跌落 (21)图9：VBAT跌落的最低电压 (22)图10：使用PWRKEY驱动电路开机 (22)图11：使用PWKEY按键开机 (23)图12：使用PWRKEY开机时序图 (23)图13：使用PWRKEY关机时序图 (24)图14：复位电路 (25)图15：复位时序图 (26)图16：外部电容给RTC供电 (27)图17：不可充电电池给RTC供电 (27)图18：可充电电池给RTC供电 (28)图19：串口连接图 (29)图20：TX连接图 (29)图21：RX连接图 (30)图22：软件升级接口 (31)图23：模块作为被叫当接收到语音呼叫时RI上的电平变化 (32)图24：模块作为被叫当接收到数据呼叫（CSD）时RI上的电平变化 (32)图25：模块接收到短信息（SMS）或者串口主动上报（URC）RI上的电平变化 (32)图26：模块作为主叫时RI上的电平变化 (33)图27：受话器接口电路 (34)图28：麦克风接口电路 (34)图29：8引脚SIM卡座的接口推荐电路 (36)图30：6引脚SIM卡座的接口推荐电路 (36)图31： MOLEX 91228 SIM卡座 (37)图32：AMPHENOL C707 10M006 5122 SIM卡座尺寸图 (38)图33：键盘接口参考电路1 (40)图34：键盘接口参考电路2 (40)图35：键盘接口参考电路3 (41)图36：键盘接口说明 (41)图37：PWM参考电路 (44)图38：NETLIGHT参考设计电路 (45)图39：LED驱动电路连接示意图 (46)图40：发射同步信号时序图 (47)图41： GSM天线接口连接电路 (48)图42： GSM天线接口简化连接电路 (48)图43：蓝牙天线接口连接电路 (49)图44： FM天线接口连接电路 (49)图45：以耳机GND管脚作为FM天线的接口连接电路 (50)图46：模块顶视图和底视图 (56)图 47： 模块推荐焊接炉温曲线图 (56)版本历史 日期版本 变更描述 作者 2013-05-101.00 初版 宋家林,李亚1. 绪论本文档描述了模块的硬件应用接口，包括相关应用场合的电路连接以及射频接口等。

LBI-38709Mobile CommunicationsEDACS™ MTD SERIES800 MHzDATA ONLYTABLE OF CONTENTSRF BOARD..................................................................... LBI-38866 AUDIO BOARD .............................................................. LBI-38622 LOGIC BOARD .............................................................. LBI-38616 SERVICE SECTION ...................................................... LBI-38624 Maintenance ManualLBI-38709Copyright © March 1994, Ericsson GE Mobile Communications Inc.LBI-38709SPECIFICATIONS*GENERALOperating Voltage 13.8 volts ±20%Battery DrainTransmit 4 amperes (maximum)Receive0.65 amperes (maximum)Channel Spacing25 kHzFrequency Stability± 2.5 PPM (±0.00025%)Temperature Range -30°C to +60°C (-22°F to +140°F)Dimensions (H x W x D) (Less Accessories)Height43.5mm (1.7 inches)Width160.2mm (6.3 inches)Depth184mm (7.25 inches)Weight 1.34 kg (47.5 ounces)Antenna Impedance 50 ohmsTRANSMITTERFrequency Range806-821 MHz (851-866 MHz Talkaround)Output Power10 Watts (20% duty cycle, EIA)Spurious and Harmonics-16 dBm (maximum)Modulation Limiting± 5 kHzHum and Noise- 45 dB (maximum)RECEIVERFrequency Range851-866 MHzAcceptable Frequency Displacement± 2.5 kHz (minimum)Sensitivity (12 dB SINAD)-116 dBm (typical)Spurious Response70 dB minimumAdjacent Channel Selectivity68 dB minimum at 25 kHzIntermodulation65 dB minimum* These specifications are intended primarily for use by service personnel. Refer to the appropriate Specifications Sheetfor complete specifications.LBI-38709The EDACS MTD Series mobile is a synthesized, wideband radio that uses integrated circuits and microcomputer technology to provide high performance trunked operation. The radio operates in the 806 to 821 MHz (transmit) and 851 to 866 MHz (receive) trunking bands. The trunking signalling format is based on 9600 baud high-speed digital coding which provides a typical system access time of 1/3 second.This MTD mobile radio is designed for 10 watts RF power output. A power detection circuit locataed just before the antenna connector keeps the output power constant over changing voltage and temperature conditions.The 800 MHz band is allocated to use contiguous 25 kHz spaced channels and 45.0125 MHz transmit-receive offset. The IF filters in the radio have been designed accordingly. In addition, the frequency determining element (TCXO) has a stability of 2.5 PPM over the operating temperature range ensuring operation in the specified channel bandwidth.All radio functions are stored in a programmable electrically erasable PROM (EEPROM). The radio is field programmable using an IBM compatible personal computer with the following equipment:•Serial Programming Interface Module TQ-3370•Programming Cable TQ-3354, and•MTD Programming Software TQ-3349With the interface equipment and software, the computer can be used to program (or reprogram) customer system frequencies and options. Programming is done through the radio's DB9 input connector.The MTD radio assembly consists of the following circuit boards and assemblies:•RF Board A2 (19D902123G16)•Audio Board A3 (19D902304G3)•Logic Board A1 (19D902151G3)The circuit boards are mounted in a main casting to provide easy access for servicing. Interconnect plugs are used to connect the boards to eliminate pinched wires and other wiring problems.The RF board includes the programmable frequency synthesizer, transmitter and receiver circuitry and PIN diode TX-RX switch.SynthesizerFirst mixer injection and transmitter exciter drive is derived from the synthesizer circuit. The synthesizer consists of the VCO, prescaler IC, PLL IC, and reference oscillator (TCXO). The logic board serially loads channel frequency information into the PLL IC.TransmitterThe transmitter circuit consists of a broadband exciter fed by the frequency synthesizer and a broadband power amplifier module. The output of the power amplifier is fed through a PIN switch circuit and a low-pass filter to the antenna cable. The transmitter is designed to operate over the 806 to 821 MHz range. A power control circuit senses the output at the antenna port and varies the exciter bias to keep the RF power constant over varying operating conditions.ReceiverThe receiver is a dual conversion superheterodyne with a first intermediate frequency of 45.0125 MHz and a second intermediate frequency of 455 kHz. A quadrature detector is used to recover the audio from the carrier. The receiver is designed with fixed RF filters to operate over the entire 851 to 866 MHz range without retuning.Diode SwitchAs the same antenna port is used for the receiver input and the transmitter power output, a PIN diode switch is used to connect these stages together. High RF isolation is provided to the receiver input when the transmitter is powered to prevent receiver damage. The transmitter is isolated during receive to minimize signal losses to the receiver.AUDIO BOARDAll of the data signals to and from the transceiver are processed by the audio board. Functions provided by the audio board circuitry include the receiver noise squelch, received data filtering and amplification, transmit data filtering and amplification, transmit deviation limiting, received high speed (9600 baud) data filtering and limiting and tramsit data wave shaping.LBI-38709The logic board contains the microprocessor and associated support circuitry, EEPROM field programmable memory, EPROM software, a custom high-speed data modem IC and DAC. This board provides all the signalling functions (9600 baud high -speed and subaudible low-speed data generation and detection) as well as alert tones, data loading for the transceiver synthesizer, and control of transmit and receive. The individual radio personality is field programmable using the Electrically Erasable PROM (EEPROM).ACCESSORIES AND OPTIONS SQUELCH TAIL ELIMINATION (STE) (Conventional Mode)STE is used with Channel Guard to eliminate squelch tails. The STE burst is transmitted when the microphone PTT is released. The receiving radio decodes the burst and mutes the receiver audio for 250 ms. This mute time allows the transmission to end and to mute the squelch tail. The radio looks for STE on the received signal when the radio is either in an on-hook or off-hook condition. The STE is enabled for transmit and/or receive by PC programming the radio's personality.PC PROGRAMMING OPTIONSThe radio is programmed using an IBM compatible personal computer equipped with an RS-232 connector. Option TQ-3370 provides the RS-232 serial interfacae unit and the cable between the PC and the unit. Programming cable TQ-3354 is used between TQ-3370 and the MTD Data Only Radio.NOISE SUPPRESSION KIT OPTIONNoise Suppression Kit Option PD1A (19A148539G1) is available for installations where excessive alternator or electrical noises present on the power cable do no permit the radio to operate properly.REMOTE DATA TERMINAL OPTIONThe Remote Data Terminal Option is required for data operation over the RF to and from a mobile data terminal. The Remote Data Interface (RDI) Option (19A149654P1) transfers the data between the radio and the Remote Data Terminal.A spare 9-foot power cable Option CC7F (19B801358P2) is available for installations requiring more than the standard 9-foot cable.SYSTEM DESCRIPTIONThe MTD 800 MHz (digitally trunked) Data Only radio system provides fast access to available RF channels and a degree of privacy due to selective signalling. This also eliminates annoyance of other system user's conversations while ensuring that intended calls are not missed.The system uses 9600 baud high-speed digital signalling to identify individual units and user groups. The programming used to determine transmit encoded groups and decoded received groups is contained in the personality EEPROM contained in the mobile. This information is individually programmed to each user's needs via the PC programming for the radio.Typical system configuration consists of at least two repeater stations (with a maximum number of 20) and the associated mobiles. One repeater always is a control channel which is dedicated to sending out continuous control data and also to receive channel request data from the mobiles. When a mobile is first turned on, it scans the available list of frequencies programmed in the personality EEPROM for a control channel. When a control channel is found, the mobile locks onto the frequency and monitors the data for a channel assignment (incoming call).When receiving a channel assignment (incoming call), the monitoring mobile immediately switches over to the assigned data channel and waits for a high-speed data confirmation message. Upon receipt of this message the data paths are unmuted and the user can complete the call.After the initiating mobile receives a channel assignment from the control station, it immediately switches frequency over to the assigned data channel and sends a burst of 9600 baud dotting.MAINTENANCE Maintenance information for the MTD Series 800 MHz Data Only mobile radio is provided in the Service Section Manual.LBI-38709INTERCONNECT DIAGRAMMTD SERIES 800 MHz, 10 WATTDATA ONLY MOBILE RADIO(19C851523, Sh. 4, Rev. 2)ILLUSTRATED MECHANICAL PARTS BREAKDOWN LBI-38709MTD SERIES 800 MHz, 10 WATTDATA ONLY MOBILE RADIO(19C851519, Sh. 6, Rev.3)LBI-38709PARTS LISTMTD SERIES800 MHz, 10 WATTDATA ONLY MOBILE RADIO19C851519G19。

SIM800系列_NTP_应用文档_V1.00手册名称SIM800系列_NTP_应用文档版本 1.00日期2013-10-29状态发布文档控制号SIM800系列_NTP_应用文档_V1.00一般事项SIMCom把本手册作为一项对客户的服务，编排紧扣客户需求，章节清晰，叙述简要，力求客户阅读后，可以通过AT命令轻松使用模块，加快开发应用和工程计划的进度。

SIMCom不承担对相关附加信息的任何独立试验，包含可能属于客户的任何信息。

而且，对一个包含SIMCom模块、较大型的电子系统而言，客户或客户的系统集成商肩负其系统验证的责任。

由于产品版本升级或其它原因，本手册内容会不定期进行更新。

除非另有约定，本手册仅作为使用指导，本手册中的所有陈述、信息和建议不构成任何明示或暗示的担保。

手册中信息修改，恕不另行通知。

版权本手册包含芯讯通无线科技（上海）有限公司的专利技术信息。

除非经本公司书面许可，任何单位和个人不得擅自摘抄、复制本手册内容的部分或全部，并不得以任何形式传播，犯规者可被追究支付赔偿金。

对专利或者实用新型或者外观设计的版权所有，SIMCom保留一切权利。

版权所有©芯讯通无线科技（上海）有限公司2013年目录1.NTP 功能 (5)1.1. SNTP 功能介绍 (5)1.2. NTP AT命令使用 (5)2.AT 命令 (6)2.1. AT+CNTPCID 设置GPRS承载场景ID (6)2.2. AT+CNTP 同步网络时间 (6)3.应用实例 (8)3.1. 网络时间同步 (8)附录 (9)A. 参考文档 (9)B. 术语和缩写 (9)版本历史日期 版本 修改点描述 作者 2013-10-29 1.00 第一版 张平适用范围本手册描述了NTP 相关AT 命令操作方法和应用实例。

本手册适用于SIM800，SIM800W ，SIM800V ，SIM800H 和SIM800L 。

1.NTP 功能Network Time Protocol（NTP）是用来使计算机时间同步化的一种协议，它可以使计算机对其服务器或时钟源（如石英钟，GPS等等)做同步化，它可以提供高精准度的时间校正（LAN上与标准间差小于1毫秒，WAN上几十毫秒），且可介由加密确认的方式来防止恶毒的协议攻击。

23click™BOARD2. Soldering the headers3. Plugging the board inOnce you have soldered the headers your board is ready to be placed into the desired mikroBUS ™ socket. Make sure to align the cut in the lower-right part of the board with the markings on the silkscreen at the mikroBUS ™socket. If all the pins are alignedcorrectly, push the board all the way into the socket.Turn the board upward again. Make sure to align the headers so that they are perpendicular to the board, then solder the pins carefully.Turn the board upside down so that the bottom side is facing you upwards. Place shorter pins of the header into the appropriate soldering pads.Before using your click ™ board, make sure to solder 1x8 male headers to both left and right side of the board. Two 1x8 male headers are included with the board in the package.4. Essential featuresThe underside of GSM3 click ™ holds the SIM card slot . Aside from that the click ™ has the following additional features: audio input/output connection pad (for microphone and earphones, can also be used as an FM antenna). The STM800H module supports Bluetooth so the click ™ has an active 2.4GHz antenna . A connector for an external GSM antenna is also provided . Two indication LEDs signal the operating and network status of the module.1GSM3 click ™ carries SIM800H , a quad-band (850 / 900 / 1800 / 1900MHz) GSM/GPRS module that transmits voice, sms and data information. The board communicates with the target board MCU through the following mikroBUS ™ lines: Tx and Rx (UART), RST (reset), STA (status indicator), RTS, PWK (PWRKEY, used to power on/down the module) and CTS. GSM3 click ™ is designed to use 3.3V and 5V I/O voltage levels.GSM3 click™1. IntroductionGSM3 click manualver 1.0101000000738348. Code examplesMikroElektronika offers free tech support (/support) until the end of the product’s lifetime, so if something goes wrong, we’re ready and willing to help!Once you have done all the necessary preparations, it’s time to get your click ™ board up and running. We have provided examples for mikroC ™, mikroBasic ™ and mikroPascal ™ compilers on our Libstock website. Just download them and you are ready to start..com6. DimensionsMikroElektronika assumes no responsibility or liability for any errors or inaccuracies that may appear in the present document. Specification and information contained in the present schematic are subject to change at any time without notice.Copyright © 2015 MikroElektronika.All rights reserved.mmmils LENGTH 431693WIDTH 25.41000HEIGHT8.23230000T X B 0106SIM800H5. Schematic7. SMD jumper10. Disclaimer9. Support25.4m m / 1000m i l s43mm / 1693milsResolder the onboard zero ohm SMD jumper to select between 3.3V or 5V I/O voltage levels (soldered in the 3.3V position by default).。

4极永磁无刷直流电机仿真结果BRUSHLESS PERMANENT MAGNET DC MOTOR DESIGNFile: Setup1.resGENERAL DATARated Output Power (kW): 0.55 额定输出功率Rated V oltage (V): 220 额定电压Number of Poles: 4 极数Given Rated Speed (rpm): 1500 给定额定转速Frictional Loss (W): 11 摩擦损耗Windage Loss (W): 0 风损Rotor Position: Inner 转子位置Type of Load: Constant Power 负载类型Type of Circuit: C2 控制电路类型Lead Angle of Trigger in Elec. Degrees: 0 晶体管导通角Trigger Pulse Width in Elec. Degrees: 120 导通脉宽One-Transistor V oltage Drop (V): 2 晶体管压降One-Diode V oltage Drop (V): 2二极管压降Operating Temperature (C): 75 运行温度Maximum Current for CCC (A): 0Minimum Current for CCC (A): 0STATOR DATANumber of Stator Slots: 24 定子槽数Outer Diameter of Stator (mm): 120 定子外径Inner Diameter of Stator (mm): 75 定子内径Type of Stator Slot: 3 定子槽类型Stator Sloths0 (mm): 0.5hs1 (mm): 1hs2 (mm): 8.2bs0 (mm): 2.5bs1 (mm): 5.6bs2 (mm): 7.6rs (mm): 0Top Tooth Width (mm): 4.62351 齿顶宽度Bottom Tooth Width (mm): 4.78125 齿底宽度Skew Width (Number of Slots) 1 斜槽宽Length of Stator Core (mm): 65 定子铁心长度Stacking Factor of Stator Core: 0.95 定子叠压系数Type of Steel: D23_50 定子材料Slot Insulation Thickness (mm): 0 槽绝缘厚度Layer Insulation Thickness (mm): 0 层绝缘厚度End Length Adjustment (mm): 0 端部长度调整Number of Parallel Branches: 1Number of Conductors per Slot: 60 每槽导体数Type of Coils: 21 绕组类型Average Coil Pitch: 5 平均节距Number of Wires per Conductor: 1 电线每导体数Wire Diameter (mm): 0.71 线径Wire Wrap Thickness (mm): 0.08 线绝缘厚度Slot Area (mm^2): 59.42 槽面积Net Slot Area (mm^2): 54.12 净槽面积Limited Slot Fill Factor (%): 75 最大槽满率Stator Slot Fill Factor (%): 69.1907 槽满率Coil Half-Turn Length (mm): 143.747 线圈半匝长ROTOR DATAMinimum Air Gap (mm): 0.5 最小气隙Inner Diameter (mm): 26Length of Rotor (mm): 65Stacking Factor of Iron Core: 0.95 叠压系数Type of Steel: D23_50 转子材料Polar Arc Radius (mm): 37 极弧半径Mechanical Pole Embrace: 0.7 机械极弧系数Electrical Pole Embrace: 0.699985 电极弧系数Max. Thickness of Magnet (mm): 3.5 最大磁钢厚度Width of Magnet (mm): 38.7594 磁钢宽度Type of Magnet: XG196/96 磁钢材料Type of Rotor: 1 转子类型Magnetic Shaft: No 转轴是否磁性PERMANENT MAGNET DATA 永磁材料参数Residual Flux Density (Tesla): 0.96 剩磁密度Coercive Force (kA/m): 690 矫顽力Maximum Energy Density (kJ/m^3): 183 最大磁能积Relative Recoil Permeability: 1 相对回复磁导率Demagnetized Flux Density (Tesla): 5.85937e-005 退磁磁通密度Recoil Residual Flux Density (Tesla): 0.867073 回复剩磁密度Recoil Coercive Force (kA/m): 690.015 回复矫顽力MATERIAL CONSUMPTION 材料消耗Armature Copper Density (kg/m^3): 8900 电枢铜密度Permanent Magnet Density (kg/m^3): 7800 永磁材料密度Armature Core Steel Density (kg/m^3): 7820 电枢铁芯密度Rotor Core Steel Density (kg/m^3): 7820 转子铁芯密度Armature Copper Weight (kg): 0.729388 电枢铜重量Permanent Magnet Weight (kg): 0.275114 永磁材料重量Armature Core Steel Weight (kg): 2.63935 电枢铁心重量Rotor Core Steel Weight (kg): 1.44611 转子铁心重量Total Net Weight (kg): 5.08996 总重量Armature Core Steel Consumption (kg): 5.44721 电枢铁心消耗Rotor Core Steel Consumption (kg): 1.85836 转子铁心消耗STEADY STATE PARAMETERS 稳态参数Stator Winding Factor: 0.879653 定子绕组系数D-Axis Reactive Inductance Lad (H): 0.021587 直轴电枢反应电抗Q-Axis Reactive Inductance Laq (H): 0.021587 交轴电枢反应电抗D-Axis Inductance L1+Lad(H): 0.0281925 直轴同步电抗Q-Axis Inductance L1+Laq(H): 0.0281925 交轴同步电抗Armature Leakage Inductance L1 (H): 0.00660549 电枢绕组漏抗Zero-Sequence Inductance L0 (H): 0 零序电抗Armature Phase Resistance R1 (ohm): 5.67264 电枢绕组相电阻Armature Phase Resistance at 20C (ohm): 4.6662 20度绕组相电阻D-Axis Time Constant (s): 0.00380546 直轴时间常数Q-Axis Time Constant (s): 0.00380546 交轴时间常数Ideal Back-EMF Constant KE (Vs/rad): 0.981343 反电势常数Start Torque Constant KT (Nm/A): 0.800227 启动转矩常数Rated Torque Constant KT (Nm/A): 1.02912 额定转矩常数NO-LOAD MAGNETIC DATA 空载磁路数据Stator-Teeth Flux Density (Tesla): 1.61237 定子齿磁密Stator-Yoke Flux Density (Tesla): 1.16604 定子轭磁密Rotor-Yoke Flux Density (Tesla): 0.728065 转子轭磁密Air-Gap Flux Density (Tesla): 0.677341 气隙磁密Magnet Flux Density (Tesla): 0.731645 磁钢磁密Stator-Teeth By-Pass Factor: 0.00468801 定子齿旁路系数Stator-Yoke By-Pass Factor: 3.45683e-005 定子轭旁路系数Rotor-Yoke By-Pass Factor: 2.00386e-005 转子轭旁路系数Stator-Teeth Ampere Turns (A.T): 36.1578 定子齿安匝Stator-Yoke Ampere Turns (A.T): 14.5864 定子轭安匝Rotor-Yoke Ampere Turns (A.T): 3.18795 转子轭安匝Air-Gap Ampere Turns (A.T): 323.26 气隙安匝Magnet Ampere Turns (A.T): -377.204 磁钢磁势Armature Reactive Ampere Turns 电枢反应安匝at Start Operation (A.T): 3647.8 启动安匝数Leakage-Flux Factor: 1 漏磁系数Correction Factor for Magnetic 磁路修正系数Circuit Length of Stator Yoke: 0.582455 定子轭磁路修正系数Correction Factor for MagneticCircuit Length of Rotor Yoke: 0.793199 转子轭磁路修正系数No-Load Speed (rpm): 2091.38 空载转速Cogging Torque (N.m): 6.36774e-013 齿槽转矩FULL-LOAD DATA 负载特性数据Average Input Current (A): 2.93027 平均负载电流Root-Mean-Square Armature Current (A): 1.95039 电枢电流有效值Armature Thermal Load (A^2/mm^3): 58.7204 电枢热负荷Specific Electric Loading (A/mm): 11.9199 电枢线负荷Armature Current Density (A/mm^2): 4.92624 电枢电流密度Frictional and Windage Loss (W): 13.0778 风磨损耗Iron-Core Loss (W): 28.9672 铁芯损耗Armature Copper Loss (W): 43.1578 电枢铜耗Transistor Loss (W): 8.92247 晶体管损耗Diode Loss (W): 0.44813 二极管损耗Total Loss (W): 94.5734 总损耗Output Power (W): 550.085输出功率Input Power (W): 644.659 输入功率Efficiency (%): 85.3297 效率Rated Speed (rpm): 1783.34 额定转速Rated Torque (N.m): 2.94556 额定转矩/负载Locked-Rotor Torque (N.m): 40.3887 堵转转矩/启动转矩Locked-Rotor Current (A): 50.559 启动电流WINDING ARRANGEMENT 绕组排列The 2-phase, 2-layer winding can be arranged in 6 slots as below: AAABBBAngle per slot (elec. degrees): 30 每槽电角度Phase-A axis (elec. degrees): 105 A相轴电角度First slot center (elec. degrees): 0 第一槽中心角TRANSIENT FEA INPUT DATA 瞬态数据For Armature Winding: 电枢绕组Number of Turns: 360 匝数Parallel Branches: 1 并联支路数Terminal Resistance (ohm): 5.67264 相电阻End Leakage Inductance (H): 0.00252843 终端漏抗2D Equivalent Value: 二维分析用到的等效数据Equivalent Model Depth (mm): 65 等效气隙长度Equivalent Stator Stacking Factor: 0.95 等效定子叠压系数Equivalent Rotor Stacking Factor: 0.95 等效转子叠压系数Equivalent Br (Tesla): 0.867073 等效剩磁磁密Equivalent Hc (kA/m): 690.015 等效矫顽力Estimated Rotor Moment of Inertia (kg m^2): 0.00149257 转动惯量估计值。