SKY13286-359LF中文资料

常用频段带线隔离器嵌入式隔离器参数表隔离器、射频隔离器、同轴隔离器、带线（嵌入式）隔离器、宽带隔离器、双节隔离器、表面封装隔离器、微波隔离器、波导隔离器、高功率隔离器带线（嵌入式）隔离器∙频率范围12MHz至26.5GHz，高达2000W功率.∙应用于民用，军事，航天，空间等.∙低插损，高隔离器，高功率.∙可按客户要求订制生产.低频率12MHz至1300MHz,包括FM,VHF,UHF等410MHz至26.5GHz, GSM,CDMA,WCDMA,LTE,L.S.C.X band, etc带线（嵌入式）隔离器：只是输入输出端口是带状线，装上连接器，就是同轴隔离器了，带线隔离器一般可以直接焊在板子上使用。

常见带线隔离器实物图如图一二，图二为带衰减，两者区别为带衰减可承受功率较大。

带线隔离器应用广泛，下面简单介绍常用手机频段使用带线隔离器的产品规格：图一 图二常用手机频段划分：以下分别列出优译三种尺寸带线隔离器指标参数：1919带线隔离器外形设计图2020带线隔离器指标参数表2020带线隔离器外形设计2525带线隔离器指标参数表2525带线隔离器外形设计图延伸阅读关于环形器隔离器的概述：环行器和隔离器是一类微波铁氧体器件，通过铁氧体控制微波信号的传输。

由于其具有非互易性，正向插损很小，而反向时则能量绝大部分被吸收。

环行器和隔离器依靠磁场来完成非互易性的工作，但仅有磁场而没有微波铁氧体，微波信号的传输仍然可以互易。

器件中的微波铁氧体决定了它的谐振频率。

关于优译：优译创立于中国深圳市，注册资金2亿元人民币，是集军民用微波通信器件开发、设计与生产的一体化企业，产品远销海内外。

公司成立于2003年，依托产业优势，凭借过硬的专业技术，以国内、国际双规运营的经验模式，在微波通信行业赢得信誉和口碑，生产的产品频率范围从300KHz 至110GHz, 功率高可达20KW，广泛使用于民用、军事、航天、空间技术等领域。

常用的军用电磁兼容测试标准
随着军事技术的不断进步和发展，军用电子设备在现代战争中扮演着至关重要的角色。

为了确保军用电子设备能够在电磁环境下正常运作，军用电磁兼容测试成为了必不可少的一环。

以下是常用的军用电磁兼容测试标准：
1. MIL-STD-461：该标准旨在规定军用电子设备在电磁环境下的要求和测试方法，包括辐射和传导两种测试方法。

2. MIL-STD-464：该标准是一项指导性文件，旨在确保不同系统和设备在电磁环境下协同工作。

它规定了电磁环境的分类、行动和计划、电磁干扰源和敏感性评估等方面的要求。

3. RTCA DO-160：该标准是一项航空工业标准，规定了航空电子设备在电磁环境下的要求和测试方法。

4. CISPR 22：该标准规定了电子设备在射频辐射的限制和测量方法。

5. IEC 61000：该标准规定了电子设备在电磁环境下的要求和测试方法，包括辐射和传导两种测试方法。

以上是常用的军用电磁兼容测试标准，其中MIL-STD-461和MIL-STD-464是美国军方颁布的标准，而RTCA DO-160则是航空工业标准。

这些标准的制定旨在确保军用电子设备在电磁环境下能够正常工作，为现代战争的胜利提供坚实的支持。

- 1 -。

矿石收音机，也被称为无源收音机，是指用天线、地线以及基本调谐回路和矿石做检波器而组成的没有放大电路的无线电接收装置。

它主要用于中波公众无线电广播的接收。

为保证矿石收音机的综合性能，所有元件都是经过精心挑选的。

例如，其中等容调谐电容C1，采用的是全新军用3联铜片瓷座可变电容器，容量为3X9-325pF，以保证调谐同步。

具体元件参数可能因不同的矿石收音机设计而异，但一般常见的元件参数包括：硬纸拼接骨架尺寸（例如：150 x 165 mm）、导线外径（例如：1.3mm）、空气可变电容（例如：365Px2）、场效应管（例如：3XP）和舌簧耳机（例如：SH091）等。

值得一提的是，尽管现在人们对半导体收音机非常关注，认为其体积小、耗费少、寿命长，但实际上矿石机就是半导体收音机的一种形式。

不过与半导体收音机不同，矿石机只有半导体检波功能，没有半导体放大功能。

Venus638FLPx GPS ReceiverData Sheet10mmx 10mmVenus638FLPx-L / Venus638FLPx-DFEATURES20Hz update rate-148dBm cold start sensitivity-165dBm tracking sensitivity29 second cold start TTFF3.5 second TTFF with AGPS1 second hot start2.5m accuracyMultipath detection and suppressionJamming detection and mitigationSBAS (WAAS / EGNOS) support7-day extended ephemeris AGPS67mW full power navigationWorks directly with active or passive antennaInternal flash for optional 75K point data logging Supports external SPI flash memory data logging Complete receiver in 10mm x 10mm x 1.3mm size Contains LNA, SAW Filter, TCXO, RTC Xtal, LDO Pb-free RoHS compliant Venus638FLPx is a high performance, low cost, single chip GPS receiver targeting mobile consumer and cellular handset applications. It offers very low power consumption, high sensitivity, and best in class signal acquisition and time-to-first-fix performance.Venus638FLPx contains all the necessary components of a complete GPS receiver, includes 1.2dB cascaded system NF RF front-end, GPS baseband signal processor, 0.5ppm TCXO, 32.768kHz RTC crystal, RTC LDO regulator, and passive components. It requires very low external component count and takes up only 100mm2 PCB footprint.Dedicated massive-correlator signal parameter search engine within the baseband enables rapid search of all the available satellites and acquisition of very weak signal. An advanced track engine allows weak signal tracking and positioning in harsh environments such as urban canyons and under deep foliage.The self-contained architecture keeps GPS processing off the host and allows integration into applications with very little resource.Venus638FLPx is very easy to use, minimizes RF layout design issues and offers very fast time to market.Product Series Product DescriptionVenus638FLPx-L Flash version GPS receiver (internal 1.2V LDO version)Suitable for Venus634FLPx direct drop-in replacementVenus638FLPx-D Flash version GPS receiver (external 1.2V version)Suitable for lower power application using external 1.2V supplyTECHNICAL SPECIFICATIONSReceiver Type L1 frequencyGPS C/A codeSBAS capable65-channel architecture8 million time-frequency searches per secondAccuracy Position 2.5m CEPVelocity 0.1m/secTiming 60nsOpen Sky TTFF 29 second cold start3.5 second with AGPS1 second hot startReacquisition < 1sSensitivity -165dBm tracking-148dBm cold startUpdate Rate 1 / 2 / 4 / 5 / 8 / 10 / 20 Hz (default 1Hz)Dynamics 4GOperational Limits Altitude < 18,000m*1 , Velocity < 515m/s*1Datum Default WGS-84Interface UART LVTTL levelBaud Rate 4800 / 9600 / 38400 / 115200Protocol NMEA-0183 V3.01, GGA, GLL, GSA, GSV, RMC, VTG (default GGA, GSA, GSV, RMC, VTG) SkyTraq BinaryMain Supply Voltage 2.8V ~ 3.6V (Venus638FLPx-L)2.8V ~3.6V, 1.08V ~ 1.32V (Venus638FLPx-D)Backup Voltage 1.5V ~ 6VCurrent ConsumptionEnhanced Acquisition Low Power Acquisition TrackingVenus638FLPx-L ***************************Venus638FLPx-D ******************************************************Assuming 75% efficiency switch-mode 3.3V-to-1.2V regulator is used, thenEnhanced Acquisition Low Power Acquisition TrackingVenus638FLPx-D *************************** Operating Temperature -40 ~ +85 deg-CStorage Temperature -40 ~ +125 deg-CPackage LGA69 10mm x 10mm x 1.3mm, 0.8mm pitch*1: COCOM limit, either may be exceeded but not bothBLOCK DIAGRAMFigure-1 GPS Receiver based on Venus638FLPxVENUS638FLPx PIN-OUT DIAGRAMFigure-2b Venus638FLPx Pin-Out DiagramVENUS638FLPx PIN DEFINITIONPin Number Signal Name Type Description1 RSTN Input Active LOW reset input, 3.3V LVTTL2 VCC33I Power Input Main voltage supply input, 2.8V ~ 3.6V3 NC Not connected, empty pin4 PIO12 Bidir General purpose I/O pin, 3.3V LVTTL5 GPIO2 Bidir General purpose I/O pin, 3.3V LVTTL6 GPIO1 Bidir General purpose I/O pin, 3.3V LVTTL7 LED / GPIO0 Bidir Navigation status indicator or General purpose I/O. 3.3V LVTTL8 GPIO24 Bidir General purpose I/O pin. 3.3V LVTTLAlso serves as Search Engine Mode Selection upon power-up1: low power acquisition mode0: enhanced acquisition mode9 BOOT_SEL Bidir Boot mode selection. Pull-high or pull-low using 10K resistor. Mustnot connect to VCC or GND directly.1: execute from internal ROM0: execute from internal Flash memory10 GND Power System ground11 GND Power System ground12 GPIO22 Bidir General purpose I/O pin, 3.3V LVTTL13 GPIO23 Bidir General purpose I/O pin, 3.3V LVTTL14 GPIO20 Bidir General purpose I/O pin, 3.3V LVTTL15 GND Power System ground16 GPIO29 Bidir General purpose I/O pin, 3.3V LVTTL17 V12O_RTC Power Output 1.2V LDO output for RTC & backup memory. Normally unused.18 VBAT Power Input Supply voltage for internal RTC and backup SRAM, 1.5V ~ 6V.VBAT should be powered by non-volatile supply voltage to haveoptimal performance. If VBAT is connected to VCC33I, powered offas VCC33I power is removed, then it’ll cold start every time. Forapplications that do not care lesser performance cold startingevery time, this pin can be connected to VCC33I.19 GND Power System ground20 NC Not connected, empty pin21 GND_RF Power RF section system ground22 GND_RF Power RF section system ground23 NC Not connected, empty pin24 GND_RF Power RF section system ground25 GND_RF Power RF section system ground26 NC Not connected, empty pin27 GND_RF Power RF section system ground28 GND_RF Power RF section system ground29 GND_RF Power RF section system ground30 NC Not connected, empty pin31 GND_RF Power RF section system ground32 RFIN Input GPS signal input, connect to GPS antenna.33 GND_RF Power RF section system ground34 NC Not connected, empty pin35 NC Not connected, empty pin36 REG_ENA Input Connect to pin-2 VCC33I37 PIO14 Bidir General purpose I/O pin, 3.3V LVTTL38 MOSI / PIO9 Bidir SPI data output or general purpose I/O pin, 3.3V LVTTL39 MISO / PIO8 Bidir SPI data input or general purpose I/O pin, 3.3V LVTTL40 P1PPS Output 1 pulse per second output. Active after position fix; goes HIGH forabout 4msec, 3.3V LVTTL41 SPI_CLK / PIOO7 Output SPI clock or general purpose output pin, 3.3V LVTTL42 RXD0 Input Received input of the asynchronous UART port. Used to inputbinary command to the GPS receiver. 3.3V LVTTL43 SPI_CSN / PIO6 Bidir SPI chip select output or general purpose I/O pin, 3.3V LVTTL44 TXD0 Output Transmit output of the asynchronous UART port. Used to outputstandard NMEA-0183 sentence or response to input binarycommand. 3.3V LVTTL45 SDA Bidir I2C data, 3.3V I/O46 SCL Bidir I2C clock, 3.3V I/O47 GPIO4 Bidir General purpose I/O pin, 3.3V LVTTL48 GPIO3 Bidir General purpose I/O pin, 3.3V LVTTL49 GND System ground50 PIO5 Output General purpose output pin, 3.3V LVTTL51 PIO11 Bidir General purpose I/O pin, 3.3V LVTTL52 RXD1 Input Received input of the asynchronous UART port.3.3V LVTTL53 GPIO25 Bidir General purpose I/O pin, 3.3V LVTTL54 GPIO30 Bidir General purpose I/O pin, 3.3V LVTTL55 PIO15 Bidir General purpose I/O pin, 3.3V LVTTL56 NC / V12 NC pin for Venus638FLPx-L1.2V supply input pin for Venus638FLPx-D57 TXD1 Output Transmit output of the asynchronous UART port.3.3V LVTTL58 VCC33I Power Input Main voltage supply input, 2.8V ~ 3.6V59 GPIO28 Bidir General purpose I/O pin, 3.3V LVTTL60 GND Power System ground61 GND_RF Power RF section system ground62 GND_RF Power RF section system ground63 GPIO6 Bidir General purpose I/O pin, 3.3V LVTTL64 GND Power System ground65 GND_RF Power RF section system ground66,67,68 NC69 GND_RF Power RF section system groundWhen using Venus638FLPx-L to replace Venus634FLPx, pin-45 ~ pin-69 can all be left unconnected.When using Venus638FLPx-D, 1.2V need to be supplied at pin-56The NC pins are to be left unconnected.DC CHARACTERISTICS OF DIGITAL INTERFACEBelow is when VCC3I is at nominally 3.3VParameter Min. Typ. Max. Units Input Low Voltage 0.8 Volt Input High Voltage 2.0 Volt Output Low Voltage, Iol = 2 ~ 16mA 0.4 Volt Output High Voltage, Ioh = 2 ~ 16mA 2.9 VoltMECHANICAL DIMENSIONRECOMMENDED PCB FOOTPRINTFigure-3 Recommended PCB Footprint.RECOMMENDED REFLOW PROFILETemperature (℃) 25 82.5 140 150 160 170 180 190 200 225 250 250 215 185 155 125 95 65 35 Time(minute) 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 8.5 9Profile Description SnPb Eutectic Process Lead Free ProcessPreheatMaximum Temperature 100+/-10 ℃140+/-10 ℃Time(ΔT) 40~60s 50~70sRamp-UpRamp-Up Rate 1 ℃/s Max. 1 ℃/s Max.Time(ΔT) 120~150s 160~200sReflowMaximum Temperature Peak Temp. Peak Temp.Minimum Temperature 180+/-5℃200+/-10℃Peak Temperature 220+/-2℃250+/-2℃Time(ΔT) during Peak10~30s20~40sTemp.+/-2℃Reflow Time(ΔT) 120~150s 120~150sCoolingCooling Rate 1.5 ℃/s Max 1.5 ℃/s MaxTime(ΔT) 60~120s 150~180sAPPLICATION CIRCUIT INTERFACE SIGNALSGND_A: RF groundLED: Signal to indicate GPS position status, 3.3V LVTTL.Active low for no-fix, toggle every second after position fix.PSE_SEL: Search engine mode selection, sampled only at end of power-on reset cycle1: Low power acquisition mode0: Enhanced acquisition modeGND: Digital groundP1PPS: 1 pulse per second time-mark (3.3V LVTTL)RSTN: Active low reset inputVCC33: 3.3V power inputFRXD0: UART input (3.3V LVTTL)FTXD0: UART output (3.3V LVTTL)VBAT: Battery-backed RTC and SRAM supply input, 1.5V ~ 6V, must not be unconnected.APPLICATION INFORMATION1. For fast-rising power supply, a simple series R/C reset delay to pin-1, RSTN, as indicated in the application circuit is suitable.For system having slow-rising power supply, a reset IC providing 2~5ms reset duration may be necessary.2. The RF input of Venus638FLPx is already matched to 50-ohm. Passive antenna matched to 50-ohm can be directly applied.3. For using Venus638FLPx with active antenna, one with gain in range of 10~30dB and noise figure < 2dB can be used. Powerto the active antenna needs to be applied externally.4. Pin-18 VBAT supplies backup power to the real-time clock and backup SRAM for fast startup. For portable applicationswhere there is battery with voltage in range of 1.5V ~ 6.0V as the main source, the VBAT pin can be directly connected to it.If VBAT is connected to main power as pin-2, no supply voltage as Venus638FLPx is powered off, then it’ll cold start every time and GPS performance will not be optimal.5. Like BGA device, the Venus638FLPx is moisture sensitive. It needs to be handled with care to void damage from moistureabsorption and SMT re-flow. The device should be baked for 24 hours at 125-degC before mounting for SMT re-flow if it has been removed from the protective seal for more than 48*1hours.6. The supported SPI Flash memory verified for data logging application are:Manufacturer Device ID SizeEON EN25F040 4MbitEON EN25F080 8MbitMXIC MX25L400 4MbitMXIC MX25L800 8MbitMXIC MX25L1605 16MbitMXIC MX25L3205 32MbitMXIC MX25L6405 64MbitWINBOND W25X40 4MbitWINBOND W25X80 8MbitWINBOND W25X16 16MbitWINBOND W25X32 32MbitWINBOND W25X64 64MbitSST SST25LF040 4MbitSST SST25LF080 8MbitSST SST25VF016 16MbitSST SST 25VF032 32Mbit7. The P1PPS pin must not be pulled-high during power on reset, or it’ll enter into debug mode and freeze.*1: Actual will be longer, moisture sensitivity level still undergoing verification.SLEEP MODEFor application requiring sleep mode, it can be implemented using regulator with enable control as below figure shows. To put Venus638FLPx to sleep, the power to Venus638FLPx is cut off by disabling the regulator via host processor GPIO pin. In sleep mode, VBAT consume less than 10uA. Fast start up operation is provided by keeping supply voltage to VBAT constant, retaining the internal data and keep RTC running while Venus638FLPx is put to sleep or when supply 3.3V power is removed.For applications needing sleep mode but cannot have extra cost of adding a rechargeable backup supply battery, it can be implemented as below figure shows. It will provide fast start up when Venus638FLPx is put to sleep and awakened, but will cold start every time when the 3.3V supply voltage is removed and re-applied again.When using sleep mode, add 10K series resistor on pin-42 RXD0 and pin-44 TXD0.PACKAGENMEA MESSAGESThe full descriptions of supported NMEA messages are provided at the following paragraphs.GGA - Global Positioning System Fix DataTime, position and fix related data for a GPS receiver.Structure:$GPGGA,hhmmss.sss,ddmm.mmmm,a,dddmm.mmmm,a,x,xx,x.x,x.x,M,,,,xxxx*hh<CR><LF>1 2 3 4 5 6 7 8 9 10 11Example:$GPGGA,111636.932,2447.0949,N,12100.5223,E,1,11,0.8,118.2,M,,,,0000*02<CR><LF>Field Name Example Description1 UTC Time 111636.932 UTC of position in hhmmss.sss format, (000000.000 ~ 235959.999)2 Latitude 2447.0949 Latitude in ddmm.mmmm formatLeading zeros transmitted3 N/S Indicator N Latitude hemisphere indicator, ‘N’ = North, ‘S’ = South4 Longitude 12100.5223 Longitude in dddmm.mmmm formatLeading zeros transmitted5 E/W Indicator E Longitude hemisphere indicator, 'E' = East, 'W' = West6 GPS qualityindicator 1 GPS quality indicator0: position fix unavailable1: valid position fix, SPS mode2: valid position fix, differential GPS mode3: GPS PPS Mode, fix valid4: Real Time Kinematic. System used in RTK mode with fixed integers5: Float RTK. Satellite system used in RTK mode. Floating integers6: Estimated (dead reckoning) Mode7: Manual Input Mode8: Simulator Mode7 Satellites Used 11 Number of satellites in use, (00 ~ 12)8 HDOP 0.8 Horizontal dilution of precision, (00.0 ~ 99.9)9 Altitude 108.2 mean sea level (geoid), (-9999.9 ~ 17999.9)10 DGPS Station ID 0000 Differential reference station ID, 0000 ~ 1023NULL when DGPS not used11 Checksum 02GLL – Latitude/LongitudeLatitude and longitude of current position, time, and status.Structure:$GPGLL,ddmm.mmmm,a,dddmm.mmmm,a,hhmmss.sss,A,a*hh<CR><LF>1 2 3 4 5 6 7 8Example:$GPGLL,2447.0944,N,12100.5213,E,112609.932,A,A*57<CR><LF>Field Name Example Description1 Latitude 2447.0944 Latitude in ddmm.mmmm formatLeading zeros transmitted2 N/S Indicator N Latitude hemisphere indicator‘N’ = North‘S’ = South3 Longitude 12100.5213 Longitude in dddmm.mmmm formatLeading zeros transmitted4 E/W Indicator E Longitude hemisphere indicator'E' = East'W' = West5 UTC Time 112609.932 UTC time in hhmmss.sss format (000000.000 ~235959.999)6 Status A Status, ‘A’ = Data valid, ‘V’ = Data not valid7 Mode Indicator A Mode indicator‘N’ = Data not valid‘A’ = Autonomous mode‘D’ = Differential mode‘E’ = Estimated (dead reckoning) mode‘M’ = Manual input mode‘S’ = Simulator mode8 Checksum 57GSA – GNSS DOP and Active SatellitesGPS receiver operating mode, satellites used in the navigation solution reported by the GGA or GNS sentence and DOP values.Structure:$GPGSA,A,x,xx,xx,xx,xx,xx,xx,xx,xx,xx,xx,xx,xx,x.x,x.x,x.x*hh<CR><LF>1 2 3 3 3 3 3 3 3 3 3 3 3 3 4 5 6 7Example:$GPGSA,A,3,05,12,21,22,30,09,18,06,14,01,31,,1.2,0.8,0.9*36<CR><LF>Field Name Example Description1 Mode A Mode‘M’ = Manual, forced to operate in 2D or 3D mode‘A’ = Automatic, allowed to automatically switch 2D/3D2 Mode3 Fix type1 = Fix not available2 = 2D3 = 3D3 Satellite used 1~12 05,12,21,22,30,09,18,06,14,01,31,, Satellite ID number, 01 to 32, of satellite used in solution, up to 12 transmitted4 PDOP 1.2 Position dilution of precision (00.0 to 99.9)5 HDOP 0.8 Horizontal dilution of precision (00.0 to 99.9)6 VDOP 0.9 Vertical dilution of precision (00.0 to 99.9)7 Checksum 36GSV – GNSS Satellites in ViewNumber of satellites (SV) in view, satellite ID numbers, elevation, azimuth, and SNR value. Four satellites maximum per transmission.Structure:$GPGSV,x,x,xx,xx,xx,xxx,xx,…,xx,xx,xxx,xx *hh<CR><LF>1 2 3 4 5 6 7 4 5 6 7 8Example:$GPGSV,3,1,12,05,54,069,45,12,44,061,44,21,07,184,46,22,78,289,47*72<CR><LF>$GPGSV,3,2,12,30,65,118,45,09,12,047,37,18,62,157,47,06,08,144,45*7C<CR><LF>$GPGSV,3,3,12,14,39,330,42,01,06,299,38,31,30,256,44,32,36,320,47*7B<CR><LF>Field Name Example Description1 Number of message 3 Total number of GSV messages to be transmitted (1-3)2 Sequence number 1 Sequence number of current GSV message3 Satellites in view 12 Total number of satellites in view (00 ~ 12)4 Satellite ID 05 Satellite ID number, GPS: 01 ~ 32, SBAS: 33 ~ 64 (33 =PRN120)5 Elevation 54 Satellite elevation in degrees, (00 ~ 90)6 Azimuth 069 Satellite azimuth angle in degrees, (000 ~ 359 )7 SNR 45 C/No in dB (00 ~ 99)Null when not tracking8 Checksum 72RMC – Recommended Minimum Specific GNSS DataTime, date, position, course and speed data provided by a GNSS navigation receiver.Structure:$GPRMC,hhmmss.sss,A,dddmm.mmmm,a,dddmm.mmmm,a,x.x,x.x,ddmmyy,,,a*hh<CR><LF>1 2 3 4 5 6 7 8 9 10 11Example:$GPRMC,111636.932,A,2447.0949,N,12100.5223,E,000.0,000.0,030407,,,A*61<CR><LF>Field Name Example Description1 UTC time 0111636.932 UTC time in hhmmss.sss format (000000.00 ~235959.999)2 Status A Status‘V’ = Navigation receiver warning‘A’ = Data Valid3 Latitude 2447.0949 Latitude in dddmm.mmmm formatLeading zeros transmitted4 N/S indicator N Latitude hemisphere indicator‘N’ = North‘S’ = South5 Longitude 12100.5223 Longitude in dddmm.mmmm formatLeading zeros transmitted6 E/W Indicator E Longitude hemisphere indicator'E' = East'W' = West7 Speed over ground 000.0 Speed over ground in knots (000.0 ~ 999.9)8 Course over ground 000.0 Course over ground in degrees (000.0 ~ 359.9)9 UTC Date 030407 UTC date of position fix, ddmmyy format10 Mode indicator A Mode indicator‘N’ = Data not valid‘A’ = Autonomous mode‘D’ = Differential mode‘E’ = Estimated (dead reckoning) mode‘M’ = Manual input mode‘S’ = Simulator mode11 checksum 61VTG – Course Over Ground and Ground SpeedThe Actual course and speed relative to the ground.Structure:GPVTG,x.x,T,,M,x.x,N,x.x,K,a*hh<CR><LF>1 2 3 4 5Example:$GPVTG, 000.0,T,,M,000.0,N,0000.0,K,A*3D<CR><LF>Field Name Example Description1 Course 000.0 True course over ground in degrees (000.0 ~ 359.9)2 Speed 000.0 Speed over ground in knots (000.0 ~ 999.9)3 Speed 0000.0 Speed over ground in kilometers per hour (0000.0 ~1800.0)4 Mode A Mode indicator‘N’ = not valid‘A’ = Autonomous mode‘D’ = Differential mode‘E’ = Estimated (dead reckoning) mode‘M’ = Manual input mode‘S’ = Simulator mode5 Checksum 3DORDERING INFORMATIONPart Number DescriptionVenus638FLPx-L Flash version GPS receiver (internal 1.2V LDO version)Venus638FLPx-D Flash version GPS receiver (external 1.2V version)SkyTraq Technology, Inc.4F, No.26, Minsiang Street, Hsinchu, Taiwan, 300Phone: +886 3 5678650Fax: +886 3 5678680Email: ****************.tw© 2008 SkyTraq Technology Inc. All rights reserved.Not to be reproduced in whole or part for any purpose without written permission of SkyTraq Technology Inc (“SkyTraq”). Information provided by SkyTraq is believed to be accurate and reliable. These materials are provided by SkyTraq as a service to its customers and may be used for informational purposes only. SkyTraq assumes no responsibility for errors or omissions in these materials, nor for its use. SkyTraq reserves the right to change specification at any time without notice.These materials are provides “as is” without warranty of any kind, either expressed or implied, relating to sale and/or use of SkyTraq products including liability or warranties relating to fitness for a particular purpose, consequential or incidental damages, merchantability, or infringement of any patent, copyright or other intellectual property right. SkyTraq further does not warrant the accuracy or completeness of the information, text, graphics or other items contained within these materials. SkyTraq shall not be liable for any special, indirect, incidental, or consequential damages, including without limitation, lost revenues or lost profits, which may result from the use of these materials.SkyTraq products are not intended for use in medical, life-support devices, or applications involving potential risk of death, personal injury, or severe property damage in case of failure of the product.Change LogVersion 0.7, January 25, 20111. Changed latitude, longitude, speed, heading number of digits back to original format due to customer backwardcompatibility issueVersion 0.6, October 20, 20101. Edited performance spec due to firmware enhancement2. Added 1 more decimal digit to latitude, longitude, speed, heading in NMEA sentenceVersion 0.5, August 31, 20101. Added application information on P1PPS pinVersion 0.4, August 3, 20101. Pin-1 orientation in the shipping tray rotated 90-degreeVersion 0.3, April 6, 20101 Modified for Flash typeVersion 0.2, March 24, 20101. Added current consumption number for –D version at 3.3VVersion 0.1, February 24, 20101. Initial release。

LF355/356/357 JFET输入型运算放大器——中文数据手册--by LF邮箱：******************整体描述:这些是第一个合成的JFET输入的运算放大器，它把匹配的高电压的JFET晶体管和标准的双极性晶体管放到了一块芯片上（双极FET技术）。

这些运放的特征是低输入失调和偏置电流、低偏置电压和偏置电压漂移、可以进行偏置调节而不会降低漂移和共模抑制比。

这些运放也设计有高压摆率、宽带宽、极快的建立时间、低电压电流噪声。

特征：优点--代替昂贵的混合型和模块型FET运算放大器--低噪声应用性能优异——高或低的输入源阻抗均可--偏置可调不会像其他合成型运放降低漂移和共模抑制比--新的输出阶段可以接入大的电容负载（5000pF）不会出现稳定性问题--内部补偿和可承受大的差分输入电压应用：--精密高速积分器--快速模/数和数/模转换器--高阻抗缓冲保护--宽带、低噪、低漂移放大器--对数放大器--光电放大器--采样保持电路共同特性：--低输入失调电流——30pA--低输入偏置电流——3pA--高输入阻抗——10的12次方Ω--低输入噪声电流——0.01pA/sqrt(Hz)--高共模抑制比——100dB--高直流增益——106dB不同特性：--极快的建立时间——5系列4us，6系列7系列1.5us--快速的压摆率——5系列5V/us，6系列12V/us，7系列50V/us--宽增益带宽——5系列2.5MHz，6系列5MHz，7系列20MHz--低输入噪声电压——5系列20nV/sqrt(Hz)，6系列7系列12nV/sqrt(Hz)供电电压：±15V典型电路连接：Vos调节--Vos用一个25k的电位器调节--电位器中间调节端连到V+驱动容性负载--对于LF155/6 R=5k--对于LF357 R=1.25k--由于独特的输出平台设计，这些放大器能够驱动大的容性负载并且能保持稳定性。

爱 克 赛 Powerware UPS 产 品 航 空 系 统 国 内 部 分 用 户 名 单中国广播卫星通信公司1PLUS 250 并机250南京航空学院4系统1010南京航空学院1121010江苏扬州卫星通讯甘肃1PLUS 1210新疆航空公司1Prime4545航空航天苏州飞机仪表厂研究所BP+15民航三亚航管站BP+50沈阳桃仙机场BP+37.5福州机场雷达站IBP+10湖南长沙机场雷达站BP+37.5湖南长沙黄花机场29315(Plus)上海虹桥机场BP+37.5重庆机场BP+37.5天津民航学校BP+50北京空军司令部通信部S1050中国航空器材公司DELTA11-80广州南方航空公司计算中心IBP+30南航计算机中心BP+30南航计算机中心IBP+30航空部六零六所BP+40广州飞机维修工程公司BP+75首都机场信息管理系统筹备组S1100青岛流亭机场BP+80青岛流亭机场IBP+20首都机场BP+100哈尔滨机场BPII 15哈尔滨机场BPII 15民航中南电子公司BP+80济南机场BP+80济南机场IBP+30延吉机场扩建指挥部BP+40延吉机场扩建指挥部BP+40民航甘肃省通信处IBP+30贵阳龙洞堡机场BP+80民航甘肃省局通信导航处BP+80贵阳龙洞堡机场BP+80内蒙古民航局雷达站IBP+30内蒙古民航局航管中心BP+80 RAYTHEON 郑州机场BP+80上海宝山钢铁公司DS1080民航总局空中交通管理局IBP+30×2新疆乌鲁木齐机场BP+75郑州省民航局BP+80郑州省民航局BP+80郑州省民航局BP+80民航汕头外砂机场通讯科BP+80民航汕头外砂机场通讯科BP+30民航连云港站通讯科BP+80民航连云港站通讯科BP+30哈尔滨机场BPII15哈尔滨机场BPII15民航江苏省局通讯导航总站雷达站BP+80民航江苏省局通讯导航总站雷达站BP+75哈尔滨机场扩建指挥部DS1200徐州市观音机场PLUS65并合肥机场雷达站BP+75人行怀柔清算中心SYSTEM375并咸阳机场BP+20咸阳机场BP+80航天部一院15所PLUS510南昌机场BP+80南昌机场BP+20桂林机场(ALENIA)BP+75桂林机场(ALENIA)BP+80桂林机场(ALENIA)BP+80中国民航海南管理局通信雷达站BP+80中国民航海南管理局通信雷达站BP+75民航天津培训中心ALENIA PLUS80民航海南省美兰机场雷达站BP+75民航海南省美兰机场雷达站BP+80桂林两江国际机场(航管楼)BP+80桂林两江国际机场(雷达站)BP+75中国航空技术国际支持公司PROFILE10民航湖南省雷达站BP+75海口美兰机场计算机房PROFILE10海口美兰机场计算机房PROFILE10海口美兰机场计算机房PROFILE10海口美兰机场计算机房PROFILE10云南航空公司通信处BP+80云南航空公司通信处BP+20民航山西省局空管中心通信科雷达站BP+20民航山西省局空管中心通信科雷达站BP+80民航安徽省局通信雷达站BP+75中国北方航空公司计算机信息中心PRIME30南昌昌北机场航管工程分指挥部PLUS40中国云南航空公司PLUS65并中国云南航空公司PLUS65并江苏证券有限责任公司电脑工程部PLUS40。

SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•Si4831/35-B30广播机械调谐AM/FM/SW 无线电接收器特性⏹ 支持全球FM 波段 (64–109MHz)⏹支持全球AM 波段 (504–1750kHz)⏹支持SW 波段 (Si4835 独有)(5.6–22MHz)⏹卓越的真实世界性能⏹依据EN55020标准⏹无需手动调整⏹灵活的波段选择⏹自动的频率控制(AFC)⏹集成LDO 稳压器r ⏹ 2.0-3.6V 电源电压⏹支持广泛的铁氧体环棒和空气环形天线⏹24引脚的SSOP ⏹外形封装⏹支持站和立体声和LED 指示灯⏹可直接实现音量控制l ⏹高低音控制S T S T V O Si4831/35-B30，其功能和/或架构涵盖于以下一个或多个专利，以及国人外正申请和已发布的其他专利中: 7,127,217;7,272,373; 7,272,375; 7,321,324;7,355,476; 7,426,376; 7,471,940;7,339,503; 7,339,504.订购信息：请参阅第 13 页。

Si4831/35-B302SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•Si4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 3T ABLE OF C ONTENTSSectionPage1. Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42. Typical Application Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .83. Bill of Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .94. Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .104.1. Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .104.2. FM Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .104.3. AM Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114.4. SW Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114.5. Frequency Tuning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114.6. Band Select . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114.7. Bass and Treble . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114.8. Volume Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .115. Pin Descriptions: Si4831/35-B30 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .126. Ordering Guide . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .137. Package Markings (Top Marks) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .147.1. Si4831/35-B30 Top Mark . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .147.2. Top Mark Explanation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .148. Package Outline: Si4831/35-B30 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .159. PCB Land Pattern: Si4831/35-B30 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1610. Additional Reference Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17Document Change List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18Si4831/35-B304SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•1. Electrical SpecificationsTable 1. Recommended Operating Conditions 1,2ParameterSymbol Test ConditionMin Typ Max Unit Supply Voltage 3V DD 2— 3.6V Power Supply Powerup Rise Time V DDRISE10——µs Ambient TemperatureT A–152585︒CNote:1. Typical values in the data sheet apply at V DD = 3.3V and 25°C unless otherwise stated.2. All minimum and maximum specifications in the data sheet apply across the recommended operating conditions forminimum V DD = 2.7V.3. Operation at minimum V DD is guaranteed by characterization when V DD voltage is ramped down to 2.0V. Partinitialization may become unresponsive below 2.3V.Table 2. Absolute Maximum Ratings 1,2ParameterSymbol Value Unit Supply Voltage V DD –0.5 to 5.8V Input Current 3I IN 10mA Operating Temperature T OP –40 to 95 ︒C Storage Temperature T STG–55 to 150︒C RF Input Level 40.4V PKNotes:1.Permanent device damage may occur if the above Absolute Maximum Ratings are exceeded. Functional operationshould be restricted to the conditions as specified in the operational sections of this data sheet. Exposure beyond recommended operating conditions for extended periods may affect device reliability.2. The Si4831/35-B30 devices are high-performance RF integrated circuits with certain pins having an ESD rating of<2kV HBM. Handling and assembly of these devices should only be done at ESD-protected workstations.3. For input pins RST, VOL+/TREBLE, VOL–/BASS, XTALO, XTALI, BAND, TUNE2, TUNE1, STATION, and STEREO.4. At RF input pins, FMI and AMI.Si4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 5Figure 1.Reset TimingTable 3. DC Characteristics(V DD =2.7 to 3.6V, T A =–15 to 85°C)ParameterSymbolTest ConditionMinTypMaxUnitFM Mode Supply Current 1I FM —21.0—mA Supply Current 2I FMLow SNR level—21.5—mAAM/SW Mode Supply Current 1I AM—17.0—mASupplies and Interface V DD Powerdown CurrentI DDPD—10—µANotes:1.Specifications are guaranteed by characterization.2. LNA is automatically switched to higher current mode for optimum sensitivity in weak signal conditions.Table 4. Reset Timing Characteristics(V DD = 2.7 to 3.6V, TA = –15 to 85°C)ParameterSymbol Min Typ Max Unit RST Pulse Width and TUNE1, TUNE2 Setup to RST t SRST 100——µs TUNE1, TUNE2 Hold from RSTt HRST30——nsTUNE1TUNE2RSTSi4831/35-B306SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•Table 5. FM Receiver Characteristics 1,2(V DD = 2.7 to 3.6V, TA = –15 to 85°C)ParameterSymbol Test Condition Min Typ Max UnitInput Frequencyf RF64—109MHz Sensitivity with Headphone Network 3(S+N)/N = 26 dB — 2.2—µV EMF LNA Input Resistance 4,5—4—k ΩLNA Input Capacitance 4,5—5—pF AM Suppression 4,5,6,7m = 0.3—50—dB Input IP34,8—105—dBµV EMFAdjacent Channel Selectivity 4±200 kHz —50—dB Alternate Channel Selectivity 4±400 kHz—65—dB Audio Output Voltage 5,6,7—80—mV RMS Audio Mono S/N 5,6,7,9,10—55—dB Audio Stereo S/N 3,4,5,7,9,10,—55—dB Audio Frequency Response Low –3dB ——30Hz Audio Frequency Response High –3dB15——kHz Audio Stereo Separation 5,11—42—dB Audio THD 6,5,11—0.10.5%Audio Output Load Resistance 4,10R L Single-ended 10——k ΩAudio Output Load Capacitance 4,10C LSingle-ended——50pF Powerup/Band Switch Time 4——110msNotes:1.Additional testing information is available in “AN569: Si4831/35-DEMO Board Test Procedure.” Volume =maximumfor all tests. Tested at RF =98.1MHz.2. To ensure proper operation and receiver performance, follow the guidelines in “AN555: Si483x-B Antenna, Schematic,Layout, and Design Guidelines.” Skyworks will evaluate schematics and layouts for qualified customers.3. Frequency is 76~109MHz.4. Guaranteed by characterization.5. V EMF =1 mV.6. F MOD =1kHz, MONO, and L =R unless noted otherwise.7. ∆f =22.5kHz.8. |f 2 – f 1| > 2MHz, f 0=2x f 1 – f 2.9. B AF =300Hz to 15kHz, A-weighted.10. At L OUT and R OUT pins.11. ∆f =75 kHz.Si4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 7Table 6. AM/SW Receiver Characteristics 1, 2(V DD = 2.7 to 3.6 V, TA = –15 to 85 °C)ParameterSymbol Test Condition Min Typ Max Unit Input Frequencyf RFMedium Wave (AM)504— 1750kHz Short Wave (SW)5.60—22.0MHz Sensitivity 3,4,5(S+N)/N = 26 dB — 30—µV EMF Large Signal Voltage Handling 5THD < 8%— 300— mV RMS Power Supply Rejection Ratio 5ΔV DD =100 mV RMS , 100 Hz— 40— dB Audio Output Voltage 3,6— 60— mV RMS Audio S/N 3,4,6— 55— dB Audio THD 3,6— 0.10.5%Antenna Inductance 5,7180—450µH Powerup/Band Switch Time 5From powerdown ——110msNotes:1.Additional testing information is available in “AN569: Si4831/35-DEMO Board Test Procedure.” Volume =maximumfor all tests. Tested at RF =520kHz.2. To ensure proper operation and receiver performance, follow the guidelines in “AN555: Si483x-B Antenna, Schematic,Layout, and Design Guidelines.” Skyworks will evaluate schematics and layouts for qualified customers.3. FMOD =1kHz, 30% modulation, 2kHz channel filter.4. B AF =300Hz to 15kHz, A-weighted.5. Guaranteed by characterization.6. V IN =5mVrms.7. Stray capacitance on antenna and board must be < 10pF to achieve full tuning range at higher inductance levels.Table 7. Reference Clock and Crystal Characteristics(V DD = 2.7 to 3.6V, T A = –15 to 85°C)ParameterSymbolTest Condition MinTypMaxUnitReference ClockXTALI Supported Reference Clock Frequencies—32.768—kHz Reference Clock Frequency Tolerance for XTALI–100—100ppmCrystal OscillatorCrystal Oscillator Frequency —32.768—kHz Crystal Frequency Tolerance –100—100ppm Board Capacitance——3.5pFSi4831/35-B308SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•2. Typical Application SchematicNotes:1.Place C 4 close to V DD2 and DBYP pins.2. All grounds connect directly to GND plane on PCB.3. Pin 6 and 7 leave floating.4. To ensure proper operation and receiver performance, follow the guidelines in "AN555: Si483x-B Antenna, Schematic,Layout, and Design Guidelines." Skyworks will evaluate the schematics and layouts for qualified customers.5. Pin 8 connects to the FM antenna interface and pin 12 connects to the AM antenna interface.6. Place Si483x as close as possible to antenna jack and keep the FMI and AMI traces as short as possible.OptionalSi4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 93. Bill of MaterialsTable 8. Si4831/35-B30 Bill of MaterialsComponent(s)Value/DescriptionSupplier C1Reset capacitor 0.1uF, ±20%, Z5U/X7RMurata C4Supply bypass capacitor, 0.1uF, ±20%, Z5U/X7R Murata C5Coupling capacitor, 0.47µF, ±20%, Z5U/X7R Murata B1Ferrite bead 2.5k/100MHzMurata VR1Variable resistor (POT), 100k, ±10%Kennon R1Reset timing resistor, 100k, ±5%Venkel R2Resistor, 10k, ±5%Venkel R3Resistor, 253k, ±1%Venkel R4Resistor, 180k, ±1%Venkel R5Resistor, 67k, ±1%Venkel U1Si4831/35-B30 Mechanical Tuning Radio Receiver Skyworks S2Band switchAny, depends oncustomerANT1Ferrite stick,180-450µHJiaxinOptional ComponentsC2, C3Crystal load capacitors, 22pF, ±5%, COG (Optional: for crystal oscillator option)Venkel Y132.768kHz crystal (Optional: for crystal oscillator option)Epson or equivalentANT2Air loop antenna, 10–20µHVariousSi4831/35-B3010SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•4. Functional DescriptionFigure 2.Si4831/35-B30 Functional Block Diagram4.1. OverviewThe Si4831/35-B30 is the industry's most advanced fully integrated, mechanical-tuned 100% CMOS AM/FM/SW radio receiver IC. Offering unmatched integration and PCB space savings, the Si4831/35-B30requires minimum external components and a small board area. The Si4831/35-B30 AM/FM/SW radio provides space savings and low power consumption while delivering the high performance and design simplicity desired for all AM/FM/SW solutions.Leveraging Skyworks' proven and patented digital low intermediate frequency (low-IF) receiver architecture,the Si4831/35-B30 delivers superior RF performance and interference rejection in AM, FM, and SW bands.The high integration and complete system production test simplifies design-in, increases system quality, and improves manufacturability.4.2. FM ReceiverThe Si4831/35-B30 integrates a low noise amplifier (LNA) supporting the worldwide FM broadcast band (64to 109MHz).Pre-emphasis and de-emphasis is a technique used by FM broadcasters to improve the signal-to-noise ratio of FM receivers by reducing the effects of high frequency interference and noise. When the FM signal is transmitted, a pre-emphasis filter is applied to accentuate the high audio frequencies. All FM receivers incorporate a de-emphasis filter which attenuates high frequencies to restore a flat frequency response. Two time constants are used in various regions. The de-emphasis time constant can be chosen to be 50 or 75µs. Refer to "AN555: Si483x-B Antenna, Schematic,Layout, and Design Guidelines."The Si4831/35-B30 also has advanced stereo blending that employs adaptive noise suppression. As a signal quality degrades, the Si4831/35-B30 gradually combines the stereo left and right audio channels to a mono audio signal to maintain optimum sound fidelity under varying reception conditions. The Si4831/35-B30can drive a stereo light with the stereo/mono information so that the user can easily discern the signal quality.S T S T V O L TUNE 1/2BANDSi4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 11The stereo light up criteria is defined using both RSSI and the Left and Right separation levels as these two specifications are the primary factors for stereo listening. The criteria can be set between two conditions: the Left and Right channels are separated by more than 6dB with RSSI at >20dB or Left and Right channels are separated by more than 12dB with RSSI at >28dB. The selection can be set up using different values of the external resister. Refer to "AN555: Si483x-B Antenna, Schematic, Layout, and Design Guidelines."4.3. AM ReceiverThe highly integrated Si4831/35-B30 supports worldwide AM band reception from 504 to 1750kHz with five sub-bands using a digital low-IF architecture with a minimum number of external components and no manual alignment required. This patented architecture allows for high-precision filtering, offering excellent selectivity and SNR with minimum variation across the AM band. Similar to the FM receiver, the Si4831/35-B30optimizes sensitivity and rejection of strong interferers,allowing better reception of weak stations.To offer maximum flexibility, the receiver supports a wide range of ferrite loop sticks from 180–450µH. An air loop antenna is supported by using a transformer to increase the effective inductance from the air ing a 1:5 turn ratio inductor, the inductance is increased by 25 times and easily supports all typical AM air loop antennas, which generally vary between 10 and 20µH.4.4. SW ReceiverThe Si4835 supports 16 short wave (SW) band receptions from 5.60 to 22.0MHz. Si4835 supports extensive short wave features such as minimal discrete components and no factory adjustments. The Si4835supports using the FM antenna to capture short wave signals.4.5. Frequency TuningA valid channel can be found by tuning the potentiometer that is connected to the TUNE1 and TUNE2 pin of the Si4831/35-B30 chip.To offer easy tuning, the Si4831/35-B30 also supports a station LED light. It will light up the LED if the RF signal quality passes the LED sensitivity threshold when tuned to a valid station.4.6. Band SelectThe Si4831/35-B30 supports worldwide AM band with five sub-bands, US/Europe/Japan/China FM band with five sub-bands, and SW band with 16 sub-bands. For details on band selection, refer to "AN555: Si483x-B Antenna, Schematic, Layout, and Design Guidelines."4.7. Bass and TrebleThe Si4831/35-B30 further supports bass and treble tone control for superior sound quality. Pins 16 and 17can be configured for tone control, allowing customers to use either two buttons or one slide-switch to adjust the bass and treble. For further configuration details,refer to "AN555: Si483x-B Antenna, Schematic, Layout,and Design Guidelines."4.8. Volume ControlThe Si4831/35-B30 not only allows customers to use the traditional PVR wheel volume control through an external speaker amplifier, it also supports direct digital volume control through pins 16 and pin 17 by using volume up and down buttons. Refer to "AN555: Si483x-B Antenna, Schematic, Layout, and Design Guidelines."Si4831/35-B3012SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•5. Pin Descriptions: Si4831/35-B30Pin Number(s)Name Description1STEREO Stereo indicator 2STATION Station indicator 3TUNE1Frequency tuning 4TUNE2Frequency tuning5BAND Band selection and De-emphasis/Stereo separation selection 6,7NC No connect. Leave floating.8FMI FM RF inputs. FMI should be connected to the antenna trace.9RFGND RF ground. Connect to ground plane on PCB.10,11NC Unused. Tie these pins to GND.12AMI AM RF input. AMI should be connected to the AM antenna.13,14GND Ground. Connect to ground plane on PCB.15RST Device reset (active low) input 16VOL+/TREBLE Volume button up/Treble 17VOL–/BASS Volume button down/Bass 18XTALO Crystal oscillator output 19XTALI Crystal oscillator input20VDD1Supply voltage. May be connected directly to battery.21VDD2Supply voltage. May be connected directly to battery.22DBYP Dedicated bypass for VDD23ROUT Right audio line output in analog output mode 24LOUTLeft audio line output in analog output modeNC FMI RFGNDAMIBAND TUNE2TUNE1STATION STEREO NC NC NC RST LOUT ROUT DBYP VDD2VOL+/TREBLE XTALO XTALI VDD1GNDGNDVOL-/BASSSi4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 136. Ordering GuidePart Number*DescriptionPackage Type OperatingTemperature/VoltageSi4831-B30-GU AM/FM Broadcast Radio Receiver 24L SSOP Pb-free –15 to 85°C 2.0 to 3.6V Si4835-B30-GUAM/FM/SW Broadcast Radio Receiver24L SSOP Pb-free–15 to 85°C 2.0 to 3.6V*Note: Add an “(R)” at the end of the device part number to denote tape and reel option. The devices will typically operate at25°C with degraded specifications for V DD voltage ramped down to 2.0V.Si4831/35-B3014SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•7. Package Markings (Top Marks)7.1. Si4831/35-B30 Top Mark7.2. Top Mark ExplanationMark Method:YAG Laser Line 1 Marking:Device identifier4831B30GU =Si4831-B304835B30GU =Si4835-B30Line 2 Marking:YY =YearWW =Work weekTTTTTT =Manufacturing codeAssigned by the Assembly House.4831B30GU YYWWTTTTTT 4835B30GU YYWWTTTTTTSi4831/35-B30SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************• 158. Package Outline: Si4831/35-B30The 24-pin SSOP illustrates the package details for the Si4831/35-B30. Table 9 lists the values for the dimensions shown in the illustration.Figure 3.24-Pin SSOP Table 9. Package DimensionsDimension Min Nom MaxA —— 1.75A10.10—0.25b 0.20—0.30c 0.10—0.25D 8.65 BSC E 6.00 BSC E1 3.90 BSC e 0.635 BSC L 0.40— 1.27θ0°—8°aaa 0.20bbb 0.18ccc 0.10ddd 0.10Notes:1.All dimensions shown are in millimeters (mm) unless otherwise noted.2. Dimensioning and Tolerancing per ANSI Y14.5M-1994.3. This drawing conforms to the JEDEC Solid State Outline MO-137, Variation AE.4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020 specificationfor Small Body Components.Si4831/35-B3016SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•9. PCB Land Pattern: Si4831/35-B30Figure 4, “PCB Land Pattern,” illustrates the PCB land pattern details for the Si4831/35-B30-GU SSOP . Table 10lists the values for the dimensions shown in the illustration.Figure 4.PCB Land Pattern Table 10. PCB Land Pattern DimensionsDimensionMin Max C 5.205.40E0.65 BSCX10.350.45Y11.55 1.75General:1.All dimensions shown are in millimeters (mm) unless otherwise noted.2. This land pattern design is based on the IPC-7351 guidelines.Solder Mask Design:3. All metal pads are to be non-solder mask defined (NSMD). Clearance between thesolder mask and the metal pad is to be 60µm minimum, all the way around the pad.Stencil Design:4. A stainless steel, laser-cut, and electro-polished stencil with trapezoidal wallsshould be used to assure good solder paste release.5. The stencil thickness should be 0.125mm (5 mils).6. The ratio of stencil aperture to land pad size should be 1:1 for all perimeter pads. Card Assembly:7. A No-Clean, Type-3 solder paste is recommended.8. The recommended card reflow profile is per the JEDEC/IPC J-STD-020specification for Small Body Components.Si4831/35-B30 10. Additional Reference ResourcesContact your local sales representatives for more information or to obtain copies of the following references:⏹EN55020 Compliance Test Certificate⏹AN555: Si483x-B Antenna, Schematic, Layout, and Design Guidelines⏹AN569: Si4831/35-DEMO Board Test Procedure⏹Si4831/35-DEMO Board User’s GuideSkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•17Si4831/35-B3018SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•D OCUMENT C HANGE L ISTRevision 0.1 to Revision 0.7⏹Updated block diagram.⏹Updated application schematic.⏹Updated bill of materials.⏹Updated Section “4.2. FM Receiver”.⏹Updated Section “4.3. AM Receiver”.⏹Updated Section “4.6. Band Select”.Revision 0.7 to Revision 1.0⏹Updated block diagram⏹Updated Table 2, “Absolute Maximum Ratings 1,2,” on page 4⏹Updated Table 5, “FM Receiver Characteristics 1,2,” on page 6⏹Updated Table 6, “AM/SW Receiver Characteristics 1, 2,” on page 7⏹Updated “4. Functional Description”⏹Updated “10. Additional Reference Resources”Si4831/35-B30 N OTES:SkyworksSolutions,Inc.•Phone[781]376-3000•Fax[781]376-3100•*********************•19Copyright © 2021 Skyworks Solutions, Inc. All Rights Reserved.Information in this document is provided in connection with Skyworks Solutions, Inc. (“Skyworks”) products or services. These materials, including the information contained herein, are provided by Skyworks as a service to its customers and may be used for informational purposes only by the customer. Skyworks assumes no responsibility for errors or omissions in these materials or the information contained herein. Skyworks may change its documentation, products, services, specifications or product descriptions at any time, without notice. Skyworks makes no commitment to update the materials or information and shall have no responsibility whatsoever for conflicts, incompatibilities, or other difficulties arising from any future changes.No license, whether express, implied, by estoppel or otherwise, is granted to any intellectual property rights by this document. Skyworks assumes no liability for any materials, products or information provided hereunder, including the sale, distribution, reproduction or use of Skyworks products, information or materials, except as may be provided in Skyworks’ Terms and Conditions of Sale.THE MATERIALS, PRODUCTS AND INFORMATION ARE PROVIDED “AS IS” WITHOUT WARRANTY OF ANY KIND, WHETHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, INCLUDING FITNESS FOR A PARTICULAR PURPOSE OR USE, MERCHANTABILITY, PERFORMANCE, QUALITY OR NON-INFRINGEMENT OF ANY INTELLECTUAL PROPERTY RIGHT; ALL SUCH WARRANTIES ARE HEREBY EXPRESSLY DISCLAIMED. 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Skyworks assumes no liability for applications assistance, customer product design, or damage to any equipment resulting from the use of Skyworks products outside of Skyworks’ published specifications or parameters.Skyworks, the Skyworks symbol, Sky5®, SkyOne ®, SkyBlue™, Skyworks Green™, Clockbuilder ®, DSPLL ®, ISOmodem ®, ProSLIC ®, and SiPHY ® are trademarks or registered trademarks of Skyworks Solutions, Inc. or its subsidiaries in the United States and other countries. Third-party brands and names are for identification purposes only and are the property of their respective owners. Additional information, including relevant terms and conditions, posted at , are incorporated by reference.PortfolioQuality/qualitySupport & Resources/support。