参数资料
| 型号: | CBC-EVAL-08 |
| 厂商: | Cymbet Corporation |
| 文件页数: | 8/11页 |
| 文件大小: | 0K |
| 描述: | ENERCHIP EH SEH EVAL KIT |
| 产品目录绘图: | CBC-EVAL-08 Module |
| 特色产品: | EnerChip? EH Solar Energy Harvesting Evaluation Kit |
| 标准包装: | 1 |
| 系列: | EnerChip™ EH |
| 主要目的: | 电源管理,可再生能源 |
| 嵌入式: | 否 |
| 已用 IC / 零件: | CBC5300 |
| 主要属性: | 薄膜充电式固态电池 |
| 次要属性: | 太阳能收集器 |
| 已供物品: | 板 |
| 相关产品: | 859-1009-6-ND - IC BATT SOLID ST ENERCHIP 16QFN 859-1009-1-ND - IC BATT SOLID ST ENERCHIP 16QFN 859-1009-2-ND - IC BATT SOLID ST ENERCHIP 16QFN 859-1005-5-ND - IC BATT SOLID ST ENERCHIP 16QFN |
| 其它名称: | 859-1002 |
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�EnerChip� Solar� Energy� Harvesting� Demo� Kit�
�While� it� is� relatively� straightforward� to� calculate� a� power� budget� and� design� a� system� to� work� within� the�
�constraints� of� the� power� and� energy� available,� it� is� easy� to� overlook� the� power� required� to� initialize� the� system�
�to� a� known� state� and� to� complete� the� radio� link� with� the� host� system� or� peer� nodes� in� a� mesh� network.� The�
�initialization� phase� can� sometimes� take� two� to� three� times� the� power� needed� for� steady� state� operation.�
�Ideally,� the� hardware� should� be� in� a� low� power� state� when� the� system� power-on� reset� is� in� its� active� state.� If�
�this� is� not� possible,� the� microcontroller� should� place� the� hardware� in� a� low� power� state� as� soon� as� possible.�
�After� this� is� done,� the� microcontroller� should� be� put� into� a� sleep� state� long� enough� for� the� energy� harvester�
�to� replenish� the� energy� storage� device.� If� the� power� budget� is� not� exceeded� during� this� phase,� the� system�
�can� continue� with� its� initialization.� Next,� the� main� initialization� of� the� system,� radio� links,� analog� circuits,� and�
�so� forth,� can� begin.� Care� should� be� taken� to� ensure� that� the� time� the� system� is� on� during� this� phase� does�
�not� exceed� the� power� budget.� Several� sleep� cycles� might� be� needed� to� ‘stairstep’� the� system� up� to� its� main�
�operational� state.� The� Cymbet� CBC5300� energy� harvester� module� has� a� handshake� line� CHARGE� to� indicate�
�to� the� microcontroller� when� energy� is� available.� Another� way� to� know� whether� energy� is� available� is� to� have� the�
�microcontroller� monitor� the� voltage� on� its� power� bus� using� one� its� internal� A/D� converters.�
�Circuit� Recommendations� to� Save� Power�
�In� most� system� power� budgets,� the� peak� power� required� is� not� as� critical� as� the� length� of� time� the� power�
�is� required.� Careful� selection� of� the� message� protocol� for� the� RF� link� can� have� a� significant� impact� on� the�
�overall� power� budget.� In� many� cases,� using� higher� power� analog� circuits� that� can� be� turned� on,� settle� quickly,�
�and� be� turned� off� can� decrease� the� overall� energy� consumed.� Microcontroller� clock� frequency� can� also� have�
�a� significant� impact� on� the� power� budget.� In� some� applications� it� might� be� advantageous� to� use� a� higher�
�microcontroller� clock� frequency� to� reduce� the� time� the� microcontroller� and� peripheral� circuits� are� active.� Avoid�
�using� circuits� that� bias� microcontroller� digital� inputs� to� mid-level� voltages;� this� can� cause� significant� amounts�
�of� parasitic� currents� to� flow.� Use� 10M� to� 22M� pull-up/down� resistors� where� possible.� However,� be� aware�
�that� high� circuit� impedances� coupled� with� parasitic� capacitance� can� make� for� a� slow� rise/fall� time� that� can�
�place� the� voltage� on� the� microcontroller� inputs� at� mid-levels,� resulting� in� parasitic� current� flow.� One� solution� to�
�the� problem� is� to� enable� the� internal� pull-up/down� resistor� of� the� microcontroller� input� to� force� the� input� to� a�
�known� state,� then� disable� the� resistor� when� it’s� time� to� check� the� state� of� the� line.� If� using� the� microcontroller’s�
�internal� pull-up/down� resistors� on� the� inputs� to� bias� push-button� switches� in� a� polled� system,� leave� the� pull-up/�
�down� resistor� disabled� and� enable� the� resistor� only� while� checking� the� state� of� the� input� port.� Alternatively,� in�
�an� interrupt-driven� system,� disable� the� pull-up/down� resistor� within� the� first� few� instructions� in� the� interrupt�
�service� routine.� Enable� the� pull-up/down� resistor� only� after� checking� that� the� switch� has� been� opened.�
�Microcontroller� pull-up/down� resistors� are� typically� less� than� 100k� and� will� be� a� huge� load� on� the� system� if�
�left� on� continuously� while� a� button� is� being� pressed� or� if� held� for� any� significant� length� of� time.� For� even� greater�
�reduction� in� power,� use� external� pull-up/down� resistors� in� the� 10M� to� 22M� range.� Bias� the� external� resistor�
�not� with� the� power� rail� but� with� a� microcontroller� port.� The� same� algorithm� used� for� internal� pull-up/down�
�resistors� can� then� be� used� to� save� power.� The� CHARGE� line� on� the� CBC5300� has� a� 10M� pull-up� resistor� with�
�a� very� slow� rise� time.� Use� an� internal� microcontroller� pull-down� resistor� to� force� the� CHARGE� line� low� all� of� the�
�time� and� then� disable� the� pull-down� resistor� to� check� the� state� of� the� line.� This� will� keep� the� CHARGE� line� from�
�biasing� the� input� at� mid� level� for� long� periods� of� time� which� could� case� large� parasitic� currents� to� flow.�
�The� CBC5300� energy� harvester� module� has� a� feature� for� disabling� the� on-board� EnerChip� thin� film� storage�
�devices.� A� handshake� line� BATOFF� is� provided� for� use� of� this� feature.� A� high� level� will� disable� the� EnerChips.�
�This� is� useful� in� very� low� ambient� energy� conditions� to� steer� all� of� the� available� energy� into� the� load.� EnerChip�
�devices� have� very� low� self-discharge� rates� (typically� 2.5%� per� year)� so� it� is� not� necessary� to� continuously� charge�
�them.�
�DS-72-08� Rev18�
�?2009� Cymbet� Corporation� ?� Tel:� +1-763-633-1780� ?� www.cymbet.com�
�Page� 8� of� 11�
�相关PDF资料 |
PDF描述 |
|---|---|
| CBC-EVAL-09 | ENERCHIP EP ENERGY HARVEST EVAL |
| CBC-EVAL-11 | INDUCTIVE CHARGING EVAL KIT |
| CBJ157 | TRS JACK STR PCB SLD POT 3-LUG |
| CBJ70 | TRB JACK STR PCB 3-LUG |
| CBJR12 | MINI-WECO PATCH JACK 75OHM R/A |
相关代理商/技术参数 |
参数描述 |
|---|---|
| CBC-EVAL-08_10 | 制造商:CYMBET 制造商全称:CYMBET 功能描述:EnerChipa?¢ EH Solar Energy Harvester Evaluation Kit |
| CBC-EVAL-09 | 功能描述:电源管理IC开发工具 EnerChip EP Universal EH Kit RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| CBC-EVAL-09 - DSC | 功能描述:CBC915-ACA, CBC51100 EnerChip? Series Power Management, Energy Harvesting Evaluation Board 制造商:cymbet corporation 系列:EnerChip?? 零件状态:有效 主要用途:电源管理,能量收集 嵌入式:否 使用的 IC/零件:CBC915-ACA,CBC51100 主要属性:EM/RF,太阳能,热能,振动能量处理器 辅助属性:- 所含物品:板 标准包装:1 |
| CBC-EVAL-09_13 | 制造商:CYMBET 制造商全称:CYMBET 功能描述:EnerChip EP Universal Energy Harvester Eval Kit |
| CBC-EVAL-10 | 功能描述:电源管理IC开发工具 EnerChip CCEH EH Kit RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
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