- 您现在的位置:买卖IC网 > Sheet目录1214 > EVAL-ADE7878EBZ (Analog Devices Inc)BOARD EVAL FOR ADE7878
��
�
�ADE7854/ADE7858/ADE7868/ADE7878�
�Sign� of� Reactive� Power� Calculation�
��summarizes� the� relationship� between� the� phase� difference� between�
�the� voltage� and� the� current� and� the� sign� of� the� resulting� reactive�
�power� calculation.�
�The� ADE7858� /� ADE7868� /� ADE7878� have� sign� detection� circuitry�
�for� reactive� power� calculations� that� can� monitor� the� total� reactive�
�Data� Sheet�
�Both� total� and� fundamental� reactive� energy� accumulations� are�
�always� a� signed� operation.� Negative� energy� is� subtracted� from�
�the� reactive� energy� contents.�
��achieve� the� integration� of� the� reactive� power� signal� in� two�
�stages� (see� Figure� 71).� The� process� is� identical� for� both� total� and�
�fundamental� reactive� powers.�
�powers� or� the� fundamental� reactive� powers.� As� described� in� the�
��mulation� is� executed� in� two� stages.� Every� time� a� sign� change� is�
�detected� in� the� energy� accumulation� at� the� end� of� the� first� stage,�
�that� is,� after� the� energy� accumulated� into� the� internal� accumulator�
�reaches� the� VARTHR� register� threshold,� a� dedicated� interrupt� is�
�triggered.� The� sign� of� each� phase� reactive� power� can� be� read� in�
�the� PHSIGN� register.� Bit� 7� (REVRPSEL)� in� the� ACCMODE�
�register� sets� the� type� of� reactive� power� being� monitored.� When�
�REVRPSEL� is� 0,� the� default� value,� the� total� reactive� power� is�
�monitored.� When� REVRPSEL� is� 1,� then� the� fundamental�
�reactive� power� is� monitored.�
�?�
�?�
�The� first� stage� is� conducted� inside� the� DSP:� every� 125� μs�
�(8� kHz� frequency),� the� instantaneous� phase� total� reactive�
�or� fundamental� power� is� accumulated� into� an� internal�
�register.� When� a� threshold� is� reached,� a� pulse� is� generated�
�at� the� processor� port� and� the� threshold� is� subtracted� from�
�the� internal� register.� The� sign� of� the� energy� in� this� moment�
���The� second� stage� is� performed� outside� the� DSP� and� consists�
�in� accumulating� the� pulses� generated� by� the� processor� into�
�internal� 32-bit� accumulation� registers.� The� content� of� these�
�registers� is� transferred� to� the� var-hour� registers� (xVARHR� and�
�PMAX� � f� s� � 3600� � 10� n�
�V� FS� � I� FS�
�Bits[12:10]� (REVRPC,� REVRPB,� and� REVRPA,� respectively)�
�in� the� STATUS0� register� are� set� when� a� sign� change� occurs� in�
�the� power� selected� by� Bit� 7� (REVRPSEL)� in� the� ACCMODE�
�register.�
�Bits[6:4]� (CVARSIGN,� BVARSIGN,� and� AVARSIGN,� respectively)�
�in� the� PHSIGN� register� are� set� simultaneously� with� the� REVRPC,�
�REVRPB,� and� REVRPA� bits.� They� indicate� the� sign� of� the� reactive�
�power.� When� they� are� 0,� the� reactive� power� is� positive.� When�
�they� are� 1,� the� reactive� power� is� negative.�
�Bit� REVRPx� of� the� STATUS0� register� and� Bit� xVARSIGN� in� the�
�PHSIGN� register� refer� to� the� reactive� power� of� Phase� x,� the�
�power� type� being� selected� by� Bit� REVRPSEL� in� ACCMODE�
�register.�
�Setting� Bits[12:10]� in� the� MASK0� register� enables� the� REVRPC,�
�REVRPB,� and� REVRPA� interrupts,� respectively.� If� enabled,� the�
�IRQ0� pin� is� set� low� and� the� status� bit� is� set� to� 1� whenever� a� change�
�of� sign� occurs.� To� find� the� phase� that� triggered� the� interrupt,�
�the� PHSIGN� register� is� read� immediately� after� reading� the�
�STATUS0� register.� Next,� the� status� bit� is� cleared� and� the� IRQ0�
�pin� is� set� to� high� by� writing� to� the� STATUS0� register� with� the�
�corresponding� bit� set� to� 1.�
�Table� 18.� Sign� of� Reactive� Power� Calculation�
�xFVARHR)� when� these� registers� are� accessed.� AVARHR,�
�BVARHR,� CVARHR,� AFWATTHR,� BFWATTHR,� and�
�CFWATTHR� represent� phase� fundamental� reactive� powers.�
��this� process.� The� VARTHR� 48-bit� signed� register� contains� the�
�threshold� and� it� is� introduced� by� the� user.� It� is� common� for� both�
�total� and� fundamental� phase� reactive� powers.� Its� value� depends�
�on� how� much� energy� is� assigned� to� one� LSB� of� var-hour�
�registers.� When� a� derivative� of� reactive� energy� (varh)� of� [10� n�
�varh],� where� n� is� an� integer,� is� desired� as� one� LSB� of� the�
�xVARHR� register;� then,� the� xVARTHR� register� can� be� computed�
�using� the� following� equation:�
�VARTHR� =�
�where:�
�PMAX� =� 33,516,139� =� 0x1FF6A6B,� the� instantaneous� power�
�computed� when� the� ADC� inputs� are� at� full� scale.�
�f� S� =� 8� kHz,� the� frequency� with� which� the� DSP� computes� the�
�instantaneous� power.�
�V� FS� ,� I� FS� are� the� rms� values� of� phase� voltages� and� currents� when�
�the� ADC� inputs� are� at� full� scale.�
�The� maximum� value� that� may� be� written� on� the� VARTHR�
�Φ� 1�
�Between� 0� to� +180�
�Between� ?180� to� 0�
�Between� 0� to� +180�
�Between� ?180� to� 0�
�Integrator�
�Off�
�Off�
�On�
�On�
�Sign� of� Reactive� Power�
�Positive�
�Negative�
�Positive�
�Negative�
�register� is� 2� 47� ?� 1.� The� minimum� value� is� 0x0,� but� it� is�
�recommended� to� write� a� number� equal� to� or� greater� than�
�PMAX.� Never� use� negative� numbers.�
�VARTHR� is� a� 48-bit� register.� As� previously� stated� in� the� Voltage�
��� is� defined� as� the� phase� angle� of� the� voltage� signal� minus� the� current�
�1�
�signal;� that� is,� Φ� is� positive� if� the� load� is� inductive� and� negative� if� the� load� is�
�capacitive.�
�Reactive� Energy� Calculation�
�Reactive� energy� is� defined� as� the� integral� of� reactive� power.�
��the� WTHR� register� shown� in� Figure� 69,� VARTHR� is� accessed� as�
�two� 32-bit� registers� (VARTHR1� and� VARTHR0),� each� having� eight�
�MSBs� padded� with� 0s.�
�Reactive� Energy� =� ∫� q(t)dt�
�(36)�
�Rev.� H� |� Page� 54� of� 100�
�发布紧急采购,3分钟左右您将得到回复。
相关PDF资料
EVAL-ADE7880EBZ
BOARD EVAL FOR ADE7880
EVAL-ADE7953EBZ
BOARD EVAL FOR ADE7953
EVAL-ADF4002EBZ1
BOARD EVAL FOR ADF4002
EVAL-ADG788EBZ
BOARD EVALUATION FOR ADG788
EVAL-ADM1021AEB
BOARD EVAL FOR ADM1021
EVAL-ADM1023EB
BOARD EVAL FOR ADM1023
EVAL-ADM1031EB
BOARD EVAL FOR ADM1031
EVAL-ADM1062TQEBZ
BOARD EVALUATION FOR ADM1062TQ
相关代理商/技术参数
EVAL-ADE7880EBZ
功能描述:BOARD EVAL FOR ADE7880 RoHS:是 类别:编程器,开发系统 >> 评估演示板和套件 系列:* 产品培训模块:Obsolescence Mitigation Program 标准包装:1 系列:- 主要目的:电源管理,电池充电器 嵌入式:否 已用 IC / 零件:MAX8903A 主要属性:1 芯锂离子电池 次要属性:状态 LED 已供物品:板
EVAL-ADE7880EBZ
制造商:Analog Devices 功能描述:ADE7880, ENERGY METER, 3 PH, SPI, I2C, E
EVAL-ADE7913EBZ
制造商:AD 制造商全称:Analog Devices 功能描述:3-Channel, Isolated, Sigma-Delta ADC with SPI
EVAL-ADE7953EBZ
功能描述:BOARD EVAL FOR ADE7953 RoHS:是 类别:编程器,开发系统 >> 评估演示板和套件 系列:- 标准包装:1 系列:PSoC® 主要目的:电源管理,热管理 嵌入式:- 已用 IC / 零件:- 主要属性:- 次要属性:- 已供物品:板,CD,电源
EVAL-ADF4001EBZ2
制造商:Analog Devices 功能描述:Evaluation Board For Pll Frequency Synthesizer 制造商:Analog Devices 功能描述:ADF4001 PLL SYNTHESIZER EVAL BOARD
EVAL-ADF4002EB1
制造商:Analog Devices 功能描述:EVAL BOARD - Bulk
EVAL-ADF4002EBZ1
功能描述:BOARD EVAL FOR ADF4002 RoHS:是 类别:编程器,开发系统 >> 评估演示板和套件 系列:- 产品培训模块:Obsolescence Mitigation Program 标准包装:1 系列:- 主要目的:电源管理,电池充电器 嵌入式:否 已用 IC / 零件:MAX8903A 主要属性:1 芯锂离子电池 次要属性:状态 LED 已供物品:板
EVAL-ADF4007EBZ1
功能描述:BOARD EVALUATION FOR ADF4007EB1 RoHS:是 类别:编程器,开发系统 >> 评估演示板和套件 系列:- 标准包装:1 系列:PSoC® 主要目的:电源管理,热管理 嵌入式:- 已用 IC / 零件:- 主要属性:- 次要属性:- 已供物品:板,CD,电源