收藏本站
ADE7854/ADE7858/ADE7868/ADE7878
Integration Time Under A Steady Load
The discrete time sample period (T) for the accumulation register
is 125 μs (8 kHz frequency). With full-scale pure sinusoidal signals
on the analog inputs and a 90° phase difference between the vol-
tage and the current signal (the largest possible reactive power),
the average word value representing the reactive power is PMAX =
33,516,139 = 0x1FF6A6B. If the VARTHR threshold is set at the
PMAX level, this means the DSP generates a pulse that is added
at the var-hour registers every 125 μs.
The maximum value that can be stored in the var-hour
accumulation register before it overflows is 2 31 ? 1 or
0x7FFFFFFF. The integration time is calculated as
Time = 0x7FFF,FFFF × 125 μs = 74 hr 33 min 55 sec (38)
Energy Accumulation Modes
The reactive power accumulated in each var-hour accumulation
32-bit register (AVARHR, BVARHR, CVARHR, AFVARHR,
BFVARHR, and CFVARHR) depends on the configuration of
Data Sheet
In this mode, the ADE7858 / ADE7868 / ADE7878 transfer the
reactive energy accumulated in the 32-bit internal accumulation
registers into the xVARHR or xFVARHR registers after an
integral number of line cycles, as shown in Figure 72. The
number of half line cycles is specified in the LINECYC register.
The line cycle reactive energy accumulation mode is activated by
setting Bit 1 (LVAR) in the LCYCMODE register. The total reactive
energy accumulated over an integer number of half line cycles
or zero crossings is available in the var-hour accumulation registers
after the number of zero crossings specified in the LINECYC reg-
ister is detected. When using the line cycle accumulation mode,
Bit 6 (RSTREAD) of the LCYCMODE register should be set to
Logic 0 because a read with the reset of var-hour registers is not
available in this mode.
ZXSEL[0] IN
LCYCMODE[7:0]
ZERO-
CROSSING
DETECTION
(PHASE A)
Bits[5:4] (CONSEL[1:0]) in the ACCMODE register, in correlation
with the watt-hour registers. The different configurations are
described in Table 19. Note that IA ’ /IB ’ /IC ’ are the phase-shifted
current waveforms.
Table 19. Inputs to Var-Hour Accumulation Registers
ZXSEL[1] IN
LCYCMODE[7:0]
ZERO-
CROSSING
DETECTION
(PHASE B)
ZXSEL[2] IN
LINECYC[15:0]
CALIBRATION
CONTROL
CONSEL[1:0]
AVARHR,
AFVARHR
BVARHR,
BFVARHR
CVARHR,
CFVARHR
ZERO-
LCYCMODE[7:0]
00
01
10
VA × IA’
VA × IA’
VA × IA’
VB × IB’
0
VB × IB’
VC × IC’
VC × IC’
VC × IC’
CROSSING
DETECTION
(PHASE C)
VB = ?VA ? VC
AVAROS
11
VA × IA’
VB × IB’
VC × IC’
AVARGAIN
AVARHR[31:0]
VB = ?VA
OUTPUT
FROM
Bits[3:2] (VARACC[1:0]) in the ACCMODE register determine
TOTAL
REACTIVE
POWER
ACCUMULATOR
VARTHR[47:0]
32-BIT
REGISTER
how CF frequency output can be a generated function of the total
and fundamental reactive powers. While the var-hour accumu-
lation registers accumulate the reactive power in a signed
format, the frequency output can be generated in either the signed
mode or the sign adjusted mode function of VARACC[1:0]. See
the Energy-to-Frequency Conversion section for details.
Line Cycle Reactive Energy Accumulation Mode
As mentioned in the Line Cycle Active Energy Accumulation
Mode section, in line cycle energy accumulation mode, the
energy accumulation can be synchronized to the voltage
channel zero crossings so that reactive energy can be accu-
mulated over an integral number of half line cycles.
ALGORITHM
Figure 72. Line Cycle Total Reactive Energy Accumulation Mode
Phase A, Phase B, and Phase C zero crossings are, respectively,
included when counting the number of half line cycles by setting
Bits[5:3] (ZXSEL[x]) in the LCYCMODE register. Any combi-
nation of the zero crossings from all three phases can be used
for counting the zero crossing. Select only one phase at a time
for inclusion in the zero-crossings count during calibration.
For details on setting the LINECYC register and the Bit 5
(LENERGY) in the MASK0 interrupt mask register associated
with the line cycle accumulation mode, see the Line Cycle
Active Energy Accumulation Mode section.
Rev. H | Page 56 of 100
发布紧急采购,3分钟左右您将得到回复。

采购需求

(若只采购一条型号,填写一行即可)

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

*型号 *数量 厂商 批号 封装
添加更多采购

我的联系方式

*
*
*
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