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| 型号: | ADE7759ARSZ |
| 厂商: | Analog Devices Inc |
| 文件页数: | 23/36页 |
| 文件大小: | 0K |
| 描述: | IC ENERGY METERING 1PHASE 20SSOP |
| 标准包装: | 66 |
| 输入阻抗: | 390 千欧 |
| 测量误差: | 0.1% |
| 电压 - 高输入/输出: | 2.4V |
| 电压 - 低输入/输出: | 0.8V |
| 电流 - 电源: | 3mA |
| 电源电压: | 4.75 V ~ 5.25 V |
| 测量仪表类型: | 单相 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 20-SSOP(0.209",5.30mm 宽) |
| 供应商设备封装: | 20-SSOP |
| 包装: | 管件 |
| 产品目录页面: | 797 (CN2011-ZH PDF) |
| 配用: | EVAL-ADE7759EBZ-ND - BOARD EVALUATION FOR ADE7759 |
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�ADE7759�
�load� conditions.� This� output� frequency� can� provide� a� simple,�
�single-wire,� optically� isolated� interface� to� external� calibration�
�equipment.� Figure� 38� illustrates� the� energy-to-frequency� con-�
�version� in� the� ADE7759.�
�The� energy-to-frequency� conversion� is� accomplished� by� accu-�
�mulating� the� active� power� signal� in� a� 24-bit� register.� An� output�
�pulse� is� generated� when� there� is� a� zero� to� one� transition� on� the�
�MSB� (most� significant� bit)� of� the� register.� Under� steady� load� con-�
�ditions� the� output� frequency� is� proportional� to� the� active� power.�
�The� output� frequency� at� CF,� with� full-scale� ac� signals� on�
�Channel� 1� and� Channel� 2� and� CFDEN� =� 000h,� CFNUM� =� 000h,�
�and� APGAIN� =� 000h,� is� approximately� 5.593� kHz.� This� can� be�
�calculated� as� follows:�
�output.� Therefore,� the� content� of� CFDEN� should� always� be� set�
�no� less� than� that� of� the� CFNUM� register,� i.e.,� the� maximum�
�output� frequency� from� CF� pin� will� never� exceed� that� of� the� ETF�
�output.� The� power-up� default� value� for� CFDEN� is� 3Fh� and�
�CFNUM� is� 0h.�
�The� output� frequency� will� have� a� slight� ripple� at� a� frequency�
�equal� to� twice� the� line� frequency.� This� is� due� to� imperfect� filter-�
�ing� of� the� instantaneous� power� signal� to� generate� the� active�
�power� signal—see� Active� Power� Calculation� section.� Equation� 3�
�gives� an� expression� for� the� instantaneous� power� signal.� This� is�
�filtered� by� LPF2,� which� has� a� magnitude� response� given� by�
�Equation� 10:�
�With� the� active� power� gain� register� set� to� 000h,� the� average�
�value� of� the� instantaneous� power� signal� (output� of� LPF2)� is�
�H� (� f� )� =�
�1�
�1� +� f� /� 8� .� 9� Hz�
�(10)�
�CCCDh� or� 52,429� decimal.� An� output� frequency� is� generated�
�on� CF� when� the� MSB� in� the� energy-to-frequency� register� (24� bits)�
�The� active� power� signal� (output� of� LPF2)� can� be� rewritten� as:�
�?� cos� (� 4� π� f� l� t� )�
�p� (� t� )� =� VI� ?� ?�
�toggles,� i.e.,� when� the� register� accumulates� 2� 23� .� This� means� the�
�register� is� updated� 2� 23� /CCCDh� times� (or� 159.999� times).� Since�
�the� update� rate� is� 4/CLKIN� or� 1.1175� μ� s,� the� time� between�
�MSB� toggles� (CF� pulses)� is� given� as:�
�?� VI� ?�
�?� 1� +� 2� f� l� /� 8� .� 9� Hz� ?�
�(11)�
�ETF� Output� (� Hz� )� =�
�?� sin� (� 4� π� f� l� t� )�
�?� VI� ?�
�?� ?� 4� π� f� l� (� 1� +� 2� f� l� /� 8� .� 9� Hz� )� ?� ?�
�159� .� 999� ·� 1� .� 1175� m� s� =� 1� .� 78799� ·� 10� –� 4� s� (� 5592� .� 86� Hz� )�
�Equation� 8� gives� an� expression� for� the� output� frequency� at� the�
�Energy-to-Frequency� (ETF)� output� with� the� contents� of� CFDEN�
�and� CFNUM� registers� are� both� zero.�
�Average LPF� 2� Output� � CLKIN�
�(8)�
�2� 25�
�This� output� frequency� is� easily� scaled� by� a� pair� of� calibration�
�frequency� divider� registers� (CFDEN[11:0]� and� CFNUM[11:0]).�
�These� frequency� scaling� registers� are� 12-bit� registers� that� can�
�scale� the� output� frequency� by� 1� to� 2� 12� .� The� output� frequency� is�
�given� by� the� expression� below:�
�where� f� l� is� the� line� frequency� (e.g.,� 60� Hz).�
�From� Equation� 6:�
�E� (� t� )� =� VIt� ?� ?� (12)�
�From� Equation� 12� it� can� be� seen� that� there� is� a� small� ripple� in�
�the� energy� calculation� due� to� a� sin(2� ω� t)� component.� This� is�
�shown� in� Figure� 39.� The� active� energy� calculation� is� shown� by�
�the� dashed� straight� line� and� is� equal� to� V� � I� � t.� The� sinusoidal�
�ripple� in� the� active� energy� calculation� is� also� shown.� Since� the�
�average� value� of� a� sinusoid� is� zero,� this� ripple� will� not� contribute�
�to� the� energy� calculation� over� time.� However,� the� ripple� can� be�
�CF� (� Hz� )� =� ETF� Output� (� Hz� )� �
�CFNUM� [11: 0 ]� +� 1�
�CFDEN� [� 11� :� 0� ]� +� 1�
�(9)�
�observed� in� the� frequency� output,� especially� at� higher� output�
�frequencies.� The� ripple� will� get� larger� as� a� percentage� of� the�
�frequency� at� larger� loads� and� higher� output� frequencies.� The� rea-�
�For� example,� if� the� CF� output� frequency� is� 5.59286� kHz� while�
�the� contents� of� CFNUM� and� CFDEN� are� zero,� the� CF� output�
�frequency� can� be� set� to� 25� Hz� by� writing� 8� BDh� (2237� in� deci-�
�mal)� to� the� CFDEN� register� and� 00Ah� (10� in� decimal)� to� the�
�CFNUM� register.� Note� that� the� CFNUM� and� CFDEN� regis-�
�ters� are� meant� only� to� scale� down� the� frequency� from� the� ETF�
�son� is� that� at� higher� output� frequencies� the� integration� or� averaging�
�time� in� the� energy-to-frequency� conversion� process� is� shorter.� As�
�a� consequence,� some� of� the� sinusoidal� ripple� is� observable� in� the�
�frequency� output.� Choosing� a� lower� output� frequency� at� CF� for�
�calibration� can� significantly� reduce� the� ripple.� Also,� averaging� the�
�output� frequency� by� using� a� longer� gate� time� for� the� counter� will�
�achieve� the� same� results.�
�15�
�APOS� [15:0]�
�0�
�SIGN�
�2� 6�
�2� 5�
�2� 4�
�2� 3�
�2� 2�
�2� 1�
�2� 0�
�2� –1� 2� –2� 2� –3� 2� –4� 2� –5� 2� –6� 2� –7� 2� –8�
�20�
�LPF2�
�+�
�+�
�23�
�WAVEFORM� [23:0]�
�0�
�ACTIVE� POWER� OFFSET�
�CALIBRATION�
�ENERGY-TO-FREQUENCY�
�ACTIVE� POWER�
�23�
�0�
�+�
�SIGNAL� –� P�
�11�
�11�
�CFNUM� [11:0]�
�CFDEN� [11:0]�
�0�
�0�
�MSB�
�TRANSITION�
�+�
�CF�
�Figure� 38.� Energy-to-Frequency� Conversion�
�REV.� A�
�–23� –�
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