HO 240-P-0100

**Current Transducer HO-P series** 

_I_ **PN = 60, 100, 120, 180, 240, 250 A** 

## **Ref: HO 60-P, HO 100-P, HO 120-P, HO 180-P, HO 240-P, HO 250-P** 

**For the electronic measurement of current: DC, AC, pulsed..., with galvanic separation between the primary and the secondary circuit.** 

## **Features** 

- ●Open loop multi-range current transducer 

- ●Voltage output 

- ●Single power supply +5 V 

- ●Over-current detect 2.93 × _I_ PN (peak value) 

- ●EEPROM Control 

- ●Galvanic separation between primary and secondary circuit 

- ●Low power consumption 

- ●Compact design for THT PCB mounting 

- ●Aperture: 15 × 8 mm 

- ●Factory calibrated 

- **Dedicated parameter settings available on request (see page 12).** 

## **Advantages** 

- ●Low offset drift 

- ●Over-drivable _V_ ref 

- ●8 mm creepage/clearance 

## **Applications** 

- ●AC variable speed and servo motor drives 

- ●Static converters for DC motor drives 

- ●Battery supplied applications 

- ●Uninterruptible Power Supplies (UPS) 

- ●Switched Mode Power Supplies (SMPS) 

- ●Power supplies for welding applications 

- ●Combiner box 

- ●MPPT. 

## **Standards** 

- ●EN 50178: 1997 

- ●IEC 61010-1: 2010 

- ●IEC 61326-1: 2012 

- ●UL 508: 2010. 

## **Application Domain** 

   - ●Industrial. 

- ●Fast response. 

N°97.K4.27.000.0; N°97.K4.34.000.0; N°97.K4.36.000.0; N°97.K4.42.000.0; N°97.K4.D4.000.0; N°97.K4.45.000.0 16July2015/Version 5 

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LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

www.lem.com 

**HO 60 .. 250-P series** 

## **Absolute maximum ratings** 

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Parameter Symbol Unit Value<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Value**|
|---|---|---|---|
|||||
|Supply voltage (not destructive)|_U_C|V|8|
|Supply voltage (not entering non standard modes)|_U_C|V|6.5|
|Primary conductor temperature|_T_B|°C|120|
|ESD rating, Human Body Model (HBM)|_U_ESD|kV|2|



Stresses above these ratings may cause permanent damage. Exposure to absolute maximum ratings for extended periods may degrade reliability. 

## **UL 508: Ratings and assumptions of certification** 

File # E189713 Volume: 2 Section: 5 

## **Standards** 

- ●CSA C22.2 NO. 14-10 INDUSTRIAL CONTROL EQUIPMENT - Edition 11 - Revision Date 2011/08/01 

- ●UL 508 STANDARD FOR INDUSTRIAL CONTROL EQUIPMENT - Edition 17 - Revision Date 2010/04/15 

## **Ratings** 

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Parameter Symbol Unit Value<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Value**|
|---|---|---|---|
|||||
|Primary involved potential||V AC/DC|600|
|Max surrounding air temperature|_T_A|°C|105|
|Primary current|_I_P|A|According to series primary<br>current|
|Secondary supply voltage|_U_C|V DC|5|
|Output voltage|_V_out|V|0 to 5|



## **Conditions of acceptability** 

- _1 - These devices have been evaluated for overvoltage category III and for use in pollution degree 2 environment._ 

- _2 - A suitable enclosure shall be provided in the end-use application._ 

- _3 - The terminals have not been evaluated for field wiring._ 

- _4 -  These devices are intended to be mounted on a printed wiring board of end use equipment. The suitability of the connections (including spacings) shall be determined in the end-use application._ 

- _5 - Primary terminals shall not be straightened since assembly of housing case depends upon bending of the terminals._ 

- _6 - Any surface of polymeric housing have not been evaluated as insulating barrier._ 

- _7 -  Low voltage control circuit shall be supplied by an isolating source (such as a transformer, optical isolator, limiting impedance or electro-mechanical relay)._ 

- _10 - The jumper installed within the primary hole is only intended for fixing the sensor and not for carrying the primary current._ 

## **Marking** 

Only those products bearing the UR Mark should be considered to be Listed or Recognized and covered under UL's Follow-Up Service. Always look for the Mark on the product. 

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16July2015/Version 5 

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**HO 60 .. 250-P series** 

## **Insulation coordination** 

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**----- Start of picture text -----**<br>
Parameter Symbol Unit Value Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Value**|**Comment**|
|---|---|---|---|---|
||||||
|Rms voltage for AC insulation test 50/60 Hz/1 min|_U_d|kV|4.3||
|Impulse withstand voltage 1.2/50 µs|_ÛW_|kV|8||
|Partial discharge extinction rms voltage @ 10 pC|_U_e|V|> 1170|Busbar / Secondary + jumpers|
|Clearance (pri. - sec.)|_d_CI|mm|> 8|Shortest distance through air|
|Creepage distance (pri. - sec.)|_d_Cp|mm|> 8|Shortest path along device body|
|Clearance (pri. - sec.)|-|mm|> 8|When mounted on PCB with<br>recommended layout|
|Case material|-|-|V0 according to<br>UL 94||
|Comparative tracking index|_CTI_||600||
|Application example|-|-|600 V<br>CAT III PD2|Reinforced insulation, non<br>uniform feld according to<br>EN 50178, EN 61010|
|Application example|-|-|1000 V<br>CAT III PD2|Based insulation, non uniform<br>feld according to<br>EN 50178, EN 61010|
|Application example|-|-|600 V<br>CAT III PD2|Simple insulation, non uniform<br>feld according to UL 508|



## **Environmental and mechanical characteristics** 

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Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Ambient operating temperature|_T_A|°C|−40||105||
|Ambient storage temperature|_T_S|°C|−40||105||
|Mass|_m_|g||34|||



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LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

16July2015/Version 5 

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**HO 60 .. 250-P series** 

## **Electrical data HO 60-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

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**----- Start of picture text -----**<br>
Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||60|||
|Primary current, measuring range|_I_PM|A|−150||150|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−0.375||0.375||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−5.625||5.625|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||13.333||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus-bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.75||0.75||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||9.2||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||5.0<br>13.8<br>26.0|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|−1.25||1.25||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|−4.80||4.80|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|−3.91||3.91|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). 

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LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

16July2015/Version 5 

www.lem.com 

**HO 60 .. 250-P series** 

## **Electrical data HO 100-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

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Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||100|||
|Primary current, measuring range|_I_PM|A|−250||250|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−0.625||0.625||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−9.375||9.375|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||8||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.5||0.5||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||6||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||3.6<br>8.7<br>16.9|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|−1||1||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|−4.55||4.55|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|−3.66||3.66|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). 

Page 5/15 

LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

16July2015/Version 5 

www.lem.com 

**HO 60 .. 250-P series** 

## **Electrical data HO 120-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

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Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||120|||
|Primary current, measuring range|_I_PM|A|−300||300|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−0.75||0.75||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−11.25||11.25|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||6.667||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus-bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.5||0.5||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||5.3||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||3.2<br>7.5<br>14.6|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|-1||1||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|-4.55||4.55|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|-3.66||3.66|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). 

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LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

16July2015/Version 5 

www.lem.com 

**HO 60 .. 250-P series** 

## **Electrical data HO 180-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

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Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||180|||
|Primary current, measuring range|_I_PM|A|−450||450|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−1.13||1.13||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−16.9||16.9|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||4.444||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus-bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.5||0.5||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||4||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||2.7<br>5.4<br>10.8|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|−1||1||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|−4.55||4.55|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|−3.66||3.66|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). LEM reserves the right to carry out modifications on its transducers, in order to improve them, without prior notice 

Page 7/15 

16July2015/Version 5 

www.lem.com 

**HO 60 .. 250-P series** 

## **Electrical data HO 240-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

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Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||240|||
|Primary current, measuring range|_I_PM|A|−600||600|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−1.5||1.5||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−22.5||22.5|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||3.333||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus-bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.5||0.5||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||3.5||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||2.5<br>5<br>8.7|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|−1||1||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|−4.55||4.55|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|−3.66||3.66|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). 

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**HO 60 .. 250-P series** 

## **Electrical data HO 250-P-0100** 

At _T_ A = 25 °C, _U_ C = +5 V, _R_ L = 10 kΩ unless otherwise noted (see Min, Max, typ. definition paragraph in page 13). 

**==> picture [512 x 18] intentionally omitted <==**

**----- Start of picture text -----**<br>
Parameter Symbol Unit Min Typ Max Comment<br>**----- End of picture text -----**<br>


|**Parameter**|**Symbol**|**Unit**|**Min**|**Typ**|**Max**|**Comment**|
|---|---|---|---|---|---|---|
||||||||
|Primary nominal rms current|_I_**PN**|A||250|||
|Primary current, measuring range|_I_PM|A|−625||625|@_U_C≥ 4.6 V|
|Number of primary turns|_N_P|-||1||See application information|
|Supply voltage1)|_U_C|V|4.5|5|5.5||
|Current consumption|_I_C|mA||19|25||
|Reference voltage (output)|_V_ref|V|2.48|2.5|2.52|Internal reference|
|Reference voltage (input)|_V_ref|V|0.5||2.65|External reference|
|Output voltage range @_I_PM|_V_out−_V_ref|V|−2||2|Over operating temperature range|
|_V_refoutput resistance|_R_ref|Ω|130|200|300|Series|
|_V_outoutput resistance|_R_out|Ω||2|5|Series|
|Allowed capacitive load|_C_L|nF|0||6||
|OCD output: On resistance|_R_on|Ω|70|95|150|Open drain, active low<br>Over operating temperature range|
|OCD output: Hold time|_t_hold|ms|0.7|1|1.4|Additional time after threshold has<br>released|
|EEPROM control|_V_out|mV|0||50|_V_outforced to GND when EEPROM<br>in an error state2)|
|Electrical offset voltage @_I_P= 0 A|_V_OE|mV|−5||5|_V_out−_V_ref@ _V_ref= 2.5 V|
|Electrical offset current<br>Referred to primary|_I_OE|A|−1.57||1.57||
|Temperature coeffcient of_V_ref|_TCV_ref|ppm/K|−170||170|−40 °C … 105 °C|
|Temperature coeffcient of_V_OE|_TCV_OE|mV/K|−0.075||0.075|−40 °C … 105 °C|
|Offset drift referred to primary<br>@_I_P= 0 A|_TCI_OE|mA/K|−23.5||23.5|−40 °C … 105 °C|
|Theoretical sensitivity|_G_th|mV/A||3.2||800 mV @_I_PN|
|Sensitivity error @_I_PN|_εG_|%|−0.5||0.5|Factory adjustment<br>(straight bus-bar)|
|Temperature coeffcient of_G_|_TCG_|ppm/K|−350||350|−40 °C … 105 °C|
|Linearity error 0 …_I_PN|_ε_L|% of_I_PN|−0.5||0.5||
|Linearity error 0 …_I_PM|_ε_L|% of_I_PM|−0.5||0.5||
|Magnetic offset current (@ 10 ×_I_PN)<br>referred to primary|_I_OM|A|−0.92||0.92|One turn|
|Reaction time @ 10 % of_I_PN|_t_ra|µs|||2.5|@ 50 A/µs|
|Response time @ 90 % of_I_PN|_t_r|µs|||3.5|@ 50 A/µs|
|Frequency bandwidth (−3 dB)|_BW_|kHz||100||Small signals|
|Output rms voltage noise (spectral<br>density)<br>(100 Hz … 100 kHz)|_e_no|µV/  Hz<br>~~√~~|||3.5||
|Output voltage noise<br>(DC … 10 kHz)<br>(DC … 100 kHz)<br>(DC … 1 MHz)|_V_no|mVpp||2.5<br>5<br>8.7|||
|Over-current detect||A|2.64× _I_PN|2.93× _I_PN|3.22× _I_PN|Peak value ±10 %|
|Accuracy @_I_PN|_X_|% of_I_PN|−1||1||
|Accuracy @_I_PN@_T_A= +105 °C|_X_|% of_I_PN|−4.55||4.55|See formula note3)|
|Accuracy @_I_PN@_T_A= +85 °C|_X_|% of_I_PN|−3.66||3.66|See formula note3)|



Notes:[1)] 3.3 V SP version available 

2) EEPROM in an error state makes the transducer behave like a reverse current saturation. Use of the OCD may help to differentiate the two cases 

> 3) Accuracy @ _X_ TA (% of _I_ PN ) = _X_ + ( 10000 _[TCG]_ × ( _T_ A _–_ 25) + 1000 _TCI_ O × E _I_ P × 100 × ( _T_ A _–_ 25)). 

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16July2015/Version 5 

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**HO 60 .. 250-P series** 

## **HO-P series, measuring range versus external reference voltage** 

**==> picture [252 x 135] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO 60-P<br>400<br>300<br>200100 UUU ccc = 5 V = 4.75 V = 4.6 V<br>0<br>-100<br>-200<br>-300<br>-400<br>0.5 1 1.5 2 2.5<br>V ref  (V)<br>I  (A) p<br>**----- End of picture text -----**<br>


**==> picture [250 x 134] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO 100-P<br>600<br>500<br>400<br>300200 UUU ccc = 5 V = 4.75 V = 4.6 V<br>100<br>0<br>-100<br>-200<br>-300<br>-400<br>-500<br>-600<br>0.5 1 1.5 2 2.5<br>V ref  (V)<br>I  (A) p<br>**----- End of picture text -----**<br>


**==> picture [511 x 135] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO 120-P HO 180-P<br>700 700<br>600 600<br>500400300200 UUU ccc = 5 V = 4.75 V = 4.6 V 500400300200 UUU ccc = 5 V = 4.75 V = 4.6 V<br>100 100<br>0 0<br>-100 -100<br>-200 -200<br>-300 -300<br>-400 -400<br>-500 -500<br>-600 -600<br>-700 -700<br>0.5 1 1.5 2 2.5 0.5 1 1.5 2 2.5<br>V ref  (V) V ref  (V)<br>I  (A) p I  (A) p<br>**----- End of picture text -----**<br>


**==> picture [252 x 134] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO 240-P<br>700600500 UUU ccc = 5 V = 4.75 V =  4.6 V<br>400<br>300<br>200<br>100<br>0<br>-100<br>-200<br>-300<br>-400<br>-500<br>-600<br>-700<br>0.5 1 1.5 2 2.5<br>V ref (V)<br>I  (A) p<br>**----- End of picture text -----**<br>


**==> picture [249 x 134] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO 250-P<br>700600 UU cc = 5 V = 4.75 V<br>500 U c = 4.6 V<br>400<br>300<br>200<br>100<br>0<br>-100<br>-200<br>-300<br>-400<br>-500<br>-600<br>-700<br>0.5 1 1.5 2 2.5<br>V ref  (V)<br>I  (A) p<br>**----- End of picture text -----**<br>


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**HO 60 .. 250-P series** 

## **Maximum continuous DC current** 

For all ranges: 

**==> picture [355 x 207] intentionally omitted <==**

**----- Start of picture text -----**<br>
300<br>250<br>HO 60-P<br>200<br>HO 100-P<br>150 HO 120-P<br>HO 180-P<br>100<br>HO 240-P<br>50 HO 250-P<br>0<br>-40 -20 0 20 40 60 80 100 120 140<br>T A (°C)<br>(A)<br>p<br>I<br>**----- End of picture text -----**<br>


Important notice:  whatever the usage and/or application, the transducer primary bar / jumper temperature shall not go above the maximum rating of 120 °C as stated in page 2 of this datasheet. 

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**HO 60 .. 250-P series** 

## **HO-P series: name and codification** 

HO family products may be ordered _**on request**_[1)] with a dedicated setting of the parameters as described below (standards products are delivered with the setting 0100 according to the table). 

## **HO-P-XXXX** 

|**_Internal_**|**_reference_**2)|**_Response time_**|**_Response time_**|**_EEPROM Control_**|**_EEPROM Control_**|**_Over_**|**_current_**|**_detection (_**×_I_PN)3)|**_detection (_**×_I_PN)3)|
|---|---|---|---|---|---|---|---|---|---|
|0|2.5 V|0|4 µs|0|YES|0|2.93|A|0.68|
|1|1.65 V|1|3.5 µs|1|NO|1|3.59|B|0.93|
|2|1.5 V|2|6 µs|||2|3.99|C|1.17|
|3|0.5 V|||||3|4.77|D|1.44|
|4|External_V_refonly|||||4|5.19|E|1.60|
|||||||5|5.76|F|1.91|
|||||||6|1.68|G|2.08|
|||||||7|2.35|H|2.31|



## Standards products are: 

- HO 60-P-0100 

- HO 100-P-0100 

- HO 120-P-0100 

- HO 180-P-0100 

- HO 240-P-0100 

- HO 250-P-0100 

Notes:[1)] For dedicated settings, minimum quantities apply, please contact your local LEM support 2) _V_ ref electrical data 

**==> picture [277 x 93] intentionally omitted <==**

**----- Start of picture text -----**<br>
V V ref (V) TCV ref (ppm/ K )<br>ref<br>parameter min typ max min max<br>0 2.48 2.5 2.52 −170 -70<br>1 1.63 1.65 1.67 −170 170<br>2 1.48 1.5 1.52 −170 170<br>3 0.49 0.5 0.51 −250 250<br>**----- End of picture text -----**<br>


> 3) OCD (× _I_ PN) correction table versus range and temperature. All other values or empty cells: no change 

**==> picture [436 x 206] intentionally omitted <==**

**----- Start of picture text -----**<br>
HO-P-010x<br>OCD  I PN (A) all temperatures<br>Parameter<br>120 180 240 250<br>A<br>B<br>C<br>D<br>E<br>6<br>F<br>G<br>H<br>7<br>0<br>1 Tolerance on OCD value<br>2 ±20 %<br>3 5.10 5.60 ±15 %<br>4 6.7  7.30 ±10 % No change<br>5 - - - Do not use<br>**----- End of picture text -----**<br>


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**HO 60 .. 250-P series** 

## **Application information** 

HOxx-P series is designed to use a bus-bar or a cable[1)] to carry the current through out the aperture with a maximum capacity of 15 × 8 mm. The 2 jumpers should be used as mechanical fixation on the PCBA and must be kept in open circuit. 

## **HO-P series: output compatibility with HAIS series** 

**==> picture [512 x 33] intentionally omitted <==**

**----- Start of picture text -----**<br>
V − V V − V<br>Reference I PN  (A) I PM  (A) I PM /  I PN @out  I PN  (Vref ) Reference I PN  (A) I PM  (A) I PM /  I PN @out  I PN  (Vref )<br>**----- End of picture text -----**<br>


|**Reference**|_I_**PN**(A)|_I_**PM**(A)|_I_**PM /**_I_**PN**|_V_out−_V_ref<br>@ _I_**PN**(V)|**Reference**|_I_**PN**(A)|_I_**PM**(A)|_I_**PM /**_I_**PN**|_V_out− _V_ref<br>@ _I_**PN**(V)|
|---|---|---|---|---|---|---|---|---|---|
|||||||||||
|HO 60-P|60|150|2.5|0.8|HAIS 50-P|50|150|3|0.625|
|HO 100-P|100|250|2.5|0.8||||||
|HO 120-P|120|300|2.5|0.8|HAIS 100-P|100|300|3|0.625|
|HO 180-P|180|450|2.5|0.8|HAIS 150-P|150|450|3|0.625|
|HO 240-P|240|600|2.5|0.8|HAIS 200-P|200|600|3|0.625|
|HO 250-P|250|625|2.5|0.8||||||



The HO-P gives the same output levels as the HAIS-P referring to the HAIS nominal currents. This allows easier replacement of HAIS by HO-P in existing applications. 

Note:[1)] The maximum magnetic offset referred to primary is inversely proportional to the number of turns, thus is divided by 2 with 2 turns. 

## **Definition of typical, minimum and maximum values** 

Minimum and maximum values for specified limiting and safety conditions have to be understood as such as well as values shown in “typical” graphs. 

On the other hand, measured values are part of a statistical distribution that can be specified by an interval with upper and lower limits and a probability for measured values to lie within this interval. 

Unless otherwise stated (e.g. “100 % tested”), the LEM definition for such intervals designated with “min” and “max” is that the probability for values of samples to lie in this interval is 99.73 %. 

For a normal (Gaussian) distribution, this corresponds to an interval between −3 sigma and +3 sigma. If “typical” values are not obviously mean or average values, those values are defined to delimit intervals with a probability of 68.27 %, corresponding to an interval between −sigma and +sigma for a normal distribution. 

Typical, maximal and minimal values are determined during the initial characterization of the product. 

## **Remark** 

Installation of the transducer must be done unless otherwise specified on the datasheet, according to LEM Transducer Generic Mounting Rules. Please refer to LEM document N°ANE120504 available on our Web site: **Products/Product Documentation** 

## **Safety** 

This transducer must be used in limited-energy secondary circuits according to IEC 61010-1. 

This transducer must be used in electric/electronic equipment with respect to applicable standards and safety requirements in accordance with the manufacturer’s operating instructions. 

## Caution, risk of electrical shock. 

When operating the transducer, certain parts of the module can carry hazardous voltage (e.g. primary bus bar, power supply). Ignoring this warning can lead to injury and/or cause serious damage. 

This transducer is a build-in device, whose conducting parts must be inaccessible after installation. A protective housing or additional shield could be used. 

Main supply must be able to be disconnected. 

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**HO 60 .. 250-P series** 

## **PCB Footprint in mm.** 

**==> picture [256 x 253] intentionally omitted <==**

## **Assembly on PCB** 

- ●Recommended PCB hole diameter 

   - 2.15 mm for primary pin 

   - 0.9 mm for secondary pin 

- ●Maximum PCB thickness 

- ●Wave soldering profile No clean process only 

- 2.4 mm maximum 260 °C, 10 s 

## **Insulation distance (nominal values):** 

|**ation distance (nominal values):**||||
|---|---|---|---|
||_d_Cp||_d_CI|
|On PCB: A - B|18.85 mm||-|
|Betweenjumper and secondary pin|21.1 mm||20.9 mm|
|Betweenprimarybusbar and secondary pin|14.6 mm||-|
|Betweenprimarybusbar andjumper|-||8 mm|
|Betweenprimarybusbar and core|-||11.34 mm|
|Between core and secondaryterminal|-||1.18 mm|
|||||



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**HO 60 .. 250-P series** 

**Dimensions HO-P series** (mm, general linear tolerance ±0.3 mm) 

**==> picture [513 x 520] intentionally omitted <==**

**----- Start of picture text -----**<br>
Connection<br>V<br>ref<br>I V<br>p out<br>U<br>c<br>**----- End of picture text -----**<br>


## **Remark:** 

- _V_ OUT is positive with respect to _V_ ref when positive _I_ P flows in direction of the arrow shown on the drawing 

   - above. 

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