Temperature measurement is a key issue in the LHC, as it will be used to regulate the cooling of the superconducting magnets. The compromise between available cooling power and the coil superconducting characteristics leads to a restricted temperature control band, around 1.9 K. An absolute accuracy DeltaT < 10 mK below 2.2 K, and DeltaT < 5 K above 25 K, is necessary. For resistive thermometers covering the full temperature range, and having a negative dR/dT sensitivity, this is typically equivalent to a relative accuracy DeltaR/R of 3 10**-3 over 3 resistance decades. Also, to limit the thermometer's self-heating, the sensing current must be limited to few muA. Furthermore, the radiation levels next to the accelerator are expected to degrade significantly the performance of conventional analogue electronics. As these stringent requirements are not met by commercial conditioners, three different architectures have been developed at CERN. The first compresses the input dynamic range using a logarithmic transfer function; the second partitions the input range into three linear regions; the third converts resistance linearly into the frequency of a square wave. They fulfil the above specifications and provide industrial robustness in terms of thermal drift, galvanic protection, and compact packaging, while optimising cost-to-performance ratio. This paper describes the principles of their design, compares their characteristics and shows results of field tests. Future developmens include ASIC versions, Fieldbus interfacing, and radiation tolerant re-design

Casas-Cubillos, J

Gomes, P

Henrichsen, K N

Jordung, U

Rodríguez-Ruiz, M A

CERN Document Server

EUROPEAN ORGANIZATION FOR NUCLEAR RESEARCHEuropean Laboratory for Particle PhysicsSIGNAL CONDITIONING FOR CRYOGENIC THERMOMETRY IN THE LHCJ. Casas, P. Gomes, K.N. Henrichsen, U. Jordung and M.A. Rodriguez RuizTemperature measurement is a key issue in the Large Hadron Collider (LHC), as it will be used to regulate thecooling of the superconducting magnets. The compromise between available cooling power and the coilsuperconducting characteristics leads to a restricted temperature control band, around 1.9 K. An absolute accuracy of10 mK below 2.2 K, and 5 K above 25 K, is necessary. For resistive thermometers covering the full temperaturerange, and having a negative dR/dT sensitivity, this is typically equivalent to a relative accuracy DR/R of 3 10-3 over3 resistance decades. Also, to limit the thermometer's self-heating, the sensing current must be limited to few mA.Furthermore, the radiation levels next to the accelerator are expected to significantly degrade the performance ofconventional analog electronics.As these stringent requirements are not met by commercial conditioners, three different architectures have beendeveloped at CERN. The first compresses the input dynamic range using a logarithmic transfer function; the secondpartitions the input range into three linear regions; the third converts resistance linearly into the frequency of a squarewave. They fulfill the above specifications and provide industrial robustness in terms of thermal drift, galvanicprotection, and compact packaging, while optimizing cost-to-performance ratio. This paper describes the principlesof their design, compares their characteristics and shows results of field tests. Future developments includeApplication Specific Integrated Circuit versions, Fieldbus interfacing, and radiation tolerant re-design.LHC DivisionPresented at the 1999 Cryogenic Engineering and International Cryogenic Materials Conference(CEC-ICMC'99), 12-16 July 1999, Montreal, CanadaGeneva, Large Hadron Collider ProjectAdministrative SecretariatLHC DivisionCERNCH - 1211 Geneva 23SwitzerlandLHC Project Report 333Abstract1 December 19991SIGNAL CONDITIONING FORCRYOGENIC THERMOMETRY IN THE LHCJ. Casas, P. Gomes, K.N. Henrichsen, U. Jordung, M.A. Rodriguez RuizCERN, European Organization for Nuclear Research1211 Geneva 23, SwitzerlandABSTRACTTemperature measurement is a key issue in the Large Hadron Collider (LHC), as itwill be used to regulate the cooling of the superconducting magnets. The compromisebetween available cooling power and the coil superconducting characteristics leads to arestricted temperature control band, around 1.9 K. An absolute accuracy of 10 mK below2.2 K, and 5 K above 25 K, is necessary. For resistive thermometers covering the fulltemperature range, and having a negative dR/dT sensitivity, this is typically equivalent to arelative accuracy ’R/R of 3 10-3 over 3 resistance decades. Also, to limit the thermometer’sself-heating, the sensing current must be limited to few PA. Furthermore, the radiationlevels next to the accelerator are expected to significantly degrade the performance ofconventional analog electronics.As these stringent requirements are not met by commercial conditioners, threedifferent architectures have been developed at CERN. The first compresses the inputdynamic range using a logarithmic transfer function; the second partitions the input rangeinto three linear regions; the third converts resistance linearly into the frequency of a squarewave. They fulfill the above specifications and provide industrial robustness in terms ofthermal drift, galvanic protection, and compact packaging, while optimizing cost-to-performance ratio. This paper describes the principles of their design, compares theircharacteristics and shows results of field tests. Future developments include ApplicationSpecific Integrated Circuit versions, Fieldbus interfacing, and radiation tolerant re-design.INTRODUCTIONThe various components of the LHC cryogenic system work at temperatures fromambient down to 1.6 K. Depending on the actual temperature value, different accuracies arerequired on its measurement. Between 300 K and 25 K, an uncertainty of 5 K can betolerated to monitor the warmer components and the general cool-down. However, at thenominal operation of superconducting magnets (below 2.2 K) only 10 mK inaccuracy isallowed, to give enough room for the regulation band of the cryogenic controller, whileavoiding magnet quench and minimizing the cooling effort of the cryogenic system.Table 1 shows the allowed uncertainty on temperature measurement on the LHCmachine, for the different temperature ranges. The accuracy budget is to be evenly sharedbetween the sensor and the signal conditioning (Figure 1). The aimed resolution has to beten times better than the overall accuracy (dT < 1mK, below 2.2 K).2SensorsCryogenic temperature sensors currently used at CERN can be classified according tofour main attributes, as shown in Table 2. CERNOX™ (CX), TVO® and RhFe cover the fulltemperature range with a single sensor. AllenBradley® (AB) and Pt100 can be combined tocover respectively low and high temperature scales, or used alone in applications notrequiring full range measurements.In terms of resistive values, CX’s span is the largest among all sensors (3 decades),requiring wide dynamic range signal conditioning. Also covering the whole temperaturerange, RhFe spans over only 2 decades of  resistance, with the advantage of less demandingdynamic range, but with the consequence of limited sensitivity.Sensors with negative dR/dT (Figure 2), like CX, TVO® and AB, show high resistanceand high sensitivity (dR/R  /  dT/T) (Figure 3) at low temperatures, where measurementaccuracy has to be at its best. This semiconductor behavior relaxes the constraints onconditioner accuracy for low temperature measurement. On the other hand, at lowtemperature metallic sensors like RhFe exhibit a sensitivity one order of magnitude worse,demanding much more accurate signal conditioning.Signal conditioningThe basic principle used to read resistive sensors consists in sending a known sensingcurrent, over a pair of wires, and reading the voltage developed at the resistor leads, viaanother pair of wires. After amplification and correction, the read signal can be sent to theprocess controller under different formats, either analog or digital. 1 10 1001 00010 0001 10 100 1000T [K]T [mK]Figure 1. Required conditioning temperature accuracyTable 1. Required overall T accuracy and resolutionT span [K] accuracy [mK] resolution [mK]   1.6 l    2.2 10 1   2.2 l    4.0 20 2   4.0 l    6.0 30 3   6.0 l   25 1 000 100 25    l 300 5 000 500 1 10 1001 00010 000100 000 1  10  100 1 000T [K]R []CERNOXTVORhFeABPt100Figure 2. Typical thermometers transfer function R(T) 0.1 1. 10. 1  10  100 1 000T [K]| (dR/R) / (dT/T) | CERNOXTVORhFeABPt100Figure 3. Dimensionless sensititvity vs temperatureTable 2. Typical characteristics of cryogenic temperature sensors currently used at CERNT span [K] R span [:] dR/dT [:/K] (dR/R) / (dT/T)CX 1.6 l 300 30 000 l   30 -40 000    l - 0.1  -2.7 l - 1.0TVO® 1.6 l 300   9 000 l 900   -7 000    l - 0.7  -1.3 l - 0.2RhFe 1.6 l 300          6 l 110         +0.7 l +0.4 +0.2 l +1.0AB 1.6 l 100 10 000 l 100 -12 000    l - 0.3  -3.0 l - 0.2Pt100  73 l 300        18 l 110         +0.4 l +0.4 +2.0 l +1.03For each type of thermometer, the signal conditioning accuracy and resolutionrequirements are summarized in Table 3 and plotted in Figure 4 and Figure 5. The RhFesensor imposes quite severe constraints on the conditioning electronics, with’R/R < 0.5 10-3 for R < 8.5:, thus requiring techniques beyond the scope of theconditioners described in this paper.A conditioner satisfying ’R/R < 3 10-3 for R > 500: and ’R/R < 6 10-3 for R < 500:is adequate for CX, AB and Pt100 thermometers. A TVO® sensor would impose a three timesbetter accuracy on the resistance measurement.As the sensor’s resistance will be calculated linearly from the read voltage (Eq. 1), therelative accuracy is the addition of the voltage and the sensing current uncertainties.Rsensor = Uread / Isense 'R/R = 'U/U + 'I/I (1)The read signal has to be digitized in order to be usable by computerized control ordiagnostics. Industrial control equipment typically employs 12-bit Analog to DigitalConverters (ADC) and the targeted temperature accuracy cannot be satisfied unless sometype of signal compression is implemented. This paper presents two compressionarchitectures that are mixed logarithmic+linear (LOG+LIN) and linear piecewise (LIN pw).The resistance measurement accuracy must be split between the accuracy of the analogcircuitry and that of the ADC, which can be expressed in terms of the ADC LeastSignificant Bit (LSB). Figure 6 and Figure 7 show respectively the accuracy and resolutionimposed by the resistance measurement, and also the accuracy and resolution attained bythe combination of different compression algorithms and a minimum size ADC.Table 3. Conditioner’s accuracy and resolution required by each type of sensor, below and above T = 6 KT < 6 K T > 6 Ksensor R span [:] 'R/R [10-3] dR [m:] R span  [:] 'R/R [10-3] dR [m:]CX 1 500 l 30 000 3.3 900   30    l 1 500 8.9   60TVO® 2 600 l   9 000 1.3 700 900    l 2 600 1.8 300RhFe        6 l          8.5 0.5        0.6     8.5 l    110 6.0   15AB    500 l 10 000 3.1 300 100    l    500 5.8 100Pt100   18    l    110 9.8 200 0.01 0.1 1. 10. 100.  10   100  1 000  10 000  100 000R [:]R/R [e-3]CERNOXTVORhFeABPt100requirementFigure 4. Required accuracy 0.001  0.01  0.1  1.  10.  100.  10  100 1 000 10 000 100 000R [:]dR []CERNOXTVORhFeABPt100requiredFigure 5. Required resolutionLSB/R (R) 0.01 0.1 1. 10. 100.  10   100  1 000  10 000  100 000R [:]R/R [e-3]required18b LIN 12b LOG13b LOG+LIN13b LIN pwFigure 6. Required ADC accuracyLSB (R) 0.001  0.01  0.1  1.  10.  100.  10  100 1 000 10 000 100 000R [:]dR []required19b LIN 14b LOG15b LOG+LIN15b LIN pwFigure 7. Required ADC resolution4 Table 4 summarizes these requirements. Due to its lower sensitivity, the TVO®typically needs 1 more bit than other sensors. For all sensors, the resolution normallyrequires 2 more bits than the accuracy.It is clear that a 12-bit resolution ADC is not sufficiently accurate (above 4.5 K) for allthe mentioned conditioning architectures. We are thus considering the use of larger ADC,with a suitable network interface.LOGARITHMIC CONDITIONERThe first conditioner (Figure 8) incorporates a logarithmic compression of the inputdynamic range. A DC sensing current of 10 PA develops a voltage (0.2 mV l 200 mV)across the thermometer, which is raised by an instrumentation amplifier. The offset andgain, before and after the logarithmic amplifier, have to be manually adjusted. Powersupply, input and output are galvanically isolated to 750 V.The overall performance against ambient temperature variation is limited by theLogarithmic IC. This explains the improvement in temperature drift at higher resistances,for LOG+LIN in comparison with LOG (Figure 9 and Figure 10). The relationship betweeninput and output is given by the following equations for LOG and LOG+LIN respectively:Iloop = 4 + 16/3  Log10 (R/20) [mA] (2)Iloop = 4 +   8/3  Log10 (R/20) + 8/(20k-20)   (R-20) [mA] (3)The rejection of power supply drift is good for R > 500 : (|’R/R  /’V| < 0.7 10-3 /V,Figure 11), but quite poor for small R.Several tens of these conditioners have been installed in cryogenic experiments atCERN, yielding good results (Figure 12), provided the ambient temperature does notchange more than a few degrees.Table 4. ADC accuracy and resolution required for each type of conditioner transfer functionfor CX, AB, Pt100 and TVO® for CX, AB, and Pt100 onlyconditioner accuracy   [bit] resolution [bit] accuracy   [bit] resolution [bit]LIN 18 19 18 19LOG 13 15 12 14LOG+LIN 14 16 13 15LIN pw 14 16 13 15Figure 8. Logarithmic conditioner block diagramTamb drift, referred to 28C (LOG)-50-2502550 10  100 1 000 10 000 100 000R[:]R/R [e-3]T =   8CT = 18CT = 28CT = 38CT = 48CT = 58CFigure 9. Thermal drift (LOG function alone)Tamb drift, referred to 23C (LOG+LIN)-50-2502550 10  100 1 000 10 000 100 000R [:]R/R [e-3]T   3CT 13CT 23CT 34CT 45CT 54CFigure 10. Thermal drift (combined LOG+LIN)5LINEAR MULTI-RANGE CONDITIONERIn order to reduce the ADC size, a linear multi-range conditioner has been developed.The input span is partitioned into three regions (Table 5), one decade wide each, with thegain proportional to the sensing current. The thermal drift due to the logarithmic IC is thusavoided, at the expense of more complex circuitry for controlling the gain (Figure 13).Furthermore, the sensing current can be lower for high R values (low T), reducing theself-heating of the sensor, and higher for small R values, increasing the voltage developedat the sensor and its signal to noise ratio. The thermocouple voltages are cancelled by theuse of a bipolar sensing current, oscillating at 4 Hz.The sensing current creates a voltage (r3.5 mV l r40 mV) across the thermometer,which is increased, by an instrumentation amplifier, (to r0.875 V l r10 V), and thenrectified and smoothed. When this voltage raises above 10 V, the gain controller selects asensing current 10 times lower, leading to the same reduction in voltage. If the voltagedrops below 0.875 V, a 10 times higher current is selected. The gap between 0.875 V and1 V corresponds to a hysteresis in the transfer function (Figure 14), that prevents oscillationbetween consecutive ranges when close to the switching point.The selected range is indicated by two bit or a three level analog signal. Manualadjustments are necessary to correct general gain and offset and differential offset of therectifier. Power supply, input and output are galvanically isolated to 750 V.Vcc drift, referred to 24V (LOG+LIN)-50-2502550 10  100 1 000 10 000 100 000R [:]R/R [e-3]Vcc = 22VVcc = 24VVcc = 26VFigure 11. Power supply driftaccuracy 0.01 0.1 1. 10. 100.1 000.10 000.1 10 100 1000T [K]DT [mK]requiredTT1TT2TT2TT4TT5TT6TT7TT8TT9TT10Figure 12. Field measurementsFigure 13. Linear multi-range conditioner block diagramhysteresis (at Vout)0110 10  100 1 000 10 000 100 000R [:]U [ V]Figure 14. Hysteresis in the transfer functionTable 5. Sensing current and conditioner transferfunction, for each input rangeR span [:] Isense [PA] Iloop [mA]     35 l      400 100 4 + 16  R /      400   350 l   4 000   10 4 + 16  R /   4 0003 500 l 40 000     1 4 + 16  R / 40 0006The sensitivity to thermal drift (|’R/R  /’Tamb| < 0.11 10-3 /qC, Figure 15) is very lowcompared to LOG conditioner. The thermal performance is further improved (Figure 16) atthe voltage output, without galvanic isolation.The insensitivity to power supply drift is good for the whole input span, both at thecurrent output (|’R/R  /’V| < 1.0 10-3 /V, Figure 17) and the voltage output(|’R/R  /’V| < 0.4 10-3 /V, Figure 18).Figure 19 shows the excellent reproducibility of the conditioners’ characteristicsbetween three samples.Several tens of these conditioners have been installed in cryogenic experiments atCERN, behaving in accordance with the requirements (Figure 20).Tamb drift, referred to 25C (at Iout)-2-1012 10  100 1 000 10 000 100 000R [:]R/R [ e-3]T =   0CT = 10CT = 25CT = 40CT = 50CFigure 15. Thermal drift at the current outputTamb drift, referred to 25C (at Vout)-2-1012 10  100 1 000 10 000 100 000R [:]R/R [e-3]T =   0CT = 10CT = 25CT = 40CT = 50CFigure 16. Thermal drift at the voltage outputVcc drift, referred to 24V (at Iout)-2-1012 10  100 1 000 10 000 100 000R [:]R/R [e-3]Vcc = 25VVcc = 24VVcc = 23VFigure 17. Power supply drift at current outputVcc drift, referred to 24V (at Vout)-2-1012 10  100 1 000 10 000 100 000R [:]R/R [e-3]Vcc = 25VVcc = 24VVcc = 23VFigure 18. Power supply drift at voltage outputexchangeability (at Vout)-2-101210 100 1000 10000 100000R [:]R/R [e-3]SN 1SN 1SN 3Figure 19. Exchangeabilityaccuracy (at Vout) 0.1 1. 10. 100.1 000.10 000. 1  10  100 1 000T [K]T [mK]requiredTT1TT2TT3TT4TT5TT6TT7TT8TT9Figure 20. Field measurements7T2F CONDITIONERThis conditioner converts the voltage across the sensor resistance linearly into afrequency (Figure 21). The requirements on accuracy and resolution are no longer put onvoltage amplitude measurement but rather on frequency measurement. The outputfrequency spans over three decades of dynamic range, like the measured resistance. Thelogarithmic compression nuisances or the complexity of a multi-range controller are tradedby a simpler concept.The sensing current follows a ramp of fixed slope (r10 PA/s). Once reached the upper(10 mV) or lower (-10 mV) threshold referred to the input, the ramp sign is inverted. Thisfixed voltage amplitude restricts the thermometer self-heating to a relatively low value.Despite the fact that the working frequencies are below 50 Hz, the current control loopeasily picks-up the mains noise. This effect is tackled by the use of a 50 Hz notch filter. Inorder to avoid spurious trigger of the flip-flop, a glitch detector is implemented, whichintroduces an extra delay on the oscillation period (Eq. 4).f = 1 / (10-3 +103/R) [Hz] (4)Manual adjustments are necessary for notch filter width and center frequency, for theglitch filter delay and for the current slope.Figure 22 shows the deviation (|’R/R| < 2 10-3) between two conditioners, using thesame transfer function. The accuracy obtained in field measurements (Figure 23) is wellwithin the requirements. Further tests are under way to investigate temperature and powersupply drifts.Figure 21. T2F conditioner block diagramexchangeability-2-1012 10  100 1 000 10 000 100 000R [:]R/R [e-3]SN 1Figure 22. Exchangeability relative to SN2accuracy 0.1 1. 10. 100. 1  10  100 1 000T [K]R/R [e-3]required1.80 K1.82 K3.1   K102  KFigure 23. Field measurements8CONCLUSIONSThe cryogenic thermometer signal conditioners presented in this paper are used in avariety of applications. When fast response is required the LOG or LOG+LIN conditionercan be used. For higher accuracy at low temperature it would be necessary to reduce thesensing current. However, in this case the thermal drift of the input amplifier will be thedominant source of error for low values of the thermometric resistance.The LINpw and T2F conditioners satisfy the LHC accuracy requirements. Howevertheir installation inside the LHC tunnel impose their redesign by using radiation tolerantintegrated components, both passive and active. This problem is being solved byperforming irradiation tests on commercial devices, and by porting the conditioners’ designinto a radiation hardened Application Specific Integrated Circuit (ASIC).Once the design of a suitable signal conditioner for thermometers has been finalized, itwill be necessary to adapt its characteristics in order to being able to use it as front end ofother instruments like pressure sensors, liquid helium level gauges, etc.The cryogenic control system requires temperature measurements distributed aroundthe 27 km circumference LHC machine. The data exchange can be done with either point-to-point analog signal transmission or by using an industrial field network. Analogtransmission implies a large investment in cabling and installation. In order to reduce thiscost we are also investigating the performance of network components and ADCs, tointegrate them together with the signal conditioners.

Signal Conditioning for Cryogenic Thermometry in the LHC

Abstract

Similar works

Full text

Available Versions

CERN Document Server