Effect of Temperature Variation on Modal Frequency of Reinforced Concrete Slab and Beam in Cold Regions

Changes of modal frequencies induced by temperature variation can be more obvious than those caused by structural damage, which will lead to the false damage identification results. Therefore, quantifying the temperature effect on modal frequencies is a critical step to eliminate its interference in damage detection. Due to the nonuniform and time-dependent characteristics of temperature distribution, it is insufficient to obtain the reliable relationships between temperatures and modal frequencies using temperatures in air or at surface. In this paper, correlations between measured temperatures (air temperature, surface temperature, mean temperature, etc.) and modal frequencies for the slab and beam are comparatively analyzed. And the quantitative models are constructed considering nonuniform temperature distribution. Firstly, the reinforced concrete slab and beam were constructed and placed outside the laboratory to be monitored. Secondly, the correlation coefficients between modal frequencies and three kinds of temperatures are calculated, respectively. Thirdly, simple linear regression models between mean temperature and modal frequencies are established for the slab and beam. Finally, five temperature variables are selected to construct the multiple linear regression models. Prediction results reveal that the proposed multiple linear regression models possess favorable accuracy to quantify the temperature effect on modal frequencies considering nonuniform temperature distribution.


Introduction
In order to guarantee the safety operation of structures, structural health monitoring (SHM) systems have been widely implemented on the existing and newly built bridges in the past few decades [1][2][3].Vibration-based Damage Identification (VBDI), as one of extremely important parts of SHM system, has been developed to monitor bridge performance and identify structural damage [4][5][6].However, a practical difficulty exists because modal parameters vary with the changing environmental conditions.In order to avoid the false damage identification results, the changes of modal parameters caused by environmental variation must be understood, quantified, and discriminated from those caused by structural damage [7][8][9][10].
Numerous investigations have indicated that temperature is the most important environmental factor affecting structural vibration properties [11,12].And its effect can be more significant than that caused by structural damage [13].
Corresponding researches have also demonstrated that mode shapes are not sensitive to temperature variation, and the change of modal damping may be masked by measurement noise [14][15][16].Therefore, the temperature effect on modal frequencies has attracted much more attention.Researchers from Los Alamos National Laboratory monitored the Alamosa Canyon Bridge in New Mexico during 24 hours.They found that the first three modal frequencies varied about 4.7%, 6.6%, and 5.0%, when the temperature of bridge deck changed by about 22 ∘ C [17,18].It was more significant than the changes of modal frequencies caused by artificial cut in I-40 Bridge [19].Peeters and De Roeck [20] reported that the first four modal frequencies of Z24 Bridge in Switzerland varied by 14%-18% during monitoring period of 10 months.There was a bilinear relationship between measured frequencies and temperatures above and below 0 ∘ C because of the asphalt layer freezing at cold temperature.Later progressive damage tests indicated that modal frequencies decreased by less than 10% till final destructive damage [21].

Shock and Vibration
As indicated by these researches, structural damage cannot be accurately identified if temperature effect is not quantified and eliminated.
During the past 20 years, considerable efforts have been devoted to investigating temperature effect on modal frequencies of RC bridges.Askegaard and Mossing [22] continuously monitored a three-span RC bridge for three years, and seasonal change of modal frequencies reached 10%.Desjardins et al. [23] studied the modal frequencies and average girder temperature of Confederation Bridge during monitoring period of 6 months.The variation of temperature from −20 ∘ C to 25 ∘ C led to the reduction in modal frequencies by 4%.Liu and DeWolf [24] found that the modal frequencies changed about 6% during one full year.And a linear regression analysis demonstrated that the modal frequencies were decreased by 0.8%, 0.7%, and 0.3% as temperature increases by one degree Celsius.Mosavi et al. [25] monitored the vibration responses and temperature of a two-span steelconcrete composite bridge during 24 h period.Frequencies in all modes changed 1-2% from night to noon and did not change significantly from night to morning.In summary, it has been widely observed that temperature significantly affects the modal frequencies of RC bridges with a negative correlation [26,27].
Some researchers have been investigating the correlation and evaluating the degree of temperature influence on modal frequencies based on field test data [28].However, vibration test in practical engineering is easily affected by external factors (service load, wind, temperature, boundary condition, damage, measurement noise, etc.) [29].It is difficult to separate the effect of temperature on modal frequencies from others, which results in the unconvinced correlations between measured modal frequencies and temperature.Therefore, the controlled laboratory experiments are necessary and imperative to provide accurate and reliable results regarding the temperature effect on modal frequencies.Xia et al. [15] conducted an experiment on a two-span continuous concrete slab out of laboratory for nearly two years.It was found that the negative correlation between modal frequencies and air temperature could be observed for the first four modes.Comparative study with cantilever beams made of steel and aluminum indicated that the modal frequencies variations of RC slab were much larger than those of metallic beams [13].For these laboratory experiments and field testes, air temperature and surface temperature are measured to discover the correlations with modal frequencies.However, the temperature distribution in RC bridge is nonuniform and time-dependent.The relationships between modal frequencies and temperature at surface (or in air) are incomplete and unreliable.
Considering that the relationships between modal frequencies and temperature cannot be sufficiently captured using air temperature or surface temperature, Xia et al. [30] investigated the variation of modal frequencies versus nonuniform temperature distribution for a RC slab.It was clearly shown that modal frequencies decreased with the increasing of temperature.In addition, a better linear correlation between modal frequencies and structural temperatures was observed than air temperature and surface temperature.However, the tests are only carried out from 8:00 am to 10:00 pm on 11 February 2009.During test period, air temperatures only fluctuated from 17 ∘ C to 27 ∘ C. It is insufficient to investigate the correlation and quantify temperature influence on modal frequencies, especially in cold regions.Moreover, temperature along width direction is assumed to be uniformly distributed, and nonuniform temperature distribution is only considered along vertical direction in Xia et al. 's research.In practice, the temperature distribution of an entire bridge is generally nonuniform throughout the cross section.Therefore, studying the correlation and quantifying temperature effect using nonuniform temperature distributions along both width and height directions are necessary for engineering application of damage identification methods.
This paper aims to investigate the correlations between modal frequencies and temperatures for RC slab and beam in cold regions and quantify the temperature effect.The RC slab and beam were constructed and placed outside the laboratory to periodically measure the modal frequencies and temperatures (air temperature, surface temperature, mean temperature, etc.).Correlations between modal frequencies and three kinds of temperatures are contrastively analyzed.In addition, simple linear regression models (SLRM) between modal frequencies and mean temperature are established.And the temperature effect on modal frequencies is evaluated based on thermal mechanics theory and thermal properties of concrete.In order to improve the accuracy of quantification, multiple linear regression models (MLRM) are developed to formulate the relationship between modal frequencies and nonuniform temperature distribution.A better prediction performance indicates that MLRM can be used to accurately quantify temperature effect on modal frequencies for structural health monitoring and damage identification.

Description of Experiment
2.1.RC Slab and Beam.The RC slab and beam constructed for monitoring temperatures and modal frequencies are shown in Figure 1.The slab is 600 mm wide and 150 mm high, and beam is 300 mm wide and 400 mm high.The lengths of them are both 4000 mm, and calculated span lengths are 3700 mm.RC slab and beam are simply supported on concrete piers by plate rubber supports.A 150 mm overhang is present at each end of the slab and beam.In order to avoid the localized damage at support positions, the metal plates with 5 mm thickness are embedded into slab and beam over supports.In addition, the concrete blocks with the length of 400 mm and the same cross section dimensions as the RC slab and beam are constructed and placed on the side of slab and beam.They are used to measure the mass variations, which can reflect the effect of air humidity on the mass of RC slab and beam.The RC slab, beam, and corresponding concrete blocks were produced on 8 June 2015.Design strength of concrete is 40 MPa, and the mixture proportions are listed in Table 1.Common Portland cement of grade 42.5 (normal type) containing 20% active admixture is used as cementitious material.Natural river sand (medium sand) with fineness modulus 2.7 is adopted as fine aggregate.And crushed gravels with a nominal maximum size of 31.5 mm are used as  operating temperature ranging from 0 to 50 ∘ C, it is installed in laboratory to ensure the accuracy of measurement.Type T thermocouples are connected to TP700 data recorder using shielded thermocouple compensation lead.Connection between two compensation leads is achieved by malefemale plugs, and the metal wire is covered with heat-shrink tubing [32].Thermocouple compensation lead is connected into the laboratory using a sealed PVC conduit.
In order to monitor the temperatures in prefabricated RC slab and beam, type T thermocouples are embedded in cross sections at mid-spans of the slab and beam.There are two reasons accounting for the layout of type T thermocouples.Firstly, thermal transmission mainly occurs along width and height directions with respect to the length because the size of length is significantly larger than width and height.Secondly, the slab and beam receive the uniform sunlight along the length direction as they are set along East-West directions.Therefore, the temperature along length direction is assumed to be uniformly distributed, and the measurements of temperatures in the cross sections of slab and beam are the main concerns.Specific layouts of thermocouples in cross sections at mid-spans of the slab and beam are shown in Figure 2. "SH" represents thermocouples along height direction in slab, while "SW" represents the thermocouples along width direction.Similarly, "BH" and "BW" represent the thermocouples along height and width directions in beam, respectively.In order to fix the thermocouples in accurate position, preformed concrete strips containing type T thermocouples are located at predetermined position before pouring concrete, as illustrated in Figure 3.In addition, the TP-2307 sensor is fixed on the undersurface of the slab using adhesive mounting squares and zip ties to monitor the air temperature and humidity.
DH131E accelerometers manufactured by Donghua Testing Technology Corporation in China are selected as the vibration sensors.The accelerometer features a sensitivity of 1 mV/g, a frequency range of 1-8000 Hz, small size ( 10 × 16 mm), and light weight (5.5 g).The operating temperature ranging from −40 to 80 ∘ C makes it ideal for outdoor application.The magnetic bases are fixed on the upper surface of slab and beam using metal/concrete epoxy, and accelerometers are mounted on the magnetic bases.A DH5922 type dynamic signal measurement and analysis system is used to measure and analyze acceleration response.It includes sixteen 24-bit Integrated Electronics Piezoelectric (IEPE) input channels and supports sampling rates of up to 51.2 kHz.Antialiasing filters and timebase export for tight synchronization between  Two DH131E accelerometers are installed at mid-span and at 3/10 of the span length from one end to monitor vertical vibration.The slab and beam are excited using a rubber hammer at 7/10 of span length along vertical direction.The first four vertical mode shapes calculated by numerical model are illustrated in Figure 4, and corresponding layouts of accelerometers and excitation point are also demonstrated.It is assumed that there are no motions at the supports.As can be seen from Figure 4, the locations of 1 # accelerometer and excitation point avoid the nodes of mode shapes. 2 # accelerometer is used to identify the modal frequencies of modes 1 and 3, and 1 # accelerometer is used to identify the first four modal frequencies.Although node 7 is not the optimal choice of excitation location for the first four vertical modes, it is successful in exciting and identifying the first seven modal frequencies, which is helpful for future investigation.

Test Procedures.
The tests are carried out from 20 September 2015, and the slab and beam are exposed to external environment from then.Modal testing is performed to measure the vibration responses of the slab and beam at twohour intervals from 8:00 am to 10:00 pm in every day of monitoring.At the same time, temperatures and air humidity are recorded by TP700 data recorder at a rate of one sample per minute.No measurements are taken from 10:00 pm to 8:00 am in the next day because the sunlight disappears and air temperature slightly changes during this period.The modal frequencies insignificantly change, and there is no obvious difference between the measurement results at 10:00 pm and those measured during the period from 10:00 pm to 8:00 am.Mosavi et al. [25] also found that the first five modal frequencies did not have a noticeable change between night and morning measurements, while an almost 2% change in modal frequencies can be observed in all modes for the noon measurement.In addition, the monitoring was discontinuously performed for the RC slab and beam due to the restrictions of measurement equipment.Therefore, the measurements from 10:00 pm to 8:00 am are not taken in this investigation.
As for the modal testing, DH5922 system samples a 16second data from the four acceleration channels at a 5120 Hz sampling rate.Data processing is performed by DHDAS-2013 software platform, which is an important part of DH5922 system.Firstly, the recorded sample data is bandpass-filtered between 10 and 1000 Hz using a finite impulse response filter.Secondly, the Hamming window with 50% overlap is used to intercept acceleration signal.The number of spectrum lines is set as 6400, and the obtained frequency resolution is 0.156 Hz.Finally, modal frequencies are calculated and extracted by frequency spectrum analysis using fast Fourier transform (FFT).For example, two samples of data collected from accelerometers installed on the slab on 13 October 2015 at 8:00 am are shown in Figure 5.Both the time history of acceleration signal and corresponding amplitude spectrum are illustrated.

Analysis of Test Results
Due to the restrictions of measurement equipment, RC slab and beam are discontinuously monitored.Measurements are completed for each of 112 samples from fourteen days during the period beginning on 20 September 2015 and ending on 9 December 2015.A total of 112 samples are sorted in measurement time order.The samples measured on 1 November 2015 are chosen as testing samples to verify the prediction performances of quantitative models, and other 104 samples are used to analyze the correlation and construct the quantitative models.temperature at the center of cross section is measured by thermocouple BH4.Similar to the beam, thermocouples (SH1, SH7, SW1, SW17, and SH4) are used to measure the temperatures at the corresponding positions of slab.It is obvious to observe that thermocouples at SW1 and BW1 on the south side of slab and beam receive direct sunlight, and their temperatures are higher than others.The significant differences of temperatures at the same time demonstrate the nonuniform temperature distributions in the slab and beam.
In order to specifically exhibit the nonuniform temperature distributions in slab and beam, temperatures measured on 16 October 2015 at 2:00 pm are shown in Figure 7.It can be found that the temperature distributions are nonuniform not only along height direction but also along width direction in cross section at mid-span.Compared with slab, nonuniform temperature distributions in beam are more obvious.This can be accounted for by the fact that the sizes of height and width of beam are much closer and thermal transmissions occur at two dimensions with similar levels.

Variation of Modal
Frequency.The identified first four modal frequencies and corresponding air temperatures are shown in Figures 8 and 9. Modal frequencies change significantly with the variation of temperatures.And the higher values of modal frequencies generally occur at the lower temperatures.It is indicated that the modal frequencies increase with temperature decreasing.Clear correlations between modal frequencies and air temperatures can be observed.
Statistics of the identified modal frequencies during monitoring period are summarized in Table 2. Variation range of modal frequency is the difference between maximum and minimum values of identified modal frequencies for a  specific mode.Mean value of modal frequency is calculated by averaging the identified modal frequencies for a specific mode.The relative variation is defined as [33] where  max ,  min , and  are the maximum, minimum, and mean values of identified modal frequencies for a specific mode, respectively.During the monitoring period, the variation ranges of first four modal frequencies are   four modes vary by 5%-12%, while air temperatures change from −14.1 ∘ C to 22.8 ∘ C, which is sufficient to mask those caused by structural damage.Because of the inherent variability in modal frequency caused by temperature, the correlation and quantitative models must be developed for eliminating temperature effect on structural damage detection.

Mass Variation.
Concrete blocks have the same crosssectional dimensions with the RC slab and beam.They are placed on the side of slab and beam and fully exposed to external environment.Static weighing is carried out at the synchronization with modal testing.Mass variations of concrete blocks are reported in Table 3.It is noted that the concrete blocks corresponding to the slab and beam are labeled as "A" and "B," respectively.As can be seen from Table 3, the relative variations in weights of concrete blocks are about 0.3%, which indicates that the changes in the weights of RC slab and beam are generally small.Therefore, air humidity will have little contribution on the total variability of identified modal frequencies, which is consistent with the study conducted by He [34].In his investigation, it is found that change in air humidity has much smaller influence on modal frequencies than change in temperature.frequencies is necessary to explain the physical meaning of modal frequency changes.According to existing literatures, it is widely accepted that the concrete elasticity modulus, geometrical features, constraint, and boundary conditions of bridges are changed with temperature, which cause the variations of modal frequencies.In this paper, the elasticity modulus of concrete is being referred to as the static elasticity modulus.Xia et al. [15] assume that the mass and boundary condition of slab remain unchanged, and temperature only affects geometrical features and elasticity modulus of concrete.On this basis, theoretical derivation is established for a simply supported slab made of an isotropic material.In order to ensure the correctness and reasonability of assumptions for the research in this paper, the sliding plate rubber supports are placed at one end of slab and beam, which allow the slab and beam to move freely.As demonstrated in Table 3, relative variations in weights of concrete blocks are as small as 0.3% during the monitoring period.Therefore, it is assumed that the variations of modal frequencies would not be affected by mass and boundary condition of slab and beam but only the geometrical features and mechanical properties of material.For a simply supported beam made of an isotropic material, its undamped vertical vibration frequency of order  is expressed as

Effect of Temperature on Modal Frequency
where   is the th order modal frequency; , , and ℎ are the length, width, and height of beam, respectively. is the elasticity modulus, and  is the mass of beam.Variables , , ℎ, and  are the functions of temperature, and the variation percentage of modal frequency can be calculated by where  represents an increment in corresponding variables.
When temperature changes by , elasticity modulus of material changes by , and geometric length changes by .The thermal coefficients of linear expansion (  ) and elasticity modulus (  ) are defined as Therefore, we can obtain Consequently, (3) yields Dimensionless rate of modal frequency change caused by temperature variation is estimated by (6).It can be used to account for the mechanism of temperature effect on modal frequencies of RC slab and beam.As for concrete, the thermal coefficient of linear expansion (  ) is about 1.0×10 −5 / ∘ C, and the thermal coefficient of elasticity modulus (  ) is generally −4.5 × 10 −3 / ∘ C [35].  is significantly much larger than   , which indicates that the variations in modal frequencies subjected to temperature change are controlled by   .However, there is very limited research for   of concrete in ambient temperature range, especially in cold regions.Extensive efforts have been contributed to study the thermal behavior of concrete at high temperature typically generated by fire.
Jiao et al. [36] investigated the changes of elasticity modulus of C30 concrete at temperature range from −20 ∘ C to 60 ∘ C. In their study, fifteen prism specimens (150 mm × 150 mm × 300 mm) are produced for testing the elasticity modulus under different temperatures.The mixture is poured into the steel molds and compacted by vibrating machine.All specimens are removed from the molds after 24 h and cured in the conditions of 20 ± 3 ∘ C and 95% relative humidity.The specimens cured for 28 days are used to test the static elasticity modulus under temperatures −20 ∘ C, 0 ∘ C, 20 ∘ C, 40 ∘ C, and 60 ∘ C according to standard GB/T 50081-2002 [37].In order to eliminate the influence of moisture, concrete specimens are wrapped by preservative film to maintain the stable moisture content.Three specimens are selected as one group for testing the elasticity modulus under specific temperature.The temperatures are jointly controlled by refrigerator and oven.The former is used for −50 ∘ C-0 ∘ C, while the latter is used for 20 ∘ C-300 ∘ C. Each group of specimens are placed in temperature control apparatus for 4 h to make the temperature at the center of specimen be consistent with setting temperature before testing [38].The testing results of elasticity modulus under five temperature grades are illustrated in Figure 10.As can be seen, the elasticity modulus is improved by 48.3% as the temperature decreases from 60 ∘ C to −20 ∘ C. Linear fitting is performed to represent the relationship between elasticity modulus and temperature.It demonstrates a significant linear negative correlation between them.Although only the elasticity moduli under five temperature grades are tested in Jiao et al. 's study, the magnitude of the change rate of elasticity modulus with respect to temperature is credible.Due to the weak statistical relationship between elasticity modulus and temperature, the detailed testing is a subject for further investigation.
Based on the fitted linear formula in Figure 10, thermal coefficient of elasticity modulus corresponding to the elasticity modulus at temperature 0 ∘ C is expressed as the ratio of slope to intercept: From ( 6) and ( 7), a theoretical variation percentage of modal frequency for concrete slab and beam is 0.215% per degree Celsius corresponding to the modal frequency at temperature 0 ∘ C. A finite element (FE) model of concrete slab is constructed using the ANSYS to demonstrate the derived theoretical variation percentage of modal frequency, as shown in Figure 11.It is modeled using the 3D solid elements (Solid 65).The values of material parameters used for the FE model are as follows: the elasticity modulus is temperature-dependent as described in Figure 10, material density is  = 2500 kg/m 3 , and Poisson's ratio is  = 0.2.These parameters are inputted into FE model to calculate modal frequencies with respect to temperatures.The Block Lanczos method in ANSYS is adopted to perform the modal analysis for the FE model of concrete slab [39,40].
The obtained first four modal frequencies under different temperatures and corresponding linear fitting formulas are illustrated in Figure 12.It is shown that the variations of calculated modal frequencies match the tendency of elasticity modulus versus temperature.As the elasticity modulus used in FE model is referred to those in Jiao et al. 's study and is not exactly the same as the real ones in this paper, the calculated modal frequencies are different from the measurements.The FE model is not updated here to match the identified modal frequencies as this is not the objective of the present study.It is focused on the variation percentage of modal frequencies to verify the accuracy of theoretical analysis.The variation percentages of modal frequencies with respect to the modal frequencies at temperature 0 ∘ C are listed in Table 4.It indicates that modal frequencies of FE model are decreased by 0.226% per degree Celsius, which shows a good agreement with theoretical results (0.215%).The numerical calculation results of modal frequencies demonstrate the accuracy of theoretical analysis.

Correlation between Modal Frequency and Temperature.
In vibration-based structural damage identification, temperature influence on modal frequencies is necessary to be eliminated through parametric approaches.A model of relationship between modal frequencies and temperature must be developed in the first step.In this paper, correlations between modal frequencies and temperatures (air temperature, surface temperature, and mean temperature) are analyzed.Air temperature is the temperature measured by digital temperature and humidity sensor in ambient environment.The surface temperature is decided as the mean value of temperatures measured by thermocouples (SH1, SH7, SW1, and SW17) for the slab and (BH1, BH7, BW1, and BW7) for the beam.Mean temperature is obtained by averaging the temperatures from all the thermocouples in the cross section at mid-span.The correlations between the first four modal frequencies and temperatures are illustrated in Figures 13 and 14.The obvious negative correlations between modal frequencies and temperatures can be shown.And one can also observe that dispersion degrees of samples are different among three correlation models.To quantitatively analyze the correlations between modal frequencies and temperatures, coefficients of determination ( 2 ), as the square of coefficient of correlation, are calculated and listed in Table 5.It is found that  2 between modal frequencies and mean temperatures are obviously larger than air temperature and surface temperature, which indicates the more significant correlations between modal frequencies and mean temperatures for slab and beam.Therefore, the relationship between modal frequencies and temperature cannot be sufficiently captured using air temperature or surface temperature.Comprehensive consideration of temperature distribution throughout the slab and beam will improve the correlation.

Simple Linear Regression
Model.The higher correlation between modal frequencies and mean temperature demonstrates that the SLRM possesses favorable fitting performance.The SLRM between modal frequency and mean temperatures is established as where   is the modal frequency fitted by SLRM,  mean is mean temperature, and  0 and  mean are the undetermined regression coefficients.For comparing the variation percentage of modal frequencies versus mean temperature, the slope ( mean ) is normalized to the intercept ( 0 ).The regression coefficients and variation percentages are listed in Table 6.
As can be seen from Table 6, modal frequencies are decreased by 0.12%-0.33%per degree Celsius corresponding to modal frequencies at temperature 0 ∘ C, which agrees with the results (0.215%) from theoretical analysis.It demonstrates that the variation percentage of modal frequency is a function of thermal coefficient of concrete elasticity modulus.As for the beam, the relative variation percentages of modal frequencies in modes 2 and 4 significantly diverge from the theoretical value.In addition,  2 between modal frequencies in modes 2 and 4 and mean temperatures are smaller than  others.This indicates that the SLRM could not accurately quantify the temperature influence on modal frequencies due to the nonuniform and time-dependent properties of temperature distribution in the RC beam.

Multiple Linear Regression Model.
Mean temperature is employed in the construction of SLRM.As the temperature distribution of bridge is significantly nonuniform and time-dependent, the unsatisfactory quantitative results are obtained by using mean temperature, especially for the beam.Therefore, the nonuniform temperature distribution in RC beam is important to be considered for accurately quantifying temperature effect on modal frequencies.MLRM is developed considering nonuniform temperature distribution and expressed as where   is modal frequency predicted by MLRM,  0 - 5 are regression coefficients, and  0 - 4 are explanatory variables.Temperature at the center and corresponding temperature differences are used to describe the nonuniform temperature distribution. 0 is the temperature measured from thermocouple BH4. 1 ,  2 ,  3 , and  4 represent the temperature differences between  0 and the temperatures at BH1, BH7, BW1, and BW7.Specific explanations are shown in Figure 15.
A total of 112 samples are obtained during the monitoring period.The samples measured on 1 November 2015 are chosen as testing samples to verify the prediction performances of quantitative models, and other 104 samples are used as training samples to construct quantitative models.The MLRM between modal frequencies and temperature variables ( 0 ,  1 ,  2 ,  3 , and  4 ) constructed by 104 training samples are listed as follows:  The statistics of  2 for 104 training samples are calculated as 0.958, 0.929, 0.935, and 0.910, which are much higher than SLRM.This indicates that MLRM can achieve a more

Figure 1 :
Figure 1: RC slab and beam constructed for monitoring.

Figure 2 :Figure 3 :
Figure 2: Layout of thermocouples in cross sections at mid-spans of slab and beam (unit: mm).

Figure 4 :
Figure 4: Locations of accelerometers and excitation point.

Figure 6 :
Figure 6: Temperature variations of slab and beam during monitoring period.

Figure 8 :
Figure 8: Identified modal frequencies of slab versus air temperature.

4. 1 .
Theoretical Analysis.Temperature variation affects the modal frequencies of slab and beam in a complicated way.Theoretical analysis for the temperature effect on modal

Figure 9 :
Figure 9: Identified modal frequencies of beam versus air temperature.

Figure 10 :
Figure 10: Temperature effect on the elasticity modulus of concrete.

Figure 11 :
Figure 11: FE model of the concrete slab.

Figure 12 :
Figure 12: Modal frequencies of FE model under different temperature.

Figure 14 :Figure 15 :
Figure 14: Correlations between modal frequencies and temperatures for the beam.

Table 1 :
Mixture proportions of designed concrete.
∘ C and relative humidity ranging from 0% to 99%.A TP700 multichannel data recorder including thermocouple and humidity input module is employed to sample the data collected by type T thermocouples and TP-2307 sensor.It features an autozero channel, a coldjunction compensator, and automatic voltage-temperature conversions for common thermocouple types.Due to the

Table 2 :
Statistics of identified modal frequencies.

Table 3 :
Statistics of measured weights of concrete blocks.

Table 5 :
2 between modal frequencies and temperatures.

Table 6 :
Regression coefficient and variation percentage of SLRM.

Table 7 :
RMSE of reproduced modal frequencies.The temperature data in testing samples are presented into quantitative models for obtaining the predicted modal frequencies.Figure17illustrates the comparison between the predicted and identified modal frequencies.Similar to the reproduction phase, the predicted modal frequencies by SLRM and MLRM vary in step with the identified modal frequencies but deviate from the identified modal frequencies in magnitude.The statistics of RMSE are summarized in Table8.MLRM achieve lower RMSE, which indicates that MLRM possess better prediction capability for testing samples.