Introduction

Radiosondes are one of the most important observation tools used in meteorological studies to measure in situ temperature, pressure, humidity, and horizontal wind above the surface up to around 30 km. There are many vendors supplying radiosondes for operational and scientific observations, and extensive intercomparisons have been conducted .

Traditionally, the hypsometric equation has been used to calculate height information from pressure, temperature, and humidity measurements. Currently, however, global positioning system (GPS) technology is used for altitude derivation, and pressure is inversely derived from the GPS height data . Over the past decade, the old-type radiosondes, which have no GPS receiver, have been replaced by new-type radiosondes with a GPS receiver.

The Vaisala RS80 radiosonde has been used worldwide since 1981, and their market share was 48 % of all radiosonde stations globally as of March 2002 . Recently, it has been reported that the RS80 radiosonde shows a negative pressure bias in the stratosphere e.g.,. Such a negative pressure bias could cause height overestimation; i.e., estimated heights being greater than the actual height. Moreover, this results in a negative temperature offset at a given altitude in the stratosphere, where temperature increases with increasing height. suggested that this RS80 negative pressure bias, together with the changeover to the Vaisala RS92, which is an updated version of the RS80, could lead to a discontinuity in the stratospheric temperature record.

We note here that there are two comparison methods for the measurements from two radiosondes (or ozonesondes or water vapor sondes) which were flown simultaneously with a single balloon. The first one is the “simultaneous sensor comparison” (i.e., at the same time during a flight or for the same air parcel) which is used, e.g., during the World Meteorological Organization (WMO) Radiosonde Intercomparison Campaigns e.g.,. This is appropriate, for example, to evaluate the performance of relative humidity sensors from different radiosonde types. However, the results cannot be readily used for data homogenization because this method does not inherently reveal any potential issues in association with height estimation. If one wants to carefully analyze radiosonde data for some specific period including the instrument switchover from old type to new one, the other comparison method should be used. That is the “comparison on pressure (or altitude or geopotential height) levels” by taking into account vertical profile shifts arising from the different performance in pressure sensors, as performed by, e.g., and .

discussed possible errors in ozone profiles caused by pressure biases from various types of conventional radiosondes, including the RS80. In their Figs. 2, 3, and 10, they actually showed “biased” mixing ratio of ozone plotted on “biased” altitude; however, in their Fig. 7, they showed errors arising when “biased” mixing ratio is plotted on “correct” altitude, which is indicated as “GPS Altitude”. In other words, they evaluated the ozone mixing ratio errors in their Fig. 7 by subtracting the“correct” ozone profile plotted on “correct” altitude from the “biased” ozone profile plotted on “correct” altitude at the same altitude. This error calculation is equivalent to the “simultaneous sensor comparison” as explained above, because the two profiles use the same vertical axis based on the same GPS measurements.

In contrast, in this paper we evaluate observational errors for conventional soundings and to consider artificial offsets in the meteorological records associated with the transition from a period when radiosondes have no GPS unit to a period when they have a GPS unit. This has to be done by the “comparison on pressure (actually geopotential height in our study) levels” as described above. We also compare our results with those of . In this study, we show the impact of the vertical shift on observed temperature profiles (in Sect. ), ozone profiles (in Sect. ), and water vapor profiles (in Sect. ) based on measurements made with an RS80 radiosonde, as well as water vapor and ozone sondes with a GPS unit, obtained during the Soundings of Ozone and Water in the Equatorial Region (SOWER) campaigns.

Data and pressure bias

The SOWER campaigns in the tropical western Pacific/Indonesian region have been conducted in every boreal winter since December 2001 to study processes in the tropical tropopause layer (TTL) e.g.,. During the SOWER campaigns, 33 successful soundings were conducted with the combined use of an RS80 radiosonde, an electrochemical concentration cells (ECC) ozonesonde together with a GPS unit, and a chilled-mirror hygrometer, from December 2003 to January 2010. All of the GPS units were provided by the Garmin Ltd. and situated in the lid of the Environmental Science Corporation (En-Sci) ECC ozonesondes. These data are used in this study (Table 1). We estimate the RS80 pressure bias using these data following the method of , and thus examine how the RS80 pressure bias affects profiles of meteorological parameters such as temperature, ozone, and water vapor. A preliminary consideration of this issue was briefly reported in , but in this paper we present our viewpoint and approach in detail.

Note that the SOWER data were not obtained using the genuine Vaisala system, which automatically corrects pressure data with an independent ground-based barometer, and the SOWER data used in this paper were consolidated according to our quality control (QC) procedure to ensure their uniformity. These data have also been used in previous studies such as and ; the QC procedure is summarized in Appendix A.

Whereas a GPS unit reports an altitude (GPS altitude $\equiv z_{\text{GPS}}$) above the WGS-84 ellipsoid , the geometric altitude ($z$) is defined by the absolute altitude above mean sea level (a.m.s.l.). The geometric altitude $z$ can be converted to geopotential height $Z$ e.g.,, which is used as a vertical coordinate for conventional meteorological data set. In this study, we obtain the geopotential heights from $z_{\text{GPS}}$ by using the station altitude (a.m.s.l.) as the initial GPS altitude. Thus, the precision of $Z$ is the same as that of $z_{\text{GPS}}$, and is accurate to within approximately 20 m between the surface and a height of 34 km . In the following, we use $Z$ values obtained from the GPS as a reference vertical coordinate.

Alternatively, using vertical profile data for pressure ($p$, N m${}^{-\mathrm{2}}$), temperature ($T$, K), and relative humidity (RH: $U$ in %), we can obtain the geopotential height, $Z_{\text{PTU}}$, by hypsometric equation e.g.,: $${\displaystyle }{Z}_{\text{PTU}}\left(p\right)=-\underset{p_{\mathrm{0}}}{\overset{p}{\int }}{\displaystyle {\displaystyle \frac{R_{\text{d}}T}{g_{\mathrm{0}}}}}{\displaystyle {\displaystyle \frac{\mathrm{1}}{p^{\prime }+\frac{U}{100}{p}_{\text{ws}}\left(\frac{M_{\text{w}}-M_{\text{d}}}{M_{\text{d}}}\right)}}}\text{d}{p}^{\prime }+Z_{\mathrm{0}}.$$

Here, $R_{\text{d}}$ is the specific gas constant for dry air (287.05 J K${}^{-\mathrm{1}}$ kg${}^{-\mathrm{1}}$), $g_{\mathrm{0}}$ is the standard acceleration of gravity (9.80665 m s${}^{-\mathrm{2}}$), $M_{\text{d}}$ is the molecular weight of dry air (28.964 kg kmol${}^{-\mathrm{1}}$), $M_{\text{w}}$ is that of water vapor (18.015 kg kmol${}^{-\mathrm{1}}$), $p_{\text{ws}}$ is the saturation water vapor partial pressure [N m${}^{-\mathrm{2}}$] at temperature $T$, and $p_{\mathrm{0}}$ and $Z_{\mathrm{0}}$ are the pressure and geopotential height (a.m.s.l.) at the first step of the integration, respectively. As $Z_{\text{PTU}}$ is calculated from PTU, the precision and accuracy depend on those of the pressure, temperature, and humidity sensors. showed that among these parameters, the accuracy of the pressure sensor is essential in the stratosphere. The Humicap sensor is reliable only up to about 12 km, and the RH values reported by RS80 in the stratosphere is always higher than the actual values. The error of RH sensors in the stratosphere, however, has little influence on our analysis. For example, if we calculate $Z_{\text{PTU}}$ with $U=\mathrm{0}$ above the 200 hPa level, the difference from original $Z_{\text{PTU}}$ (with reported RH) becomes only 3 cm at 30 km. So we used RH values reported by the RS80 radiosonde also in the stratosphere for geopotential height calculation in this analysis.

Differences between $Z_{\text{PTU}}$ and $Z$ ($Z_{\text{PTU}}$ minus $Z$) for all soundings in Table 1 (black lines) and for BI048 observations, which are shown in Figs. , , and as an example (red line). The blue line and horizontal bars indicate the mean difference and 1 standard deviation calculated at each altitude, respectively.

[Figure omitted. See PDF]

Figure  shows the differences between $Z_{\text{PTU}}$ and $Z$ at the same observation time for all soundings listed in Table 1. Although the difference is small ($\sim 20$ m) in the troposphere, it becomes larger in the stratosphere with a difference of $\sim 240$ m at 30 km on average. A similar offset of $Z_{\text{PTU}}$ was reported and discussed by . In the present analysis, the data period was extended to include the 2010 campaign, but data from Hanoi, located in the subtropics, were excluded because we now have sufficient sounding data even from the tropics. The following section shows a typical example of sounding profile (BI048), which is highlighted by a red line in Fig. .

reported a similar profile of geopotential height error of RS80 but their result differs by approximately $-30$ m in whole height region from our result and has larger error bars in the stratosphere. Here, we estimate the uncertainty of our results coming from temperature and RH uncertainties corresponding to the RS80 manufacturer's specifications on our calculation of $Z_{\text{PTU}}$. As a result, temperature uncertainty of 0.20 ${}^{\circ }$C below the 50 hPa level, 0.30 ${}^{\circ }$C from 50 to 15 hPa, 0.40 ${}^{\circ }$C above the 15 hPa level and RH uncertainty of 3 % produce 34 m of $Z_{\text{PTU}}$ uncertainty at 30 km. Since this is about one-third as much magnitude as the error bar shown in Fig. , namely, 90 m at 30 km, we believe the temperature and RH uncertainties do not have significant influence on our analysis.

RS80 pressure bias estimated for all soundings listed in Table 1. Horizontal bars show 1 standard deviation.

[Figure omitted. See PDF]

In recent years, almost all radiosonde systems have used GPS height information together with temperature and humidity to derive pressure ($p_{\text{GPS}}$). In this study, we calculate $p_{\text{GPS}}$ based on the differential form of Eq. (). To avoid perturbed results from the differential equation, we calculate $p_{\text{GPS}}$ after taking the $\pm \mathrm{1}$ min running mean of the GPS height, temperature, and humidity to smooth the profile; the same smoothing was applied to Eq. () for consistency. The $\pm \mathrm{1}$ min smoothing is a different procedure from , who used 1 km median value due to noisy data. If we assume that the typical ascending speed of soundings is 5 m s${}^{-\mathrm{1}}$, the vertical resolution of our smoothing is about 600 m which is somewhat smaller than that of .

Number of successful soundings by the SOWER campaign between December 2003 and January 2010, and the locations of campaign sites.

Figure  shows the statistical feature of the pressure bias; i.e., the differences between observed pressure ($p$) and GPS-derived pressure ($p_{\text{GPS}}$), at the same observation time from the SOWER soundings listed in Table 1. This figure shows that the RS80 pressure bias is significantly negative in the upper troposphere and stratosphere, and is $-0.4\pm 0.2$ hPa (1$\mathit{\sigma }$) between 20 and 30 km. The bias is positive in the lower troposphere, but the uncertainty is large.

This means that we may not be able to eliminate the RS80 pressure biases using a constant pressure correction because the RS80 pressure biases may not be constant with altitude particularly in the troposphere.

Note that the characteristics apparent in Fig.  may be a restrictive result from the SOWER data, because the instrumental propensity of the RS80 could depend on the production lots to some degree.

Nonetheless, also reported a similar bias for the RS80 in the stratosphere; they showed that the biases are $-0.25$ hPa at 30 hPa and $-0.5$ hPa at 10 hPa.

On the other hand, showed that the RS80 pressure biases were $-\mathrm{1}$ hPa in the stratosphere which is larger than that estimated in this study, and the pressure biases have no dependence on the sonde production date. They also estimated that it is larger than that of the RS92, and is similar to the International Met Systems (iMet) series. Here note that even if we do not make our all QC procedures, the estimated pressure biases are $-0.3\pm 1.0$, $-0.3\pm 1.1$, and $-0.5\pm 1.0$ hPa (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively. Thus the results do not change significantly and they are also still different from the result in .

As described in Sect. , discussed the influence of pressure bias on the ozone mixing ratio, but they did not take into account an altitude offset caused by the pressure bias when they evaluated the ozone mixing ratio error (their Fig. 7) as pointed out by as a comment on the discussion paper by . In the following sections, errors in temperature, ozone, and water vapor profiles resulting from the RS80 pressure bias are estimated and discussed in detail.

Impact of pressure bias on observed profiles

Temperature

In Sect. , pressure bias in the RS80 was discussed on the basis of differences between observed $p$ and $p_{\text{GPS}}$, and between $Z_{\text{PTU}}$ and $Z$. As clearly shown in Fig. , $Z_{\text{PTU}}$ systematically differs from $Z$, and this altitude misestimation can affect all meteorological profiles when we only have altitude information from PTU, $Z_{\text{PTU}}$. First, we focus on the temperature profile in this subsection.

(Left) Example of temperature profiles based on $Z_{\text{PTU}}$ ($T\left(Z_{\text{PTU}}\right)\equiv T_{\text{PTU}}\left(Z\right)$; blue dashed line) and $Z$ ($T\left(Z\right)$; red line) measured over Biak on 10 January 2010. (Right) Difference between the two temperature profiles in the left panel, defined as $T_{\text{PTU}}\left(Z\right)$ minus $T\left(Z\right)$ (blue dashed line).

[Figure omitted. See PDF]

Temperature bias caused by the RS80 pressure bias via the altitude error estimated for all soundings listed in Table 1. Horizontal bars indicate one standard deviation.

[Figure omitted. See PDF]

The left panel of Fig.  shows two temperature profiles: $T$ ($Z_{\text{PTU}}$) (blue dashed line) and $T$ ($Z$) (red line), along the vertical coordinates of $Z_{\text{PTU}}$ and $Z$, respectively. The original profile using $Z_{\text{PTU}}$ lies on the upper side of the corrected profile based on $Z$, because there is a positive offset as seen in Fig. . To calculate differences between $T$ ($Z_{\text{PTU}}$) and $T$ ($Z$) on the geopotential height ($Z$) as the “comparison on geopotential height levels” not the“simultaneous sensor comparison”, we need data points for $T$ ($Z$) and $T$ ($Z_{\text{PTU}}$) at the same geopotential height, because the observation time at the same $Z$ and $Z_{\text{PTU}}$ is different. Thus, we map $T$ ($Z_{\text{PTU}}$) on the $Z$ coordinate so as to define $T_{\text{PTU}}$ ($Z$) by using $Z$ in place of $Z_{\text{PTU}}$ ($T_{\text{PTU}}\left(Z\right)\equiv T$ ($Z_{\text{PTU}}$)).

As for Fig.  but for (left) ozone partial pressure ($p{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)\equiv p{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)$ shown by blue dashed line and $p{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$ by the red line) and (center) ozone mixing ratio ($\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)\equiv \mathit{\chi }{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)$ shown by the blue dashed line, and $\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$ by the red line). (Right) Difference in the ozone profiles for partial pressure and mixing ratio ($p{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)$ minus $p{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$ or $\mathit{\chi }{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)$ minus $\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$; blue dashed line).

[Figure omitted. See PDF]

The difference $\mathit{\delta }T\left(Z\right)(\equiv T_{\text{PTU}}(Z)-T(Z$)) is shown in the right panel of Fig. . Because of the vertical shift, we usually see negative values in the stratosphere where temperature increases with increasing height. At around 30 km, an altitude shift of 230 m can produce a negative temperature offset of about $-1.2$ K. This temperature offset is easily confirmed as the vertical gradient of temperature (5.0 K km${}^{-\mathrm{1}}$ in this case) multiplied by the vertical shift (0.23 km in this case). We also see some fluctuations in the temperature differences associated with gravity waves and/or equatorial waves.

Figure  shows an average temperature offset; i.e., the average difference of the two temperature profiles, $T_{\text{PTU}}$ ($Z$) and $T$ ($Z$) for all available soundings listed in Table 1. In the stratosphere, the temperature offset tends to increase with increasing altitude, and it is approximately $-0.2\pm 0.2$, $-0.2\pm 0.4$, and $-0.4\pm 0.9$ K (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively. This result is almost consistent with temperature change expected for a pressure sensor changeover from RS80 to RS92 shown in , but their estimate is somewhat smaller (larger) than our result in the lower (middle) stratosphere. This discrepancy may be caused by a difference of temperature profile between the tropics and mid-latitude.

As for Fig.  but for ozone partial pressure and mixing ratio.

[Figure omitted. See PDF]

Ozone

The vertical shift of the height coordinate caused by the RS80 pressure bias can also affect other observation parameters. argued that what we really need to know as ozonesonde users is the difference between the true profile obtained using a GPS unit and the observed profile obtained using a conventional pressure sensor. However, the result in applies only to those cases where we can use coincident ozone data with pressure information derived from the GPS height to calculate the ozone mixing ratios correctly. The ECC ozonesonde reports ozone partial pressure as its measurement principle e.g.,. The left panel of Fig.  shows two vertical profiles of ozone partial pressure, one using $Z_{\text{PTU}}$ ($p$O${}_{\mathrm{3}}$ ($Z_{\text{PTU}})\equiv p$O${}_{{\mathrm{3}}_{\text{PTU}}}\left(Z\right)$) and the other $Z$ ($p$O${}_{\mathrm{3}}\left(Z\right)$), as for Fig. . The profiles are taken from the same sounding as shown in Fig. . In the tropical region, ozone partial pressure has a maximum at approximately 27 km; consequently, the vertical gradient changes from positive to negative at around this level with increasing height.

As for Fig.  but for (left) water vapor partial pressure ($p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z_{\text{PTU}}\right)\equiv p{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$ shown by the blue dashed line, and $p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$ by the red line) and (center) water vapor mixing ratio ($\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z_{\text{PTU}}\right)\equiv \mathit{\chi }{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$ shown by the blue dashed line, and $\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$ by the red line). (Right) Difference in the ozone profiles for partial pressure and mixing ratio ($p{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$ minus $p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$ or $\mathit{\chi }{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$ minus $\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$; blue dashed line).

[Figure omitted. See PDF]

As the ozone mixing ratio ($\mathit{\chi }$O${}_{\mathrm{3}}$) is obtained by dividing ozone partial pressure by atmospheric pressure, the atmospheric pressure bias can lead to an error in the ozone mixing ratio. This effect has already been discussed by , based on the following definition of the ozone mixing ratio error ($\mathit{\delta }\mathit{\chi }$O${}_{\mathrm{3}}$): $${\displaystyle }\mathit{\delta }\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)={\displaystyle {\displaystyle \frac{\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)-\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}{\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}}},$$ where $\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)$ and $\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$ are $p{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)/p\left(Z_{\text{PTU}}\right)$ and $p{\mathrm{O}}_{\mathrm{3}}\left(Z\right)/p_{\text{GPS}}\left(Z\right)$, respectively. Note that used these ozone partial pressures and atmospheric pressures at the same observation time when they evaluated the ozone mixing ratio error (their Fig. 7). However, as we have already explained, there is a difference between $Z_{\text{PTU}}$ and $Z$, and the mixing ratio error ($\mathit{\delta }\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}$) should be examined at the same altitude.

The middle panel of Fig.  is the same profile as in the left panel, but for the ozone mixing ratio. The mixing ratio error can be estimated as the difference between the original mixing ratio based on $Z_{\text{PTU}}$ ($\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z_{\text{PTU}}\right)\equiv \mathit{\chi }{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)$); blue dashed line) and the mixing ratio based on $Z$ ($\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$; red line) at the same geopotential height. As $\mathit{\chi }{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)\equiv p{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)/p\left(Z\right)$, Eq. () should be replaced by the following equation: $$\begin{array}{cc}\mathit{\delta }\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)& =\frac{\mathit{\chi }{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)-\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}{\mathit{\chi }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}\\ & & =\frac{\frac{p{{\mathrm{O}}_{\mathrm{3}}}_{\text{PTU}}\left(Z\right)}{p\left(Z\right)}-\frac{p{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}{p_{\text{GPS}}\left(Z\right)}}{\frac{p{\mathrm{O}}_{\mathrm{3}}\left(Z\right)}{p_{\text{GPS}}\left(Z\right)}}.\end{array}$$

If temperature and humidity are uniform in vertical, $p_{\text{GPS}}\left(Z\right)$ is exactly equal to $p\left(Z\right)$. Therefore, the percentage error of mixing ratio exactly corresponds to the percentage error of partial pressure. In reality, however, temperature and humidity are not uniform, so these vertical profile shifts make $p_{\text{GPS}}\left(Z\right)$ different from $p\left(Z\right)$ at the same geopotential height. Nevertheless, the differences are very small. For example, 0.5 K of temperature offset in the stratosphere (e.g., 30 km) where temperature is 230 K produces only 0.2 % pressure difference (i.e., 0.5/230 K). This is much smaller than the ozone partial pressure offsets estimated in this section. Therefore, Eq. () is almost the same as the error for ozone partial pressure with an uncertainty of 0.2 %. Hence we present only the error for partial pressure representing both errors and simply write the two as $\mathit{\delta }{\mathrm{O}}_{\mathrm{3}}$. The right panel of Fig.  shows such a percentage difference for $\mathit{\delta }{\mathrm{O}}_{\mathrm{3}}\left(Z\right)$. As expected from the left panel, it changes sign at around 27 km.

Figure  shows an average percentage difference calculated from all available soundings. Although the offset is small in the troposphere, it becomes larger in the lower stratosphere with a negative peak at around 20 km. At around 27 km, where there is a maximum of ozone partial pressure, the sign of ozone offset changes. The ozone offset is estimated to be $-1.9\pm 1.6$, $-0.7\pm 0.9$, and $3.2\mathit{\%}\pm 2.2$ % (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively.

found that the pressure bias of the RS80 was $-\mathrm{1}$ hPa, which is somewhat larger than ours, as was their resulting ozone mixing ratio offset, which exponentially increases with increasing altitude. According to Fig. 7 in their paper, the ozone mixing ratio offset was approximately 2, 4, and 10 % at 20, 25, and 30 km, respectively. These estimates are based on $p_{\text{GPS}}$ derived from the coincident GPS altitude. On the other hand, we estimated the RS80 pressure bias in such a case to be $-0.4$ hPa, and the subsequent ozone offset to be negative ($-\mathrm{1}$ to $-\mathrm{2}$ %) at around 20–25 km, but positive (3 %) at 30 km, which is not an exponential increase with increasing altitude.

Water vapor

Profiles of water vapor in the stratosphere are observed using a chilled-mirror hygrometer that measures the frostpoint temperature as its measurement principle e.g.,: such a high-performance hygrometer is necessary for this analysis. A profile of water vapor partial pressure and mixing ratio can be estimated from the frostpoint temperature using the Goff–Gratch equation . In the SOWER campaign, water vapor profiles for the tropical lower stratosphere, as well as the troposphere, were observed using such chilled-mirror hygrometers.

A vertical profile of water vapor partial pressure based on $Z_{\text{PTU}}$ ($p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z_{\text{PTU}}\right)\equiv p{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$; blue dashed line) and a profile based on $Z$ ($p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$; red line) are shown in the left panel of Fig. . The water vapor mixing ratio is obtained by dividing partial pressure by atmospheric pressure ($\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\equiv p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}/p$); two profiles based on $Z_{\text{PTU}}$ ($\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z_{\text{PTU}}\right)\equiv \mathit{\chi }{{\mathrm{H}}_{\mathrm{2}}\mathrm{O}}_{\text{PTU}}\left(Z\right)$) and $Z$ ($\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\left(Z\right)$) are shown in the middle panel. As for ozone, because the percentage error in partial pressure ($\mathit{\delta }p{\mathrm{H}}_{\mathrm{2}}\mathrm{O}$) and that of the mixing ratio ($\mathit{\delta }\mathit{\chi }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}$) become almost the same at the same altitude with an uncertainty of 0.2 % (see Eqs. –), we present only the error for partial pressure representing both errors and simply write the two as $\mathit{\delta }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}$, and such a percentage error is shown in the right panel of Fig. .

As is well known, the water vapor profile in the tropical lower stratosphere has a “tape recorder” signal , and we can see such a signal in the vertical structure of the water vapor mixing ratio profile in Fig. , with the minimum at around 18 km, the maximum at around 20.5 km, and a weaker minimum at around 22 km. This vertical structure is similar to those profiles measured at Costa Rica in December–January–February 2008 shown in Fig. 3 of . As their observation period was 2 years earlier than that of the BI048 observations, the two periods should be in a similar phase of the stratospheric quasi-biennial oscillation (QBO). The water vapor partial pressure profile also has a vertical structure corresponding to that of the mixing ratio, and $\mathit{\delta }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}$ changes sign associated with the water vapor maximum at 20.5 km, as shown in the right panel.

As for Fig.  but for water vapor partial pressure and mixing ratio.

[Figure omitted. See PDF]

As for Fig.  but for the biases based on relative altitude with reference to that of the water vapor minimum near the CPT.

[Figure omitted. See PDF]

An average percentage difference for water vapor calculated from all available soundings is shown in Fig. . The average error in the water vapor profiles was estimated to be $-0.9\mathit{\%}\pm 2.1$ % at 18 km and $1.4\mathit{\%}\pm 0.9$ % (1$\mathit{\sigma }$) at 21 km associated with the tape recorder signal. The altitudes of the cold point tropopause (CPT) and water vapor minima near the CPT vary seasonally and interannually. To focus on offsets near the CPT, where the water vapor profiles have a steep gradient and minimum, we aligned the water vapor profiles according to the water vapor minimum. Figure  shows the average error based on relative altitude with reference to that of the water vapor minimum around the CPT. We can see that the offset is clearer than that in Fig. , and is estimated to be $-1.4\mathit{\%}\pm 2.3$ % at 0.5 km and $1.4\mathit{\%}\pm 1.0$ % (1$\mathit{\sigma }$) at 3.5 km above the water vapor minimum. As there is a negative and steep gradient of water vapor abundance in the upper troposphere, a small positive error of $z_{\text{PTU}}$ produces a positive water vapor error at around 16 km in Fig. , and also below the water vapor minimum in Fig. . We note here that this result is based on limited soundings obtained during the boreal winter and that the vertical distribution of water vapor error in the stratosphere may differ somewhat from this result depending on the phase of the tape recorder signal. It should be noted that the results are based on approximately 20 m of the altitude offset near the cold-point tropopause. This value is comparable to the uncertainty of the geopotential height and also to the uncertainty of the GPS unit. Also, the uncertainty of CFH measurements is estimated to be 9 % or smaller in the upper troposphere and lower stratosphere . This value is larger than water vapor offset due to the pressure biases of RS80.

Discussion

As described above, the RS80 pressure bias leads to temperature, ozone, and water vapor offsets. If we assume that RS80 radiosondes without a GPS unit were switched to new radiosondes with a GPS unit during the period 2000–2010, we would expect to see such offsets in the meteorological parameters that may affect any trend analysis that covers this period. In this section, we discuss issues related to long-term trends in temperature, ozone, and water vapor, together with the possible impacts on these trends of offsets associated with altitude misestimation.

estimated temperature trends from satellite, sonde, and GPS radio occultation (RO) data between 2001 and 2010. This includes the period when the RS80 was progressively replaced by the new radiosonde system. They reported warming trends from 13 to 25 km over the tropics, as well as whole latitude region, and that the trend obtained from sonde measurements was 0.2 K dec${}^{-\mathrm{1}}$ higher than that obtained from satellite observations. The altitude range for their trend analysis included both the troposphere and the stratosphere, as they focused on a comparison with satellite data having a coarse vertical resolution. The discrepancy between the trends based on the sonde and satellite measurements can be interpreted to be caused by the RS80 temperature offset estimated in this study, as it is consistent with the value ($+0.2$ K) averaged over 13–25 km from Fig. . At the same time, however, reported a comparable trend from GPS RO measurements to that from sonde measurements. These temperature trends should be estimated as a function of altitude and be compared in the troposphere and the stratosphere separately.

reported that the ozone mixing ratio follows a negative trend of $-\mathrm{4}$ and $-0.5$ % dec${}^{-\mathrm{1}}$ in the stratosphere from 17 to 23 km and from 23 to 30 km, respectively, based on measurements from the Stratospheric Aerosol and Gas Experiment II (SAGE II) satellite (1984–2005) and the Southern Hemisphere Additional Ozonesondes (SHADOZ) network (1998–2009). They pointed out that the negative trends in the lower stratosphere are a dynamical response to enhanced tropical upwelling. On the other hand, reported positive trends in the same altitude region based on SCanning Imaging Absorption spectroMeter for Atmospheric CHartographY (SCIAMACHY) satellite measurements (2002–2012). In particular, they argued that the positive trend between 25 and 30 km cannot be explained in terms of enhanced tropical upwelling.

As discussed above, a switch from the RS80 to the new GPS radiosondes may create an artificial ozone trend; i.e., a positive trend of 1–2 % dec${}^{-\mathrm{1}}$ at around 20 km, and a negative trend of $-\mathrm{3}$ % dec${}^{-\mathrm{1}}$ at 30 km. It is possible that the negative trend is larger than that estimated by in view of the present results.

In addition to the annual variations reflected in the tape recorder signal, water vapor abundance in the upper troposphere and lower stratosphere shows interannual variations depending on the El Ninõ–Southern Oscillation (ENSO) and the QBO e.g.,. For longer-term variations, reported that water vapor in the mid-latitude lower stratosphere from 16 to 26 km decreased during the period 2001–2005 by an average of 0.4 ppmv, then increased again during the period 2006–2010 by an average of 0.5 ppmv. As for temperature and ozone, the water vapor offset caused by the altitude misestimation affects these water vapor observation records, and the offsets are estimated to be approximately $-1.5$–1.5 %, depending on altitude, in the lower stratosphere.

Whereas the water vapor offset is smaller than its stratospheric trend, those for temperature and ozone are comparable in magnitude to their decadal trends in the lower stratosphere. Therefore, these long-term variations should be discussed after examining and correcting these radiosonde errors.

In this study, we proposed an appropriate approach how to deal with historical data sets affected by the pressure sensor biases. We recommend for the radiosonde/ozonesonde/water vapor sonde communities to apply this method to historical data sets (one example of correction for sounding data without a GPS unit shown in Appendix B) to improve our understanding of the stratospheric temperature, ozone, and water vapor trends.

Summary

At present, GPS technology is used to measure altitude, and pressure is inversely derived from the GPS height data. Although the Vaisala RS80 radiosonde was used worldwide from 1981, such old-type radiosondes without a GPS receiver have been replaced by new-type radiosondes with a GPS receiver over the past decade. Recently, it has been reported that the RS80 radiosonde shows a negative pressure bias in the stratosphere e.g.,.

There are two methods for comparison of two simultaneous radiosonde sounding data, i.e., the “simultaneous sensor comparison” and the “comparison on pressure (or altitude or geopotential height) levels”. evaluated ozone mixing ratio errors caused by pressure biases from various types of conventional radiosondes, but they used the former method for the evaluation. The latter method, however, is useful for the researchers who are considering to make corrections and data homogenization of conventional sounding data without GPS units.

In this study, we evaluate sounding errors associated with the RS80 pressure biases in conventional sounding data using an approach of the “comparison on geopotential height levels. We estimated that the pressure bias in the tropical stratosphere, as assessed using the SOWER data set for the period from December 2003 to January 2010, is $-0.4\pm 0.2$ hPa (1$\mathit{\sigma }$) from 20 to 30 km. We also estimated that this pressure bias could lead to an altitude misestimation of $43\pm 23$, $110\pm 40$, and $240\pm 92$ m (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively.

This altitude misestimation can lead to offsets in other meteorological profiles, such as temperature, ozone, and water vapor. We found that in the stratosphere the temperature offset caused by such altitude misestimation tends to increase with increasing altitude, and it is approximately $-0.2\pm 0.2$, $-0.2\pm 0.4$, and $-0.4\pm 0.9$ K (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively. On the other hand, for the ozone offset its sign changes at 27 km where there is a maximum of ozone partial pressure, and it is estimated to be $-1.9\pm 1.6$, $-0.7\pm 0.9$, and $3.2\mathit{\%}\pm 2.2$ % (1$\mathit{\sigma }$) at 20, 25, and 30 km, respectively. For water vapor, there is a minimum and maximum in the tropical lower stratosphere associated with the tape recorder signal. Thus, the water vapor offset is affected by the phase of the tape recorder and is estimated to be $-1.4\pm 2.3$ % at 0.5 km and $1.4\mathit{\%}\pm 1.0$ % (1$\mathit{\sigma }$) at 3.5 km above the water vapor minimum around the cold point tropopause.

These temperature, ozone, and water vapor offsets may produce an artificial change in long-term meteorological records at the time when the radiosonde system changed from the RS80 to the new model. Therefore, we must take these issues into account if we are to compile accurate meteorological data sets and improve our understanding of climate change.

As for Fig. but for profiles using non-QC data.

[Figure omitted. See PDF]

Frequency distribution of pressure offset, which was empirically determined using our QC procedure. The data are split into $\pm 0.25$ hPa bins with an increment of 0.5 hPa and a total of 38 soundings.

[Figure omitted. See PDF]

Here, we describe how we processed the original pressure profiles prior to analysis. Each pressure sensor in the RS80 radiosondes has its own uncertainty, in addition to the pressure bias described in this paper. If we plot the differences between $z_{\text{PTU}}$ and $z$, similar to Fig.  but using uncorrected (original) profiles, the result is as in Fig. . We see larger variability of profiles in this figure than in Fig. , because original pressure information sometimes includes a large error. To reduce this variation, we made a correction by using a constant offset value for the entire height range. The correction value was subjectively determined to fit a profile to the average. A frequency distribution of the correction values for pressure offset is shown in Fig. . On the basis of these statistics, we excluded five profiles using the criterion that the absolute value of the pressure offset should not be larger than 1.5 hPa, and so used 33 soundings (out of a total of 38) in this study.

(Left) Profile of ozone partial pressure measured without a GPS unit at 22:18 on 13 January 2006 (UT) (blue line) and that recalculated with corrected pressure by subtracting the pressure bias shown in Fig.  from the original value (green dashed line). (Right) Percentage of correction amount due to the pressure correction (green dashed line).

[Figure omitted. See PDF]

We show an attempt to correct sounding errors without GPS information using a sounding example of the SOWER data measured without a GPS unit. Figure  shows an original and a corrected profiles of ozone partial pressure measured without a GPS unit and the difference between the two. Even if we can not perfectly evaluate sounding errors and correct them when an ozonesonde (or a water vapor sonde) is launched without GPS units, we can correct them if we assume that a statistical characteristic of radiosonde pressure bias in data set measured without GPS units would not differ from that in this study, which is shown in Fig. . On the basis of this assumption, the profile in green was recalculated with corrected pressure by subtracting the bias from its original pressure value.

Acknowledgements

The authors are grateful to SOWER colleagues, K. Shimizu, S.-Y. Ogino, S. Iwasaki, N. Nishi, and T. Shibata for their assistance. We also thank the members of Lembaga Penerbangan dan Antariksa Nasional (LAPAN) of Indonesia, and the Meteorological Office of Tarawa, Kiribati. This work was supported by KAKENHI, Japan Society for the Promotion of Science, Japan (15204043, 16740264, 18204041, and 21244072), and the Global Environment Research Fund of the Ministry of the Environment (A-1 and A-071). The figures were produced by the GFD-DENNOU Library. We also thank three anonymous reviewers and Ryan Stauffer for valuable comments. Edited by: A. Stoffelen