Optimal Selection of Earthquake Resisting Schemes for Jakarta-Bandung High-Speed Railway

e Jakarta-Bandung high-speed railway is the rst overseas project involving China’s high-speed railway. Owing to the high seismic intensity in this area, the optimal selection of earthquake resisting schemes is critical for short-span bridges, and such schemes are related to the safety and cost-eectiveness of the entire line. is study compares the safety and cost-eectiveness of four earthquake resisting schemes: (i) prestressed concrete (PC) simply-supported box beams using common spherical steel bearings; (ii) PC simply-supported box beams using seismic isolation bearings; (iii) steel-concrete (SC) composite simplysupported beams using seismic isolation bearings; (iv) reinforced concrete (RC) rigid frames. e results indicate that PC beams using more expensive seismic isolation bearings reduce the cost of the substructure, making it more cost-eective. In contrast, the scheme of SC composite beams is the most expensive one, and the associated maintenance costs are also the highest. Although the scheme of RC rigid frames is the cheapest among the evaluated schemes, it is only suitable for relatively sti sites with low pier heights. Overall, PC beams with isolation bearings exhibit good seismic performance and are suitable for prefabricated construction; therefore, this scheme can be applied in various soil conditions with relatively low costs, and it is recommended for use throughout the entire Jakarta-Bandung high-speed railway.


Introduction
High-speed railway construction has entered a rapid development period all over the world. To reduce land coverage, the rule of "substituting a bridge for subgrade" is often adopted in the design and construction of high-speed railways. Bridges account for up to 70%-80% of the entire rail line in terms of length, and most are short-span bridges [1][2][3][4][5][6]. erefore, selecting the optimal earthquake resisting scheme for short-span bridges is crucial to maximizing the safety, serviceability, and economy of high-speed railways in high seismic intensity regions. Such schemes are in uenced by various factors, including the natural climatic conditions, the tra c requirements, and the local site-speci c conditions. e beam must be su ciently sti to allow the trains to run smoothly enough to meet the high standards required for a high-speed railway. Meanwhile, the weight of the superstructure should be reduced to minimize the seismic response. Prestressed concrete (PC) simply-supported box beams are generally implemented for short-span bridges in China's high-speed railways [1][2][3][4][5][6], whereas reinforced concrete (RC) rigid frame bridges are adopted for Japanese Shinkansen railways on a large scale [7,8], and steel-concrete composite (SC) beams are often used in France [1].
For high-speed railway bridges in strong earthquake conditions, both ductility seismic and isolation seismic systems have been introduced by designers [9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. Kang et al. [9] evaluated the seismic damage to high-speed railway bridge components under various earthquake excitation intensities. Chen et al. [10] studied the seismic response of a high-speed railway simply-supported girder bridge. Wei et al. [11] investigated the seismic vulnerabilities of a high-speed railway bridge by considering track-bridge interactions. Li et al. [12,13] studied the effects of seismic isolation on the seismic response of a high-speed rail prototype bridge in California. Xia et al. [14] investigated the seismic damage and seismic performance of various bridge types. Bai [15] compared structural form selections for small and mediumsized bridges along the Beijing-Shanghai high-speed railway in China. Xie et al. [16] systematically identify and quantify the damage states, repair actions, repair costs, and travel delay losses for China's high-speed railway multi-span simply-supported bridge system. Cui et al. [17] conducted the seismic fragility and risk assessment of a typical highspeed continuous girder bridge. Guo et al. [18] investigated the seismic damage features of high-speed railway simplysupported bridges under near-fault earthquakes. Shan et al. [19] proposed a novel fragility analysis method for irregular bridges in high-speed railways. Meng et al. [20] assessed the design and seismic mitigation performance of shock absorbers for a railway bridge with a simply-supported beam. Zheng et al. [21,22] studied the application of seismic devices, including friction pendulum bearings and E-shaped metallic dampers. Xia et al. [23] evaluated the seismic performance of friction pendulum bearings. Jiang et al. [24] studied the effects of friction-based fixed bearings on seismic performance of high-speed railway simply-supported bridge. Guo et al. [25] proposed an improved equivalent energy-based design procedure for seismic isolation system of simply-supported bridges in China's high-speed railways. Other related research works include train-track-bridge interaction of high-speed railway bridges, seismic design method research of bridge bents, and so on. Guo et al. [26] studied the train-track-bridge interaction in high-speed railways and proposed a real-time hybrid simulation method using the moving load convolution integral method. Shi et al. [27] proposed a toggle BRB system for the seismic retrofit of bridge bents and the corresponding design method. Mitoulis et al. [28] conducted a cost-effective analysis related to the earthquake-resisting system of multispan motorway bridges. However, limited studies are comparing the economy and safety of common earthquake resisting schemes applied to bridges on high-speed railways.
Indonesia's Jakarta-Bandung high-speed railway represents a successful application and major breakthrough concerning the "going out" policy of China's high-speed railway. It provides an important demonstration that supports the brand of "China's high-speed railway" throughout the world.
is study takes the short-span bridge of the Jakarta-Bandung high-speed railway as an example and compares the following bridge earthquake resisting schemes: (i) PC simply-supported box beams using common spherical steel bearings, (ii) PC simply-supported box beams using seismic isolation bearings, (iii) SC composite simply-supported beams using seismic isolation bearings, and (iv) RC rigid frames. e safety and cost-effectiveness of these four schemes are evaluated and compared in detail. e results provide a useful basis for the selection of the earthquake resisting systems throughout the entire line and offer a reference for similar high-speed railway projects in high seismic intensity regions.

Description of the Project and
Earthquake Input e total length of Indonesia's Jakarta-Bandung high-speed railway is 142.3 km. e project is part of the high-speed railway line that connects Jakarta to Surabaya, which has a total length of approximately 800 km. e designed running speed is 350 km/h. After completing the railway, the traveling time from Jakarta to Bandung will be reduced from the current 3 hours to only 40 minutes. e high-speed railway will adopt a cooperation mode involving joint venture construction and management by China and Indonesia enterprises.
As the first "going out" project of China's high-speed railway, the Jakarta-Bandung high-speed railway will apply the technical standards, surveys, designs, facilities, engineering construction, management, and operation of China's high-speed railways, and it will promote China's "one belt and one road" policy.
According to the seismic ground motion parameters zoning map developed based on the Indonesian code for seismic design of bridges [29], the peak acceleration along the Jakarta-Bandung high-speed railway line is equal to that of a site with a seismic intensity of 8 or 9 in China [30]. erefore, the seismic response of bridges is a decisive parameter for selecting the resisting scheme. Moreover, comparative results depend on the geological conditions and seismic parameters of the site. e standard technical parameters are as follows: design speed � 350 km/h; track type � ballastless track; mainline design � double track; design load � Chinese ZK live load. e design parameters influencing the ground motion are as follows: site soil type � Type II (moderately firm soil where the interval range of the shear wave velocity is between 250 and 500 m/s). e peak acceleration and characteristic period are 0.14 g and 0.5 s, respectively, for low-level earthquakes (i.e., earthquake recurrence interval ≈50 years); the peak acceleration and characteristic period are 0.34 g and 0.74 s, respectively, for design earthquakes (i.e., earthquake recurrence interval ≈ 475 years); peak acceleration and characteristic period are 0.57 g and 0.89 s for high-level earthquakes (i.e., earthquake recurrence interval ≈ 2475 years). Figure 1 presents the design response spectra for these three earthquake levels. Time history analyses have been conducted by matching the seismic time curves against the spectra given in the code governing the seismic design of railway engineering in China (China Railway Code, an abbreviation for the code) [30].

Seismic Calculation Principles
e Eurocode for the earthquake resistance of bridge structures [31] dictates that in regions of moderate to high seismicity, it is generally preferable (for economic and safety reasons) to design a bridge with ductile behavior, i.e., to provide reliable means to dissipate a significant amount of the input energy under severe earthquake conditions. is is accomplished via an intended configuration of flexural plastic hinges or by using isolating devices.
In seismic bridge design specifications for the United States [32], for Seismic Design Category (SDC) C or D, all bridges and their foundations must have a clearly identifiable earthquake resisting system that satisfies the life safety criteria. Moreover, the design should be based on one of three earthquake resisting systems: (1) a ductile substructure with an essentially elastic superstructure (e.g., for conventional concrete bridges), where seismic energy can be dissipated through the plastic hinges in piers and bents; (2) an essentially elastic substructure with a ductile superstructure (e.g., only for steel superstructures), where ductility is derived from ductile elements in the pier cross-frames; (3) an elastic superstructure and a substructure with a fusion mechanism between the two (e.g., for seismically isolated structures and structures with supplemental energy dissipation devices, such as dampers, to control inertial forces transferred between the superstructure and substructure).
In China Railway Code [30], bridges in regions with seismic intensities >7 should undergo ductile checks of the RC piers under rare earthquake conditions. Additional mitigation and isolation design strategies can be applied for bridges in areas with higher seismic intensities.
Considering the codes or specifications of various countries, the two most applicable earthquake resisting systems are ductility seismic and isolation seismic systems. In this study, the first and fourth schemes involve ductility seismic systems, whereas the second and third schemes use isolation seismic systems.
e Jakarta-Bandung high-speed railway is the first overseas project of China's high-speed railway, and therefore, the seismic design of bridges should be completed according to China Railway Code [30]. e three levels of seismic fortification goals are as follows: (1) low-level earthquakes (63% probability exceedance in 50 years) cause the bridges to sustain negligible or slight damage, and they can still work elastically; (2) design earthquakes (10% probability exceedance in 50 years) cause damage, but bridges can be readily inspected and repaired; (3) high-level earthquakes (2% probability exceedance in 50 years) may induce significant damage to the bridges, but they would not collapse.
For the seismic design of the ductility system, pier reinforcement should be monitored under low-level earthquake conditions. e strength of the connection between the superstructure and substructure should be checked under design earthquake conditions, and the ductility calculation should be conducted to prevent collapse following high-level earthquakes. Nonlinear time historical analysis should be implemented to assess the elastic-plastic deformation under rare earthquake conditions according to equation (1) [30]: where μ u is the nonlinear displacement ductility ratio; [μ u ] is the allowable displacement ductility ratio (herein defined as 4.8 in provision 7.3.3 of China Railway Code [30]. e value has considered safety assurances rate, thus can guarantee the safety of bridges.);Δ max is the largest nonlinear displacement of piers;Δ y is the yielding displacement of piers.
For the seismic design of the isolation system, pier reinforcement should be monitored under low-level earthquake conditions in the same way. In a rare earthquake scenario, piers should remain elastic and may sustain slight damage owing to the protection of isolation devices. Moreover, the working conditions of the isolation devices should be checked regularly to ensure proper functioning under rare earthquake conditions.

Prestressed Concrete Simply-Supported Box Beams with Common Bearings
PC simply-supported box beams are generally implemented for short-span bridges along China's high-speed railway. is structure has various advantages, including high stiffness, simple working mechanism, and beautiful appearance. Moreover, PC beams can be constructed quickly using a prefabricated construction method. e most extensively used beams have a span of 32 m. e calculated length of the beam is 31.5 m, and the total length is 32.6 m. Since the gap between the adjacent beams is 0.1 m, the standard span of the beam is 32.7 m as shown in Figure 2. erefore, PC simply-supported box beams with a span of 32 m were used in this study. According to the Jakarta-Bandung high-speed railway statistics, the average height of the piers is approximately 15 m. A multi-span simply-supported beam with a height of 15 m is depicted in Figure 2.
In order to eliminate the boundary effect, the four-span 32-m beam was taken as an example. Common spherical steel bearings were used on the pier top. ere were two fixed bearings and two longitudinal sliding bearings. Soil springs under the bottom of the piers were modeled to simulate the interactions between the foundation and the structures. e overall computed seismic beam model is shown in Figure 3x, y and z axes represent the longitudinal, transverse, and vertical axis of the bridge, respectively. Design earthquake Acceleration Sd (T) (g) Figure 1: Design response spectra.
Advances in Civil Engineering e cross-section of the deck is a box-girder with a total width of 12.4 m ( Figure 4). e bridge deck arrangement for a double ballastless track is also shown in Figure 4. e piers are wall-like columns ( Figure 5), and their cross-sections are rounded. e bridge piers are founded on Type II ground, as defined by China Railway Code [30], via 11 pile groups, each with a diameter of 1.0 m. Concrete C50 and C40 and steel rebar HRB400 (Hot-rolled Ribbed Bar) as defined in Chinese code for the design of concrete structures of the railway bridge and culvert [33] were used in the scheme. e mechanical properties of concrete and steel rebar are shown in Tables 1 and 2, respectively. e concrete of the beam is C50, and the concrete of the piers, pile caps and piles is all C40. e primary load-bearing steel rebar used in the piers is HRB400. e longitudinal cross-section of the common steel fixed bearings is shown in Figure 6. e total flexibility of the foundations was taken into account by implementing linear soil spring elements. e translational and rotational stiffness values of the springs are given in Table 3. ese values adopted were determined by the geotechnical in situ tests conducted for the bridge. e seismic design was prepared in accordance with China Railway Code [30]. Pier reinforcement should be checked under low-level earthquake conditions. e strength of the connection between the superstructure and substructure should be monitored under the design earthquake scenario, and ductility calculations should be performed to prevent collapse under high-level earthquake conditions.

Low-Level Earthquake.
A low-level earthquake controls the reinforcement ratio of the piers. e peak ground acceleration of the low-level earthquake is 0.14 g, which is equal to a seismic intensity of 9 in the China Railway Code [30]. Table 4 gives the pier bottom internal forces of the P3 pier following longitudinal and transverse earthquakes. e HRB400 reinforcement bar with a diameter of 32 m was used, and the reinforcement ratio was 1.63%, as shown in Figure 7. For the longitudinal earthquake, the largest stress of the concrete and steel rebar is 13.5 MPa and 300.0 MPa, respectively. For the transverse earthquake, the largest stress of the concrete and steel rebar is 15.9 MPa and 308.9 MPa, respectively.

Design Earthquake.
e longitudinal force of the bearing should be checked under the design earthquake scenario. e ratio between the longitudinal force and the vertical capacity can then be calculated. e longitudinal force of the bearing is approximately 5605 kN, which is 1.25 times the vertical bearing capacity of 4500 kN. Generally, along with the increasing of the horizontal force of the bearing, the difficulty of manufacturing is also increasing.
us, the cost of the bearing would increase significantly.

High-Level Earthquake.
Under high-level earthquake conditions, ductility analysis of the pier bottom must be conducted to determine whether the bridge pier is damaged.
If ductile damage has occurred, the nonlinear displacement ductility ratio is calculated. According to provision 7.3.3 of the China Railway Code [30], the allowable displacement ratio is 4.8. For the studied bridge, the displacement at the yielding moment is 9.5 cm, and the ultimate displacement is 22.59 cm. us, the calculated ductility ratio is 2.38, which is smaller than the allowable ratio of 4.8, and the performance level required for "no-collapse" under rare earthquake conditions is satisfied. According to capacity protection theory, the piles should work elastically before the piers suffer from plastic damage. erefore, the pile length and reinforcement area should be increased. Table 5 presents the corresponding pile length and reinforcement area under low-level and high-level earthquake conditions.

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According to Table 5, following a low-level earthquake, the calculated pile length is 48 m, and the reinforcement area is 102.1 cm 2 . Following a high-level earthquake, capacity protection theory indicates that the pile length should increase to 56 m, while the reinforcement area should increase to 204.0 cm 2 . e concrete volume increases to 483.8 m 3 , and the rebar weight increases to 98.7 t. e integrated unit price of rebar is RMB 4342.9, and the integrated unit price of concrete is RMB 1368.7. us, the total cost increases by approximately 339k RMB.

Prestressed Concrete Simply-Supported Box
Beams with Isolation Bearings e piers of bridges with common spherical steel bearings in high-intensity seismic regions may suffer significant damage, which is difficult and costly to repair. Moreover, the bearings themselves may also be damaged, and the longitudinal and transverse restrainers would likely be broken. e fixed bearings would become movable bearings and, in consequence, the entire structural system would be a pure sliding friction system. Although such a system (with no restoring ability) is beneficial for the substructures, the superstructures cannot be restored to their original state.
Bridges with isolation bearings exhibit better seismic performance. Under rare earthquake conditions, the shear    Advances in Civil Engineering key of the bearings would be broken (as designed), and the upper and bottom bearing plates would slide. is mitigation effect sufficiently protects the substructure, including the piers and piles. Moreover, this structural system has selfrestoring abilities. After a rare earthquake, the bearings can readily be repaired. erefore, a PC simple beam with isolation devices is included in the comparison. e most common isolation devices include lead rubber bearings, high damping laminated rubber bearings, elastoplastic steel damping bearings, and double-curved spherical seismic isolation bearings, among others. e vertical loading capacity and durability are limited for the lead rubber bearings and high damping laminated rubber bearings. e design life of a rubber bearing is approximately 30 years. erefore, during the 100-year design life of the bridge, several bearing replacements are required. It is very costly and difficult to replace the numerous bridge bearings along the entire high-speed railway line, which is fully closed. However, the design life of a steel bearing can reach 100 years with normal maintenance and rehabilitation procedures. In the case of elastoplastic steel damping bearings, the affordable bending times of the damping components are limited, and permanent yielding deformation would occur after a rare earthquake. It is costly to replace the elastoplastic components, and therefore, they are not recommended. Double-curved spherical isolation bearings, which have a large loading capacity, good durability, and self-restoring capacity, are suitable for the seismic design of high-speed and general-speed railway bridges.
When using common double-curved spherical isolation bearings, the beam will rise slightly when moving because of the influence of the double sphere. is slight rise is tolerable for common highway bridges, while it is intolerable for highspeed railway bridges. erefore, specific double-curved spherical seismic isolation bearings were designed and developed for railway bridges. Considering the features of common double-curved spherical isolation bearings, a planar sliding plate was added to the bearings to prevent the rise during operation. e railway double-curved spherical seismic isolation bearings have been applied in several national projects in China, including the Sutong Yangtze River Bridge, Hongkong-Zhuhai-Macao Major Bridge, and bridges along the Fuzhou-Xiamen Railway.
us, the railway double-curved spherical seismic isolation bearings were adopted in this study, and the corresponding overall seismic computational model is shown in    6 Advances in Civil Engineering Figure 8. e beam and pier sizes and the materials adopted are as same as the scheme (i). e curved surface radius of the double-curved spherical seismic bearings is 2.3 m, and the friction coefficient under earthquake is 0.06. e vertical loading capacity of the bearings is 4500 kN. e longitudinal cross-section of railway double-curved spherical seismic isolation bearings is shown in Figure 9. e hysteresis curve of bearings is given in Figure 10: e post-yielding stiffness of the bearing can be obtained: e equivalent stiffness can be expressed as follows: e equivalent damping can be expressed as follows: Where W is the vertical force of the bearings under dead load; R is the curved surface radius of the bearing; D d is the design horizontal displacement of the bearings; μ d is the sliding frictional coefficient of the bearings. e two-stage seismic design was carried out using the railway's double-curved spherical seismic bearings according to China Railway Code [30].

Low-Level Earthquake.
Under low-level earthquake conditions, the isolation devices of the simple beam would not function. erefore, the mechanical performance of the bridges is the same with the simple beam as it was with common spherical bearings. e reinforcement ratio is also the same. e HRB400 reinforcement bar with a diameter of 32 m was used, and the reinforcement ratio was 1.63%.

High-Level Earthquake.
With the isolation devices, the performance level of the bridges can be enhanced. In general, after a rare earthquake, the bridges work elastically or sustain little damage. Table 6 presents the pier bottom internal forces of the middle pier (P3) after a rare earthquake.
According to Table 6, the mitigation rates for longitudinal and transverse earthquakes reach 78.9% and 83.8%, respectively. e pier bottom internal forces following the high-level earthquake are lower than the corresponding forces of the low-level earthquake when the isolation devices are operating. e reinforcement can be calculated based on the internal forces of the low-level earthquake, and therefore, the piers remain elastic after a rare earthquake.
Owing to the favorable seismic effect, the seismic response to the rare earthquake does not dictate the design, and capacity protection design is not needed. With the isolation devices, the pile length and reinforcement under low-level earthquake conditions are adopted directly. Table 7 provides the mechanical status of various components under different loading cases.
It is clear that the piers and piles of the bridges with the isolation bearings all remain elastic. Only the shear keys of the bearings are broken, and these are easily repaired. us, the bridges have a higher seismic performance.

Steel-Concrete Composite Beams with
Isolation Bearings e SC composite beams are lighter than concrete beams, and therefore, they exhibit smaller seismic responses. Compared with pure steel beams, SC beams save steel materials, emit less noise, and exhibit better fatigue performance. SC beams are effective for the construction of high-speed railway bridges, especially in conditions involving limited clearance or where they are used as adjustable span beams. e potential applicability of this type of beam in the high-intensity seismic region of the Jakarta-Bandung highspeed railway was studied. e weight of the superstructures can be reduced to a certain degree, and therefore, the seismic forces of the substructures can also be decreased. e calculated span of the SC composite bridge is 31.5 m, and the total length of the beam is 32.6 m. According to the train-bridge coupling vibration results, the height of the steel beam is 2.7 m, and the steel parts adopt a double-I-shaped   section. e thicknesses of the top and bottom steel plates are each 50 mm, and the thickness of the web plate is 24 mm, with a stiffening rib thickness of 20 mm. e concrete bridge deck is cast-in-situ. e overall seismic computational model is the same as scheme (ii) (PC simply-supported box beams using seismic isolation bearings), as shown in Figure 8.
Q370qE steel as defined in Chinese code for the design on steel structure of railway bridge [34] was used in the scheme. e mechanical properties of steel plates are shown in Table 8. e SC beam comprises a Q370qE steel beam and C50 concrete deck. e concrete of the piers, pile caps, and piles is all C40. e primary load-bearing steel rebar used in the piers is also HRB400. e cross-section of the SC composite beam is shown in Figure 11. e piers are double-column piers (height � 15 m), and the cross-section of the piers and foundation pile plan are shown in Figure 12.
Considering the inherent defects of common spherical steel bearings, the double curved spherical seismic isolation bearings were used in this scheme. Although the no-collapse performance after a rare earthquake can be reached through rational reinforcement, significant damage cannot be avoided for SC composite beams with common spherical steel bearings. According to the calculated results of scheme (ii) (P.C. simply-supported box beams using seismic isolation bearings), although the isolation devices are more expensive than common bearings, the total cost is lower because of the action of isolation devices. Two-stage seismic design can therefore be conducted according to China Railway Code [30].

Low-Level Earthquake.
Low-level earthquakes control the reinforcement ratio of the piers. e peak ground acceleration of a low-level earthquake is 0.14 g. Table 9 shows the pier bottom internal forces of the P3 pier under longitudinal and transverse earthquake conditions. e HRB 400 reinforcement bar with a diameter of 28 mm was used, and the reinforcement ratio was 0.98%, as shown in Figure 13. For the longitudinal earthquake, the largest stress of the concrete and steel rebar is 13.3 MPa and 297.8 MPa, respectively. For the transverse earthquake, the largest stress of the concrete and steel rebar is 9.0 MPa and 163.4 MPa, respectively.

High-Level Earthquake.
With the isolation devices, the seismic performance of the bridges increases. In general, after a rare earthquake, the bridges work elastically or sustain little damage. Table 10 presents the pier bottom internal forces of the middle pier (P3) after a rare earthquake. e mitigation rates for longitudinal and transverse earthquakes reach 88% and 87%, respectively. e pier bottom internal forces of the high-level earthquake are less than those of lowlevel earthquakes when the isolation devices are operating. e reinforcements are monitored according to the internal forces of a low-level earthquake, and therefore, the piers remain elastic after a rare earthquake.

Reinforced Concrete Rigid Frames
e RC rigid frame scheme is economical and has a simple structure, good mechanical performance, good integrity, and facile construction. As a result, this structural system is

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A finite element analysis model was built using the Midas Civil software program as shown in Figure 15. Space beam elements were used to model the piers and beams. e secondary dead loads were transferred to mass. Soil springs were modeled under the bottom of the piers to simulate the interactions between the foundation and the structures. e RC rigid frame comprises C40 concrete and an HRB400 steel rebar.

Low-Level Earthquake.
Low-level earthquakes control the reinforcement ratio of the piers. Taking P2 piers (see Figure 15) as an example, Table 11 presents the pier bottom internal forces under longitudinal and transverse low-level earthquakes. e HRB 400 rebar with a diameter of 28 mm was used, and the reinforcement ratio was 3.06%, as shown in Figure 16. For the longitudinal earthquake, the largest stress of the concrete and steel rebar are 11.8 MPa and 206.0 MPa, respectively. For the transverse earthquake, the largest stress of the concrete and steel rebar are 8.7 MPa and 166.1 MPa, respectively.

High-Level Earthquake.
e no-collapse performance under rare earthquake conditions should be satisfied. According to China Railway Code [30], when the outermost steel rebar begins to yield, the displacement at this moment is defined as the yielding displacement of the piers. Taking the P2 piers as an example, under a longitudinal earthquake, the displacement at the yielding moment is 8.56 cm, while the ultimate displacement is 12.42 cm. us, the calculated ductility ratio is 1.45, which is smaller than the allowable ratio of 4.8. Under a transverse earthquake, the displacement at the yielding moment is 7.42 cm, and the ultimate displacement is 11.68 cm. us, the calculated ductility ratio is 1.57, which is also smaller than the allowable ratio of 4.8. e no-collapse performance under rare earthquake conditions is therefore satisfied. For an RC rigid frame bridge under a high-intensity earthquake, the piers will yield at the pier bottom, and ductility hinges are formed to dissipate the seismic energy.

Technical and Economic Comparison
For the 32-m simply-supported box beam, a prefabricated erection method was adopted. e overall cost of the bridges considers the cost of the prefabricated yards and the temporary roads. For a simply-supported bridge, the erection cost of a simple beam is approximately 220k RMB. For the RC rigid frame bridge, full framing is used for the construction, and the cost for one unit of the frame is approximately 593k RMB.   Economic analysis was conducted for the four evaluated schemes, and the costs of the substructures and superstructures are shown in Table 12.
Overall, the cost of RC rigid frames is the lowest among the four evaluated schemes, whereas the cost of SC composite beams is the highest. e cost of PC simply-supported box beams with isolation bearings is 7.4% cheaper than scheme (i) (PC simple beams with common bearings), whereas the cost of SC composite beams is 3.3% more expensive than scheme (i) and the cost of RC rigid frames is 11.0% cheaper than scheme (i). In conclusion, RC rigid frames are advantageous in terms of costs. Table 13 presents a technical comparison of the four schemes considering parameters besides costs.     According to investigations in Indonesia, SC composite beams are rarely used, and the corresponding design, construction, and maintenance experiences are lacking. Since Indonesia is located in a tropical rainforest zone, there is abundant rain throughout the year, and the air humidity is ∼80%. e railway line traverses a sea climate, which makes maintenance and rehabilitation difficult and costly.
us, considering the lifetime costs, it is even more expensive. Moreover, the noise of SC composite beams is higher than that of concrete beams, which can increase the damping of the structure, thereby reducing the vibration and noise of the bridge. In contrast, concrete beams have advantages in terms of maintenance and rehabilitation, and have less noise pollution and better durability. erefore, concrete beams are generally preferred.
Considering the overall structural systems, for a simple beam, advanced isolation devices can be implemented in the seismic design because of the favorable separation between piers and beams, leading to a better seismic performance. e integrity of the RC rigid frame is better because of the rigid pier-beam connection. erefore, only a ductile design method can be applied (at the price of pier damage). From the perspective of the project timeline, PC beams are faster to build because of their construction method (i.e., prefabricated erection). In contrast, the RC rigid frames are constructed using a full framing method, and the construction period is the longest. e construction period for SC composite beams is between that of PC beams and RC rigid frames. Although the scheme of RC rigid frames has economic advantages, its overall applicability is relatively low. Under high-level earthquake conditions, piers would undergo significant damage, which would be difficult to repair. Earthquakes in Japan have caused massive disruption of RC rigid frame bridges, leading to significant economic losses for the north-eastern Shinkansen [8].
e present study indicates that PC simply-supported beams with double-curved spherical seismic isolation bearings are optimal for the entire railway line. e other schemes can also be applied to some specific bridges.

Conclusions
e optimum selection of a rational earthquake resisting scheme is crucial for high-speed railway lines. Based on the comparison of four bridge earthquake resisting schemes relevant for the Jakarta-Bandung high-speed railway considering technical and economic aspects, the following conclusions can be drawn.
(1) PC simply-supported beams are generally constructed using a prefabricated method, and the construction quality can be guaranteed. e construction form and devices can be used repeatedly, and the beams are suitable for large-scale manufacturing. ese simple beams have static determinate structures and are suitable for various types of soils.
(2) PC simply-supported beams are connected to the piers through bearings, and therefore, advanced isolation bearings or other energy dissipation devices can be applied. e seismic performance of the bridge is thus improved, and the total cost of the project can be minimized. Under high-level earthquake conditions, the shear key can easily be replaced after broken. Although the isolation bearings are more expensive than common spherical steel bearings, the cost of the substructure can be reduced to a larger extent. e total cost is, therefore, smaller for beams with isolation bearings.
(3) e SC composite beam is the most expensive, especially when considering the subsequent costs associated with maintenance and rehabilitation. Moreover, SC composite beams exhibit less rigidity and require longer construction processes than concrete beams. e noise from SC composite beams is also relatively larger than from concrete beams. (4) In RC rigid frame bridges, the piers and beams are rigidly connected, and the advanced isolation devices cannot be integrated into this system. erefore, only a ductile design method can be used (at the price of bridge pier damage). Moreover, RC rigid frame bridges, which are indeterminate structures, are not applied to soft site regions. e cast-in-situ construction method requires a longer period of time and more manpower, and the RC rigid frame bridges show only limited economic advantages.
In conclusion, considering their high seismic performance, convenient construction, and beam type integrity, the PC simply-supported beams with isolation bearings are recommended for use throughout the entire railway line of the Jakarta-Bandung high-speed railway. Considering the Data Availability e data presented in this study are available on request from the corresponding author.

Conflicts of Interest
e authors declare no conflicts of interest.