TIDAL ANALYSIS AT KUALA LANGSA AND PUSONG ISLAND USING ADMIRALTY METHOD

Similar documents
OCN 201 Tides. Tsunamis, Tides and other long waves

Theory and Application Introductory Oceanography Ray Rector: Instructor

TIDES. Theory and Application

Equilibrium Model of Tides

Tides. Tides: longest waves. or seas. or ripples

SOME WATER CHARACTERISTICS OF ESTUARIES IN INDONESIA

Announcements. Project 2 due Nov 7 th Topics for today: Big waves. Tsunamis, seiches and tidal waves. Tsunamis and seiches

Chapter 11 Tides. A tidal bore is formed when a tide arrives to an enclosed river mouth. This is a forced wave that breaks.

SURFACE CURRENTS AND TIDES

Tidal regime along Vietnam coast under impacts of sea level rise

13. TIDES Tidal waters

Ocean Waves. Capillary. Gravity. Wind generated. Tides Tsunamis Seiches

MAR 110 LECTURE #16 Tides

Questions # 4 7 refer to Figure # 2 (page 321, Fig )

Lab 5: Ocean Waves and Tides

Overview and preview. I. Tides as Waves (really really big) What are the Forces driving these waves? II: Into make-believe.

Chapter 12: Coasts (after a brief review of Tides)

MAR 555 Lecture 20: Coastal Tides

Appendix 5: Currents in Minas Basin. (Oceans Ltd. 2009)

EFFECTS OF WAVE, TIDAL CURRENT AND OCEAN CURRENT COEXISTENCE ON THE WAVE AND CURRENT PREDICTIONS IN THE TSUGARU STRAIT

Tidal analysis and prediction of the flow characteristics around Abu Dhabi Island

The ocean water is dynamic. Its physical

Identifying the Impact of Tidal Level Variation on River Basin Flooding

LONG WAVES OVER THE GREAT BARRIER REEF. Eric Wolanski ABSTRACT

Modeling changes to the historic Lower Columbia River Estuary using Delft3D. Drew Mahedy Lumas Helaire Stefan Talke David Jay May 30, 2014

Simulation of current using a two-dimensional numerical model in the Aceh Barat Daya waters, Indonesia

PROPAGATION OF LONG-PERIOD WAVES INTO AN ESTUARY THROUGH A NARROW INLET

Applications of ELCIRC at LNEC

Tides. 1. The dynamic theory of tides. The equilibrium theory is of limited practical value, even though certain of its predictions are correct:

What causes the tides in the ocean?

MAR 110 LECTURE #22 Standing Waves and Tides

Earth s oceans covers 71 % _ of the planet s surface. In reality, Earth s ocean waters are all. interconnected as part of a single large global ocean.

Clockwise Phase Propagation of Semi-Diurnal Tides in the Gulf of Thailand

2. Water levels and wave conditions. 2.1 Introduction

Oceanography 10. Tides Study Guide (7A)

Factors affecting Rocky Intertidal Zonation Patterns

Consequences of the Earth's Rotation

Synoptic Lab, MET 421, Test 2

Chapter. The Dynamic Ocean

The movement of ocean water is a powerful thing. Waves created

Chapter 10 Lecture Outline. The Restless Oceans

What causes the tides in the ocean?

The events associated with the Great Tsunami of 26 December 2004 Sea Level Variation and Impact on Coastal Region of India

Unit 4 Lesson 3 Earth s Tides. Copyright Houghton Mifflin Harcourt Publishing Company

Duckies have been found in Hawaii, Alaska, S. America, Scotland, Washington state and Australia as of 2012.

Geostrophic and Tidal Currents in the South China Sea, Area III: West Philippines

David Wolcott Lijuan Huang Stephen Gill. Center for Operational Oceanographic Products and Services National Ocean Service/ NOAA Silver Spring, MD

Shorelines Earth - Chapter 20 Stan Hatfield Southwestern Illinois College

yarn (1-2 meters) tape sticky notes slinky short piece of yarn or ribbon calculator stopwatch

GEOGRAPHY - STD 8 [ ] Q1.

Tidally influenced environments. By Alex Tkaczyk, Henrique Menezes, and Isaac Foli

page - Laboratory Exercise #5 Shoreline Processes

Earth Science. Mark Lilly. 8th Period. Snow Packet 5

STUDY ON TSUNAMI PROPAGATION INTO RIVERS

Prof. B.S. Thandaveswara. The periodic rise and fall of the planetary ocean level in response to the gravitational

The Oregon Coast Education Program. Concepts to Teach: Tidal cycles, interconnectedness and balance

Waves waves Waves are defined by the following: Wave height H Wavelength L Period T Velocity V Breaking Waves

ROCKY SHORE HABITAT (LESSON 14)

Nortek Technical Note No.: TN-021. Chesapeake Bay AWAC Evaluation

Oceans in Motion: Waves and Tides

Make a Marigram. Overview: Targeted Alaska Grade Level Expectations: Objectives: Materials: Whole Picture: Grades 9-12

Investigation of wave processes on the eastern shelf of Sakhalin Island influenсed by tidal currents (Sea of Okhotsk)

ISOLATION OF NON-HYDROSTATIC REGIONS WITHIN A BASIN

Seasonal Variation of Stratification in the Gulf of Thailand

OECS Regional Engineering Workshop September 29 October 3, 2014

WAVE AND CURRENT HYDRODINAMICS STUDY AT BATANG AIR DINGIN RIVER MOUTHPADANG, INDONESIA

AIS data analysis for vessel behavior during strong currents and during encounters in the Botlek area in the Port of Rotterdam

Currents measurements in the coast of Montevideo, Uruguay

Waters rise and fall in tides.

Chapter - Oceans and Coasts

General Circulation in the Malacca Strait and Andaman Sea: A Numerical Model Study

Simulation of hydraulic regime and sediment transport in the Mekong delta coast

Characterizing The Surf Zone With Ambient Noise Measurements

The Hudson s Ups and Downs

Community collection of ocean current data: An example from Northern Aceh Province, Indonesia

consulting engineers and scientists

Modern and Ancient Tides

Scour Analysis at Seawall in Salurang, Sangihe Islands Regency, North Sulawesi

Analysis of daily wind circulation toward sea level rise in Semarang

PROPERTIES OF NEARSHORE CURRENTS

GEOPHYSICAL RESEARCH LETTERS

The impact of ocean bottom morphology on the modelling of long gravity waves from tides and tsunami to climate

Figure 1 Location of the ANDRILL SMS 2006 mooring site labeled ADCP1 above.

Impact of the tides, wind and shelf circulation on the Gironde river plume dynamics

SCIENCE OF TSUNAMI HAZARDS

Chapter 11 Waves. Waves transport energy without transporting matter. The intensity is the average power per unit area. It is measured in W/m 2.

Lecture Outlines PowerPoint. Chapter 15 Earth Science, 12e Tarbuck/Lutgens

MESSOLOGI LAGOON AREA (GREECE)

What are Waves? Earthquake. Waving flags. Vocal Cords Vibrate

Ocean Currents Unit (4 pts)

3/9/2013. Build house on cliff for a view of the ocean - be one with said view Pearson Education, Inc. Shorelines: summary in haiku form

International Journal of Innovative Research in Advanced Engineering (IJIRAE) ISSN:

A CYCLONIC EDDY NORTH OF LOMBOK *)

ESTIMATION OF EXTREME WATER LEVELS AT NSW COASTAL ENTRANCES

STRIDE PROJECT Steel Risers in Deepwater Environments Achievements

THE OCEAN IS ALWAYS IN MOTION. WHY IS THIS IMPORTANT? First we need to know what kinds of movement there are in the ocean. Three Kinds of Water

The Movement of Ocean Water. Currents

Directed Reading. Section: Ocean Currents. a(n). FACTORS THAT AFFECT SURFACE CURRENTS

Introduction Ocean Sciences Fourth Edition, Second digital edition ver 4.01

GNSS Technology for the Determination of Real-Time Tidal Information

Transcription:

TIDAL ANALYSIS AT KUALA LANGSA AND PUSONG ISLAND USING ADMIRALTY METHOD ANNISA SRI SUGIARTI 1 *, MARWAN 2, ICHSAN SETIAWAN 3 1 Graduate Program of Disaster Science,Syiah Kuala University, Darussalam, *Email: annisasrisugiarti@gmail.com 2 Faculty of Mathematics and Natural Science, Physical Department, Syiah Kuala University, Darussalam, 3 Faculty of Marine Science and Fisheries, Syiah Kuala University, Darussalam, A research about tidal analysis at Kuala Langsa and Pusong Island with different physical condition had been done, where Kuala Langsa is an estuary and Pusong Island is a coastal area in Kota Langsa District, Aceh Province. The purpose of this research is to determine tidal type on both locations. This research used secondary data which is obtained from Kuala Langsa Pusong Island Hydro Oceanographic Survey and primary data which is taken about 29 hours at both locations. Admiralty method had been using to analyze the tides and from this method can be obtain amplitude and phase lag based on Formhazl number. The result of this research according to Formhazl number for Kuala Langsa and Pusong Island are 0.12 and 0.23 respectively. Both values of Formhazl number of the locations are smaller than 0.25, it concluded that both locations had showed same tidal type, i.e. semidiurnal. The phase lag for tidal types in Kuala Langsa for M 2 is 359 0 while for Pusong Island is 330 0. While for the amplitude of both locations for M 2 is 56 cm for Kuala Langsa and 48 cm for Pusong Island. It is shown that the amplitudes at Kuala Langsa are a little bit higher than that of Pusong Island. The difference is suspect due to the different physical condition of the observation areas. Keywords: tidal, Admiralty method, Formhazl number, semidiurnal Introduction The body of sea water at the shoreline, the place at which land and sea water meet, are never still at one elevation only, but always fluctuate up and down due to the tidal cycle. Sea water surface is rising gradually until reach the maximum which so called high water level and then lowering down gradually to the minimum at lower water level. Most of the earth surfaces are covered by water or about 361.3 million sqkm (Mays,2001:4), that sea water always moves every time. This movement is generated by wind, sea waves, tides and currents. Indonesia is one of archipelago country that relatively wide which consists of 13,466 islands and has 99,093 km shoreline length. Because of its very wide sea water surface in Indonesia, the tidal phenomena are very well known to the people. The knowledge of sea water tide is used in sea-transportation, port activities, and the coastal area development. So, the knowledge of tidal is very importance to be studied by whom that prefer to work in river and coastal problems. The sea water tidal is the results of gravityattractive forces and centrifugal effects. The centrifugal effect is the forces outer direction from the rotation centre, so that the gravity forces vary proportionally to the earth mass but inverse proportion to the distance (Triatmodjo,2012:85).For the sea water tides, the peak of its wave is called high tide and the valley of the waves is called low tide. The difference of vertical range of the high and lowtide is called the tidal range. There are several types of tides, i.e., diurnal tide, semi diurnal tide, and some other more. The type of tide at one area, can be known by measuring the elevation of sea water surface fluctuation at the observe area every day. Whenever the measuring place has one high tide and one neap tide every day in about 24 hours, the area has diurnal tide type. On the other hands, whenever the object area has its high tide and neap tide twice in a day, the area has a semi diurnal type of tide. Another type of tide is the mixed tides which is the transition between diurnal and semi diurnal tides (Wyrtki, 1961:155).So, the research was conducted to see the comparison 97

between the tides at Kuala Langsa which area is the river estuary and Pusong Island which is the coastal area using one method of tidal prediction which is called admiralty method. Methods of Analysis Tidal analysis which occurs at Kuala Langsa and Pusong Island was conducted using secondary tidal data available from Hydro - Oceanographic Survey recorded for 15 days and a primary tidal data was collected for 29hours by recording directly at the sites using staff gauges. The distance between the two locations is about 5.6 km which Kuala Langsa is located at 4.52 0 N 98.17 0 E and Pusong Island at 4.53 0 N 98.06 0 E at Kota Langsa District, Aceh Province(PLN-FT Unsyiah, 2013). The tidal data was analyzed using admiralty methods which flowchart diagram is shown in Fig.1. The method is a method of tidal calculation which conducted to get the mean sea level obtained from tidal constant calculations (Ongkosongo and Suyarso, 1989:40). From harmonic analysis, two harmonic constants, i.e., amplitude and phase difference are calculated using admiralty method at each corrected tidal constants and corrected mean sea level. The results will be diurnal tide constants, i.e., K 1, O 1, P 1, semi diurnal tide constants M 2, S 2, N 2, K 2, and shallow water tidal constantsm 4, MS 4. Whenever the tidal constants were obtained, the type of tide is defined using Formhazl number as (Wyrtki, 1961:159): (1) where: F = Formhazl number; O 1 = harmonic constant of moon declination; K 1 = harmonic constant of moon and sun declination; M 2 = harmonic constant of moon; and S 2 = harmonic constant of sun. 98

Figure 1. Flowchart of Admiralty Method The result obtained based on Formhazl number calculations is used to classify the type of tide at the observed locations, with the conditions as the following: : semidiurnal type of tide : mixed tide prevailing semidiurnal : mixed tide prevailing diurnal : diurnal type of tide Analysis Results Tidal Constants at Kuala Langsa and Pusong Island The results of tidal constants, amplitude and phase lag, based on admiralty methods for Kuala Langsa and Pusong island are shown in Table 1 and Table 2. Table 1.Tidal constants at Kuala Langsa S 0 M 2 S 2 N 2 K 2 K 1 O 1 P 1 M 4 A (cm) 291 56 43 45 1 5 7 11 20 g ( ) 0 359 28 181 200 200 143 28 45 Table 2. Tidal constants at Pusong Island S 0 M 2 S 2 N 2 K 2 K 1 O 1 P 1 M 4 A (cm) 147 48 40 14 11 8 13 21 2 g ( ) 0 330 27 21 175 81 175 57 27 99

From Table 1, it is obtained that the M 2 constant at Kuala Langsa is dominating compare to other constants which the M 2 amplitude value is 56 cm and its phase lag is 359 0. While Table 2 shown the dominating tidal constants also for the M 2 amplitude and phase lag which values are 48 cm and 330 0 respectively. This happened due to at the two locations are very influence by the moon s attractive force rather than that of the sun. Tidal Type The Formhazl numbers which calculated using Eq. (1) have the F values of 0.12 for Kuala Langsa and 0.23 for Pusong Island. So, the tide classification based on the value of F for the two locations has a semi diurnal tidal type which the F value obtained is less than 0.25. Tidal Graph Beside the tidal constants calculations for the two observed locations, the comparison of tidal graphs between secondary data collected and the measured primary data also had been conducted. Fig. 2 shown the tidal graph at Pusong Island with the primary data assimilation, while Fig. 3 shown the tidal graph at Kuala Langsa. Figure 2. Tidal graph at Pusong Island with the primary data assimilation Figure 3. Tidal graph at Kuala Langsa with the primary data assimilation 100

Fig. 2 and Fig. 3 shown the comparison between the tidal graphs obtained from the secondary data and the primary data. The two set of graphs have the similar pattern of the tidal graph which in one day there are two high tides and two low tides. So, either at Kuala Langsa or at Pusong Island, both of them has semi diurnal tide characteristics. Discussion Tidal harmonic constants which are the amplitude and phase lag are obtained based on Admiralty method. The dominating tidal harmonic constant at the two observed locations at Kuala Langsa and Pusong Island is M 2 or principal lunar, i.e. a tidal harmonic constant which has period of 12.42 hour or 12 hour and 25 minutes. While the tidal type is defined by using the Formhazl number. The number using diurnal tide and semi diurnal tide constants. The values of Formhazl number at the two observed locations are 0.12 at Kuala Langsa and 0.23 at Pusong Island which are less than 0.25 which is semi diurnal tide. So, either using tidal harmonic constants or using tidal types with Formhazl number, the type of tide is semi diurnal at Kuala Langsa as river estuary and also at Pusong Island which is a coastal area. A bit differences in amplitude and phase lag values of the two locations for M 2, i.e., 56 cm and 359 0 at Kuala Langsa, and 48 cm and 330 0 at Pusong Island is shown in Table 1 and Table 2. The other phase lags for tidal types in Kuala Langsa for S 2, O 1 and K 1 are 28, 143 and 200 respectively while for Pusong Island are 27, 81, 175. While for the amplitudes of both locations for S 2, O 1 and K 1 are 43 cm, 7 cm and 5 cm for Kuala Langsa and 40cm, 13cm and 8cm for Pusong Island which are also shown in Table 1 and Table 2. Generally it is also shown that the amplitudes at Kuala Langsa are a little bit higher than that of Pusong Island. The difference is suspect due to the different physical condition of the observation areas. Conclusion Remark Water domain at Kuala Langsa is as an estuary and its surrounding of wetlands, mangrove forests, and river water flow downstream. The situation tend to make a little bit longer time for tide at Kuala Langsa to reach its peak compare to the tidal fluctuation at Pusong Island. The approximation results between assimilation harmonic constant data that obtained from admiralty method calculations, shows nearer values of the constants at the two locations. Acknowledgment Special thanks going to Kuala Langsa Pusong Island Hydro Oceanographic Survey Engineering Faculty of Syiah Kuala University for the data that this research can be conducted. References 1. PLN-FT Unsyiah, Final Report in Kuala Langsa-Pusong Island Hydro- Oceanographic Survey (Engineering Faculty of Syiah Kuala University, 2013) 2. Mays, L.W., Water Resources Engineering, (John Wiley & Sons Inc, New York, 2001) 3. Ongkosongo, O.S.R. and Suyarso, Tides in Asean- Australia Cooperative Programs on Marine Science Project 1: Tide and Tidal Phenomena (LIPI, Jakarta,1989, in Indonesian) 4. Triatmodjo, B., Coastal Structure Design(Beta Offset, Yogyakarta, 2012, in Indonesian) 5. Wyrtki, K., Naga Report, Volume 2 in Physical Oceanography of the Southeast Asian Waters(The University of California, La Jolla, California, 1961) 101

2024 © sportdocbox.com Privacy Policy | Terms of Service | Feedback