<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">IJG</journal-id><journal-title-group><journal-title>International Journal of Geosciences</journal-title></journal-title-group><issn pub-type="epub">2156-8359</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/ijg.2013.44067</article-id><article-id pub-id-type="publisher-id">IJG-33370</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Earth&amp;Environmental Sciences</subject></subj-group></article-categories><title-group><article-title>
 
 
  Hyperbolic Velocity Model
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>gor</surname><given-names>Ravve</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Zvi</surname><given-names>Koren</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib></contrib-group><aff id="aff1"><addr-line>Paradigm Geophysical, Herzliya, Israel</addr-line></aff><author-notes><corresp id="cor1">* E-mail:<email>igor.ravve@pdgm.com(GR)</email>;<email>zvi.koren@pgdm.com(ZK)</email>;</corresp></author-notes><pub-date pub-type="epub"><day>20</day><month>06</month><year>2013</year></pub-date><volume>04</volume><issue>04</issue><fpage>724</fpage><lpage>745</lpage><history><date date-type="received"><day>March</day>	<month>27,</month>	<year>2013</year></date><date date-type="rev-recd"><day>April</day>	<month>29,</month>	<year>2013</year>	</date><date date-type="accepted"><day>May</day>	<month>26,</month>	<year>2013</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p>
 
 
   Asymptotically bounded velocity profiles describe the vertical velocity variations in compacted sediments in a more realistic way than unbounded velocity models, and allow presenting the subsurface by a smaller number of thicker layers. The first and the simplest asymptotically bounded model is the Hyperbolic velocity profile proposed by Muscatin 1937, and our paper is an extension of this early study. The Hyperbolic model has an advantage over other bounded models: The velocity increases with depth and approaches the limiting value with a more smooth and gradual rate. We derive the time-depth relationships, forward and backward transforms between the instantaneous velocity profile and the effective models (average, RMS and fourth order average velocities), study the trajectories for pre-critical and post-critical curved rays and derive the equations for traveltime, lateral propagation and arc length. We compare the ray paths obtained with the Hyperbolic model and with the other bounded velocity profiles.  
 
</p></abstract><kwd-group><kwd>Velocity Models; Velocity Transforms; Sediments</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>The Hyperbolic velocity model was first proposed by Muscat [<xref ref-type="bibr" rid="scirp.33370-ref1">1</xref>] and published in 1937. However, since then the model was not extensively studied and is unjustifiably ignored in the literature. The objective of this research is to extend the original study and to correct the inaccuracies. We show the place of the Hyperbolic model among the other asymptotically bounded models, analyze its basic relationships and attempt to develop a complete theory.</p><p>Asymptotically bounded velocity models describe the velocity profile in compacted sediments, where the velocity gradually increases with depth and eventually approaches a limiting value. These models make it possible to describe a vertical velocity profile with a smaller number of intervals as compared to the classical unbounded models, such as linear velocity vs. depth [2,3], unbounded exponent [<xref ref-type="bibr" rid="scirp.33370-ref4">4</xref>], linear slowness [<xref ref-type="bibr" rid="scirp.33370-ref5">5</xref>], “sloth” (linear variation of slowness squared), e.g., [<xref ref-type="bibr" rid="scirp.33370-ref6">6</xref>], parabolic model [7,8], Faust velocity model [9,10] with a reference depth and different root indices. The unbounded models are described by two parameters: the instantaneous velocity at the top interface <img src="7-2800488\5f0addc0-db48-4426-94f7-d65ac7b7f795.jpg" /> and the vertical velocity gradient <img src="7-2800488\ab3b9833-3b13-4ffe-9bd8-5ec32de41ba4.jpg" /> at the same level. The Faust model includes also the root index n, normally<img src="7-2800488\3ce9021b-f239-4e84-b3da-02f03b352f4e.jpg" />. Asymptotically bounded models require an additional parameter: the limiting value of velocity <img src="7-2800488\d7a938c5-0c97-432b-99f5-82ead92146c1.jpg" /> at infinite depth. Two models of this family were studied by Ravve and Koren: the Exponential asymptotically bounded model [11,12] and the Conic model [<xref ref-type="bibr" rid="scirp.33370-ref13">13</xref>]. The asymptotically bounded profiles can be used, in particular, as velocity trend functions for the constrained velocity inversion with the best (e.g., least-squares) fit of the input data [<xref ref-type="bibr" rid="scirp.33370-ref14">14</xref>]. Examples of asymptotically bounded models are presented below. For each model, we first give the original formulation of the velocity profile as it appears in the original works by the authors, and then we convert it to a canonical form in terms of the “standard” parameters <img src="7-2800488\5cb38ac5-9d68-4a39-a0c6-64b4660b6e95.jpg" /> and<img src="7-2800488\53b8e2b5-6278-4646-9cea-5970afd75606.jpg" />. Parameter <img src="7-2800488\4ae13b8d-f6a3-4858-aa9a-ba97b5b0ce98.jpg" /> means the instantaneous velocity range,<img src="7-2800488\5b2c155f-c9f1-4fd7-a733-ea0bfa59eecf.jpg" />.</p><p>• The Hyperbolic velocity model by Muscat [<xref ref-type="bibr" rid="scirp.33370-ref1">1</xref>],</p><disp-formula id="scirp.33370-formula133191"><label>(1)</label><graphic position="anchor" xlink:href="7-2800488\570fda85-c3b3-48c7-997d-fdc47a63756e.jpg"  xlink:type="simple"/></disp-formula><p>In our notation, the Hyperbolic profile reads</p><disp-formula id="scirp.33370-formula133192"><label>(2)</label><graphic position="anchor" xlink:href="7-2800488\e722771f-3eb8-498c-b665-475882eb5846.jpg"  xlink:type="simple"/></disp-formula><p>• The Exponential velocity model by Muscat [<xref ref-type="bibr" rid="scirp.33370-ref1">1</xref>],</p><disp-formula id="scirp.33370-formula133193"><label>(3)</label><graphic position="anchor" xlink:href="7-2800488\115cfba7-f39b-400e-9928-fabbaccd5517.jpg"  xlink:type="simple"/></disp-formula><p>We convert it to our notation,</p><disp-formula id="scirp.33370-formula133194"><label>(4)</label><graphic position="anchor" xlink:href="7-2800488\febc5baf-a755-4258-975e-b4b3d4db0892.jpg"  xlink:type="simple"/></disp-formula><p>where the parameters are</p><disp-formula id="scirp.33370-formula133195"><label>(5)</label><graphic position="anchor" xlink:href="7-2800488\94c94c62-f731-4e44-8e57-0343a1743aaa.jpg"  xlink:type="simple"/></disp-formula><p>• The Exponential slowness model [5,15],</p><disp-formula id="scirp.33370-formula133196"><label>(6)</label><graphic position="anchor" xlink:href="7-2800488\cee56e34-06cc-45cc-a574-8fee19a69e52.jpg"  xlink:type="simple"/></disp-formula><p>It can be converted to canonic form,</p><disp-formula id="scirp.33370-formula133197"><label>(7)</label><graphic position="anchor" xlink:href="7-2800488\60f2ab5e-dff5-45ec-8d6c-eaa4d4907fe5.jpg"  xlink:type="simple"/></disp-formula><p>• The Exponential asymptotically bounded (EAB) velocity model [11,12],</p><disp-formula id="scirp.33370-formula133198"><label>(8)</label><graphic position="anchor" xlink:href="7-2800488\6a610a40-88e7-4f44-85bc-b34e02858aff.jpg"  xlink:type="simple"/></disp-formula><p>• The Conic velocity model [<xref ref-type="bibr" rid="scirp.33370-ref13">13</xref>],</p><disp-formula id="scirp.33370-formula133199"><label>(9)</label><graphic position="anchor" xlink:href="7-2800488\1e135a14-492c-49b7-a9c5-b3158b0ed47a.jpg"  xlink:type="simple"/></disp-formula><p>where</p><disp-formula id="scirp.33370-formula133200"><label>(10)</label><graphic position="anchor" xlink:href="7-2800488\3fa955c3-38a3-44e5-87f1-c47847c97783.jpg"  xlink:type="simple"/></disp-formula><p>A detailed review on unbounded and bounded velocity models is given by Kaufman [<xref ref-type="bibr" rid="scirp.33370-ref16">16</xref>]. <xref ref-type="fig" rid="fig1">Figure 1</xref> shows graphs of the instantaneous velocity vs. depth for the five asymptotically bounded velocity models mentioned above.</p><p>For all models, we assume the same velocity profile parameters:<img src="7-2800488\a7cdc6fb-9ff9-48da-bbb9-20f643f47931.jpg" />. The vertical gradients of the velocity vs. depth are plotted in <xref ref-type="fig" rid="fig2">Figure 2</xref>. It is interesting to note that among the five models presented, the Muscat Hyperbolic model (Equation (1) and grey line on the plot) approaches the limiting value <img src="7-2800488\5934fa4f-f58b-4712-a5d1-01fb4e63a007.jpg" /> in the slowest and the most gradual manner. The “second slow” is the Conic velocity model (red line), and the “third slow” is the EAB model (blue line). An asymptotically bounded model can be characterized by its gradient-velocity relationship, which is actually the governing differential equation of the velocity model.</p><p>This paper is structured as follows. We define the Hyperbolic model using 1) the original Muscat [<xref ref-type="bibr" rid="scirp.33370-ref1">1</xref>] formulation—depth vs. velocity, 2) the physical parameters: maximum gradient R, length scale <img src="7-2800488\64e187c8-6ca3-4827-8798-ce3668e887f3.jpg" /> and vertical shift h, and 3) the “technical” or geophysical parameters: top interface velocity<img src="7-2800488\e0e416d8-c019-42d6-a601-024411462d9e.jpg" />, top gradient <img src="7-2800488\878b13ef-3e6c-4458-8ad8-f5ab3a757013.jpg" /> and asymptotic velocity<img src="7-2800488\ce94ec74-72e4-4266-ace9-4858b5aa8604.jpg" />. We introduce the dimensionless asymptotic factor <img src="7-2800488\f80d0059-ac4b-4dd9-982e-2885eaf1d9cb.jpg" /> that simplifies the transform equations. First</p><p>we derive the time-depth and the depth-time relationships. Next we proceed to forward transforms from the instantaneous velocities to the effective models, such as the average, the RMS and the fourth order average velocity. Then we study the inversion problems, considering the inversion with the instantaneous velocities and gradients, and the inversion with the effective models, i.e., the average or the RMS velocities given vs. time or depth. Next we comment on the two types of curved rays existing in all asymptotically bounded models, depending on the initial take-off angle, and derive the trajectories of the ray paths for the Muscat velocity profile. For both types of the curved rays we derive the lateral propagation, the traveltime and the arc length.</p></sec><sec id="s2"><title>2. The Hyperbolic Velocity Profile</title><p>Muscat [<xref ref-type="bibr" rid="scirp.33370-ref1">1</xref>] defined the Hyperbolic model by</p><disp-formula id="scirp.33370-formula133201"><label>(11)</label><graphic position="anchor" xlink:href="7-2800488\8b231553-382a-4de2-bcb6-61c95353af0c.jpg"  xlink:type="simple"/></disp-formula><p>where V is the instantaneous velocity, z is depth measured from the top interface, <img src="7-2800488\c49906f0-bb7e-4369-86a8-475f10e7f8dc.jpg" />is the top interface velocity, A is the characteristic distance (scale) that affects the top gradient<img src="7-2800488\d39eedd4-5a87-4342-96c2-a0ab5d8fca73.jpg" />, and <img src="7-2800488\c6af03c2-e21f-4e24-97a6-30e0f10d9049.jpg" /> is the asymptotic velocity. Inverting Equation (1), we obtain</p><disp-formula id="scirp.33370-formula133202"><label>(12)</label><graphic position="anchor" xlink:href="7-2800488\6e006a7e-0c3e-48a3-b0a6-7be792437b49.jpg"  xlink:type="simple"/></disp-formula><p>The velocity gradient becomes</p><disp-formula id="scirp.33370-formula133203"><label>(13)</label><graphic position="anchor" xlink:href="7-2800488\484ffa59-e020-4ecc-ac96-66f218694d27.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\c5c1ca50-97d3-45e2-b21e-b028bbe24e7f.jpg" /> At<img src="7-2800488\76c523d2-10d9-43f7-8c30-7611ec4b4ef2.jpg" />, the top gradient is<img src="7-2800488\55d4d0a7-02b6-4b24-bc95-43f07a773e15.jpg" />. Therefore,</p><p><img src="7-2800488\a3b32975-1dca-4c09-9386-84c0bfebdd93.jpg" />and <img src="7-2800488\21049682-b689-41c3-9bfe-0b4e154eb673.jpg" />&#160;&#160; &#160;&#160;&#160;&#160;&#160;(14)</p><p>Introduce Equation (14) into Equation (13). In our notation, the Hyperbolic profile reads</p><disp-formula id="scirp.33370-formula133204"><label>(15)</label><graphic position="anchor" xlink:href="7-2800488\afadd618-6175-46ab-ba6a-fa222a911dec.jpg"  xlink:type="simple"/></disp-formula><p>We call values <img src="7-2800488\8f5592d5-a57c-41d7-b4b7-16ccfcb057df.jpg" /> and <img src="7-2800488\18535d15-3375-4a02-984a-c7b61e866e16.jpg" /> the technical parameters of the profile. At a definite height above the earth surface (above the upper interface), where<img src="7-2800488\8420bfdb-d872-46ac-a49c-353a0b8e3aff.jpg" />, the instantaneous velocity vanishes. According to Equation (15),</p><disp-formula id="scirp.33370-formula133205"><label>(16)</label><graphic position="anchor" xlink:href="7-2800488\90719a8e-a4dd-47c1-848d-20865dbcc62a.jpg"  xlink:type="simple"/></disp-formula><p>Introduce the absolute frame<img src="7-2800488\be8b631d-7464-4bcc-9eb4-598a85a6dd58.jpg" />, where the instantaneous velocity vanishes at the origin<img src="7-2800488\1e457f7b-9cd9-46dd-bf76-a7f929908c06.jpg" />. Parameter <img src="7-2800488\10164dfd-7bd8-48df-b6b9-04ede3595351.jpg" /> is the shift between the two frames of reference. In the absolute frame, the velocity profile simplifies to</p><disp-formula id="scirp.33370-formula133206"><label>(17)</label><graphic position="anchor" xlink:href="7-2800488\6ae98954-98b4-4868-a4f8-f9da8e116a88.jpg"  xlink:type="simple"/></disp-formula><p>where</p><disp-formula id="scirp.33370-formula133207"><label>(18)</label><graphic position="anchor" xlink:href="7-2800488\6000cb29-5cfe-4171-b6a9-c67bade7e080.jpg"  xlink:type="simple"/></disp-formula><p>We call values <img src="7-2800488\d33e01d2-189c-4f20-bd22-68b6271b0c35.jpg" /> and <img src="7-2800488\e3816ba7-3032-45f9-a2ca-2391f8253d7f.jpg" /> the physical parameters of the profile. Note that the linear velocity profile, where the ray trajectories are circular arcs, is a particular case of the Hyperbolic model with <img src="7-2800488\18595bc8-c9b6-46b6-8130-82a98ef0ab57.jpg" /> and<img src="7-2800488\e0a08953-8d9e-4303-a348-745dd340edf3.jpg" />, in such way that their product <img src="7-2800488\15953bad-75e0-4336-8bae-f439fddd3184.jpg" /> remains a finite value, and parameter <img src="7-2800488\c3c1d386-11bc-48d4-b355-eb63d036a2a7.jpg" /> becomes the constant velocity gradient of the linear model. The velocity gradient of the Hyperbolic model reads</p><disp-formula id="scirp.33370-formula133208"><label>(19)</label><graphic position="anchor" xlink:href="7-2800488\2086eefa-096f-47be-8e01-dd4b53df0c6d.jpg"  xlink:type="simple"/></disp-formula><p>At the absolute origin<img src="7-2800488\574327ff-88c5-44b4-a91a-b721b1ee5200.jpg" />, the velocity gradient reaches its maximum value<img src="7-2800488\a99b90ad-a55c-4495-b411-6ee48d7e81c6.jpg" />. Comparing Equations (17) and (19), we conclude that</p><disp-formula id="scirp.33370-formula133209"><label>(20)</label><graphic position="anchor" xlink:href="7-2800488\fe0e3dd9-6794-40e2-bf86-ccdc21c1f823.jpg"  xlink:type="simple"/></disp-formula><p>Equation (20) is the governing differential equation of the Hyperbolic velocity profile. It can be used to plot the gradient-velocity diagram. Such diagrams for several asymptotically bounded velocity models are studied in Appendix A.</p><p>Introduce the normalized (dimensionless) velocity<img src="7-2800488\ec2d910b-9f35-4828-8119-f94f0d523f9b.jpg" />, the normalized gradient <img src="7-2800488\4fc9e7d0-4118-44e8-88c0-1a7f1351a42b.jpg" /> and the normalized absolute depth<img src="7-2800488\dcd801cf-e1dc-4ad2-b5f3-6b5ef9440618.jpg" />,</p><disp-formula id="scirp.33370-formula133210"><label>(21)</label><graphic position="anchor" xlink:href="7-2800488\7da70fc3-fc45-42ac-beac-2ae71ebd6df8.jpg"  xlink:type="simple"/></disp-formula><p>Note that parameter Q is the reciprocal characteristic length. With these notations, the Hyperbolic velocity profile simplifies to</p><disp-formula id="scirp.33370-formula133211"><label>(22)</label><graphic position="anchor" xlink:href="7-2800488\42dc2180-672b-479f-957c-9a60af986de3.jpg"  xlink:type="simple"/></disp-formula><p>The technical parameters of the velocity profile are related to the physical parameters,</p><disp-formula id="scirp.33370-formula133212"><label>(23)</label><graphic position="anchor" xlink:href="7-2800488\c278fb32-b802-47f0-8115-d23f97caae6c.jpg"  xlink:type="simple"/></disp-formula><p>The inverse relationship is</p><disp-formula id="scirp.33370-formula133213"><label>(24)</label><graphic position="anchor" xlink:href="7-2800488\723c41f6-db65-4774-a7d9-9a05f426fc36.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s3"><title>3. Asymptotic Factor</title><p>To simplify the equations for velocity transforms, it is suitable to introduce a special parameter M. This parameter can be defined at any point of the profile, and in particular, at the top and the bottom interfaces of an interval,</p><disp-formula id="scirp.33370-formula133214"><label>(25)</label><graphic position="anchor" xlink:href="7-2800488\223b31e5-a7ab-4c6d-b8cc-1cc41dbb0fbe.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\38512c3e-ffc4-4e2e-8999-736574b00fee.jpg" /> is the interval thickness (the vertical distance between the two interfaces), subscript a is related to the top interface<img src="7-2800488\e2eefd8e-e19b-4f24-a98b-54e6933e3872.jpg" />, and subscript b is related to the bottom interface<img src="7-2800488\c377469e-8d95-4400-8b67-fdcd6665c1c4.jpg" />. It follows from Equation (25) that</p><disp-formula id="scirp.33370-formula133215"><label>(26)</label><graphic position="anchor" xlink:href="7-2800488\6d001033-2f93-461e-ac12-c194d885db26.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\b86c8c91-8326-4a31-8668-ba1d700a3c6a.jpg" /> and <img src="7-2800488\cc4cf982-f9bf-4a02-ac74-96c4abf068b5.jpg" /> are the top and bottom instantaneous velocities, respectively. Next, it follows from Equation (26) that parameter M is the inverse normalized measure of the difference between the velocity at the given depth level and the asymptotic velocity<img src="7-2800488\1754322f-4ce9-4ea0-8dcf-abb8aea2be08.jpg" />. Equation (26) can be inverted,</p><disp-formula id="scirp.33370-formula133216"><label>(27)</label><graphic position="anchor" xlink:href="7-2800488\c6574381-d4fc-4be0-ab4a-1cb3bb371bfd.jpg"  xlink:type="simple"/></disp-formula><p>The velocity gradient is also related to the asymptotic factor,</p><disp-formula id="scirp.33370-formula133217"><label>(28)</label><graphic position="anchor" xlink:href="7-2800488\3b851a8a-2a48-4d37-a83c-155623ebde04.jpg"  xlink:type="simple"/></disp-formula><p>It follows from Equation (25) that</p><disp-formula id="scirp.33370-formula133218"><label>(29)</label><graphic position="anchor" xlink:href="7-2800488\8ab9432c-d968-4c31-b05a-7e96a2d9f5e9.jpg"  xlink:type="simple"/></disp-formula><p>and</p><disp-formula id="scirp.33370-formula133219"><label>(30)</label><graphic position="anchor" xlink:href="7-2800488\7997bdcb-ed64-48d6-8601-9c735fbaf39e.jpg"  xlink:type="simple"/></disp-formula><p>We use Equations (28) and (29) to get the interface gradients, <img src="7-2800488\8114cebf-edf9-47fc-b859-9bdec782120f.jpg" />and<img src="7-2800488\e214a841-f81c-47a3-8a57-d43eb552b6ce.jpg" />, through the increment of the asymptotic factor, <img src="7-2800488\8bcdd6e8-109d-4644-bacb-7ffbfbda9bc2.jpg" />,</p><disp-formula id="scirp.33370-formula133220"><label>(31)</label><graphic position="anchor" xlink:href="7-2800488\94792395-3144-45c1-8a95-bc2bf37f5927.jpg"  xlink:type="simple"/></disp-formula><p>It follows from Equation (31),</p><disp-formula id="scirp.33370-formula133221"><label>(32)</label><graphic position="anchor" xlink:href="7-2800488\c909b5d2-533a-4850-b9ce-ca8b18ae3d70.jpg"  xlink:type="simple"/></disp-formula><p>Equations (27) and (29) result in the average gradient on the interval, <img src="7-2800488\1d2560a0-7eaf-4c4b-80e5-2b7300b5ba59.jpg" />, expressed either through the interface asymptotic factors <img src="7-2800488\c7a2bd85-568f-4434-8f2f-097d729ad647.jpg" /> and<img src="7-2800488\4a490f12-e230-4a2b-9a78-8c0dccbbac61.jpg" />, or through the interface gradients <img src="7-2800488\b11f182e-c2db-4ccf-a7ed-f9d9d6bd80c1.jpg" /> and<img src="7-2800488\14e502cf-3101-4752-9ee5-bf1a47f9b1e9.jpg" />,</p><disp-formula id="scirp.33370-formula133222"><label>(33)</label><graphic position="anchor" xlink:href="7-2800488\c0b0e614-b778-45df-9f09-37ae695304e6.jpg"  xlink:type="simple"/></disp-formula><p>Introduction of Equation (28) into Equation (33) leads to</p><disp-formula id="scirp.33370-formula133223"><label>(34)</label><graphic position="anchor" xlink:href="7-2800488\2ad75846-0e97-49c0-8014-f6e7ba96df23.jpg"  xlink:type="simple"/></disp-formula><p>The average gradient on the interval with the Hyperbolic velocity profile is the geometric average of the top and bottom interface gradients.</p><p>Given the velocity and its gradient at one interface, one can calculate these parameters at the other interface. The calculations can be done either in depth or in time. Four problems of this kind are considered in Appendix C.</p></sec><sec id="s4"><title>4. Depth-Traveltime Relationship</title><p>Integrate the slowness to get the vertical traveltime vs. the interval thickness,</p><disp-formula id="scirp.33370-formula133224"><label>(35)</label><graphic position="anchor" xlink:href="7-2800488\274d5d87-115f-4377-a3e3-a4387534f3f1.jpg"  xlink:type="simple"/></disp-formula><p>The traveltime equation can be written in terms of asymptotic factors at the top and bottom interfaces, <img src="7-2800488\71961f36-306d-4eb3-a9c7-8f0d1ed579ea.jpg" />and<img src="7-2800488\5cf740cd-5870-4191-9b36-468063752658.jpg" />. With the use of Equations (25) and (29), we obtain</p><disp-formula id="scirp.33370-formula133225"><label>(36)</label><graphic position="anchor" xlink:href="7-2800488\99715e69-636c-4ced-bddc-a191ae0aa7e6.jpg"  xlink:type="simple"/></disp-formula><p>where the top asymptotic factor <img src="7-2800488\e19b811a-f368-4dac-8cbc-e8f37cfc0147.jpg" /> is calculated with Equation (26), and the bottom asymptotic factor <img src="7-2800488\6aed28ff-068f-4d60-a832-e0c3ca470caa.jpg" />- with the first equation of Equation Set (32). The interval velocity (local average velocity) through the layer between the interfaces becomes</p><disp-formula id="scirp.33370-formula133226"><label>(37)</label><graphic position="anchor" xlink:href="7-2800488\891acc0e-3be7-4c19-b7b9-d697fc5dc19b.jpg"  xlink:type="simple"/></disp-formula><p>To get the vertical distance vs. traveltime we should invert Equation (26), i.e. find<img src="7-2800488\18184c45-ddfc-4ccf-a8d5-fedfd520822a.jpg" />. Introduction of Equation (29) into (36) results in</p><disp-formula id="scirp.33370-formula133227"><label>(38)</label><graphic position="anchor" xlink:href="7-2800488\1fbc28b8-4279-4761-97b0-ed0f7f6a07d8.jpg"  xlink:type="simple"/></disp-formula><p>Equation (38) should be solved for the unknown bottom asymptotic factor<img src="7-2800488\d0456191-d1ee-4334-a98c-c50523d216d7.jpg" />,</p><disp-formula id="scirp.33370-formula133228"><label>(39)</label><graphic position="anchor" xlink:href="7-2800488\9990683e-7b02-402a-bd83-58667f97bfd6.jpg"  xlink:type="simple"/></disp-formula><p>Taking exponent from both sides of Equation (39), we get</p><disp-formula id="scirp.33370-formula133229"><label>(40)</label><graphic position="anchor" xlink:href="7-2800488\2f90ee74-ce02-4236-afd5-2819edbf273d.jpg"  xlink:type="simple"/></disp-formula><p>Equation (40) can be solved with the Lambert function,</p><disp-formula id="scirp.33370-formula133230"><label>(41)</label><graphic position="anchor" xlink:href="7-2800488\c63f335f-14be-403d-8c71-595c2802a0f4.jpg"  xlink:type="simple"/></disp-formula><p>where notation <img src="7-2800488\2b929076-7db5-467f-bafd-71949c657b7d.jpg" /> means the zero branch of the Lambert function. The Lambert function <img src="7-2800488\6717dc57-7d42-47de-87dc-21c8bbfaacc7.jpg" /> delivers the solution of the transcendent equation<img src="7-2800488\8767395b-9344-41e7-8546-34280cd3d7e9.jpg" />, see Appendix B for details. In terms of the interface velocities, Equation (41) reduces to</p><disp-formula id="scirp.33370-formula133231"><label>(42)</label><graphic position="anchor" xlink:href="7-2800488\d6c8f3f4-f8fb-474c-bfc4-308fd5691c0b.jpg"  xlink:type="simple"/></disp-formula><p>After the bottom asymptotic factor <img src="7-2800488\c1b0e7e9-f306-4ef7-8c35-a0e2aff2ef39.jpg" /> or the bottom interface velocity <img src="7-2800488\9ced6f00-6c30-4ba7-830b-cd2d7f2d2ee5.jpg" /> is found, the interval thickness can be established with Equation (29),</p><disp-formula id="scirp.33370-formula133232"><label>(43)</label><graphic position="anchor" xlink:href="7-2800488\2b469fb6-347f-4d3e-a3ce-cbc7c2cbbef6.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s5"><title>5. Hyperbolic and Non-Hyperbolic Moveout</title><p>In the absence of the intrinsic anellipticity, the hyperbolic parameter W and the non-hyperbolic parameter H on the interval are defined as</p><disp-formula id="scirp.33370-formula133233"><label>(44)</label><graphic position="anchor" xlink:href="7-2800488\1e8d64a3-b206-4230-ad22-db0aa07bcccf.jpg"  xlink:type="simple"/></disp-formula><p>Introduce the velocity profile from Equation (17). The hyperbolic parameter W becomes</p><disp-formula id="scirp.33370-formula133234"><label>(45)</label><graphic position="anchor" xlink:href="7-2800488\1626af6e-a62b-4678-8183-d428ce4981d1.jpg"  xlink:type="simple"/></disp-formula><p>The non-hyperbolic parameter H becomes</p><disp-formula id="scirp.33370-formula133235"><label>(46)</label><graphic position="anchor" xlink:href="7-2800488\dfed97b2-3367-41c4-8e6e-5be372cdb1fb.jpg"  xlink:type="simple"/></disp-formula><p>With the use of the top and bottom asymptotic factors, the hyperbolic parameter becomes</p><disp-formula id="scirp.33370-formula133236"><label>(47)</label><graphic position="anchor" xlink:href="7-2800488\e9fceacb-e4e4-47b6-a205-03010f8d302a.jpg"  xlink:type="simple"/></disp-formula><p>Introducing Equation (37) for the traveltime into Equation (47), we obtain the local RMS velocity U over the interval. By definition, <img src="7-2800488\0afae736-4a62-4162-a524-506888a03fcf.jpg" />, so</p><disp-formula id="scirp.33370-formula133237"><label>(48)</label><graphic position="anchor" xlink:href="7-2800488\7caa7990-dc05-4e61-ad4c-145c9b14959e.jpg"  xlink:type="simple"/></disp-formula><p>The non-hyperbolic parameter becomes</p><disp-formula id="scirp.33370-formula133238"><label>(49)</label><graphic position="anchor" xlink:href="7-2800488\44c6b31e-bc94-4c92-b3e0-da63e6206df1.jpg"  xlink:type="simple"/></disp-formula><p>With the use of Equation (29), the non-hyperbolic parameter simplifies to</p><disp-formula id="scirp.33370-formula133239"><label>(50)</label><graphic position="anchor" xlink:href="7-2800488\d0fa02e3-d93e-48de-966c-25d5fd0066dd.jpg"  xlink:type="simple"/></disp-formula><p>When the parameters of the velocity profile are specified, the top asymptotic factor M<sub>a</sub> is a known value. The bottom asymptotic factor M<sub>b</sub> can be presented either vs. depth (interval thickness) or vs. traveltime. Thus, the hyperbolic and non-hyperbolic parameters become functions of depth or traveltime, accordingly. The anellipticity induced by the vertically varying velocity is defined as the fractional difference between the fourth-order average velocity <img src="7-2800488\2aed708d-f031-4679-b193-f42e37f3944a.jpg" /> and the RMS velocity<img src="7-2800488\37dec864-1f92-4eb7-a14b-2a20e075987a.jpg" />,</p><disp-formula id="scirp.33370-formula133240"><label>(51)</label><graphic position="anchor" xlink:href="7-2800488\d5595c91-1738-49e8-9e81-6da4db1f9cf6.jpg"  xlink:type="simple"/></disp-formula><p>Parameter <img src="7-2800488\2558b784-c1a2-4b76-9d14-b75754a363a8.jpg" /> can be also considered as a function of depth or vertical time. For a particular case of a single infinite layer (half-space) with any vertical velocity profile,</p><disp-formula id="scirp.33370-formula133241"><label>(52)</label><graphic position="anchor" xlink:href="7-2800488\58c029ee-8323-4dbd-b310-e5152adebd03.jpg"  xlink:type="simple"/></disp-formula><p>The graph for the induced anellipticity <img src="7-2800488\37b59c3b-5f04-49ee-9c2f-5897cb6fe27c.jpg" /> is plotted vs. depth in <xref ref-type="fig" rid="fig3">Figure 3</xref> for three asymptotically bounded velocity models: Exponential, Conic and Hyperbolic. For all the three models, the parameters of the velocity profile are: <img src="7-2800488\66ba83c9-e12e-4c69-8e42-263aabcaa194.jpg" /><img src="7-2800488\29b7e555-d7eb-4a4c-bf4c-473c179b1e54.jpg" />and<img src="7-2800488\0419cab0-c2d1-4636-b3ad-57e5ce8b94bd.jpg" />. At the surface, the anellipticity is zero as there are yet no accumulated variations of the instantaneous velocity. The induced anellipticity is always positive. It reaches a maximum value a definite depth and then vanishes at the</p><p>infinity, where the medium velocity is asymptotically constant.</p></sec><sec id="s6"><title>6. Forward Dix Transform</title><p>Consider a package of n layers (vertical intervals), where the nodes (interfaces) are enumerated from zero, and layers are enumerated from 1. Interval n connects nodes <img src="7-2800488\d37a5b69-5458-4dc5-9574-d19b82913c8d.jpg" /> (top interface) and n (bottom interface). The nodal average velocity<img src="7-2800488\309cd3fe-300b-4c9a-8207-8c866d0f4eff.jpg" />, RMS velocity <img src="7-2800488\a73cb4f7-460d-47ae-bcc7-572c4d1fa3b1.jpg" /> and fourthorder average velocity <img src="7-2800488\c4fa6974-8ba5-4861-a49d-c5049b35c5e6.jpg" /> are</p><disp-formula id="scirp.33370-formula133242"><label>(53)</label><graphic position="anchor" xlink:href="7-2800488\e65ca5b2-c59d-461d-963c-c02931013c1c.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\81d11947-c30e-4d42-89ec-68274fab1be6.jpg" /> is the one-way interval traveltime, <img src="7-2800488\b3e9ca0c-bbf8-4285-94c1-913649ffab2d.jpg" />is the layer thickness, W<sub>n</sub> and H<sub>n</sub> are the interval hyperbolic and non-hyperbolic parameters, respectively. For <img src="7-2800488\e0adbc25-f950-4536-87fe-bb05f6f74b14.jpg" /> we set <img src="7-2800488\d717f715-2689-44fc-a063-39fd8c4d3c5d.jpg" /> in Equation (53). The effective velocities (average, RMS and fourth-order average) can be also defined for any internal point of the interval.</p></sec><sec id="s7"><title>7. Inverse Dix Transform</title><p>Recall that the Hyperbolic velocity profile on the interval is defined by the three parameters: the top interface instantaneous velocity<img src="7-2800488\81b5420b-3747-400b-bbeb-63140bc2f6c1.jpg" />, the top interface gradient<img src="7-2800488\8248e9d6-0aed-49df-be23-a8502e7910f1.jpg" />, and the asymptotic velocity<img src="7-2800488\6f4c467a-e783-4e77-ba49-f24735382522.jpg" />. We consider that the asymptotic velocity is always given a priori. When the two other parameters, <img src="7-2800488\0a4af706-02a4-4e5b-a1da-399643136d9e.jpg" />and<img src="7-2800488\ce095e22-5c43-4f72-8506-e9bb56f5482c.jpg" />, are also known, then velocity transforms are considered forward. When one or both parameters are unknown (with another data specified instead), we deal with the velocity inversion. There are three groups of inverse transforms studied in Appendices D, E and F.</p><p>Appendix D considers the inversion that does not involve the RMS velocity. These formulations deal with the instantaneous velocity and its gradient only. We solve a problem where the two velocities are given at the interfaces, <img src="7-2800488\baddfe61-f58c-4910-b5f3-458986741c06.jpg" />and<img src="7-2800488\c25479cc-4b27-4b43-af4a-cbba0bdbc615.jpg" />, or—alternatively—the two gradients, <img src="7-2800488\f1b0e424-74c5-43bf-9052-2d6e5bf2d7b3.jpg" />and<img src="7-2800488\36978016-d9c6-42d1-bb7e-2589664f4b16.jpg" />. Another kind of problem is when the velocity and its gradient are given at the different interfaces of the interval, i.e. the velocity is given at the top interface and the gradient—at the bottom interface, <img src="7-2800488\052e6cb1-8133-424b-9acc-0d880c5c59fd.jpg" />and<img src="7-2800488\1909b698-d739-4f38-a42f-5c7b622b8f6f.jpg" />, or vice versa, <img src="7-2800488\a3bc784f-bb08-44dc-9f78-ab6ef7e39815.jpg" />and<img src="7-2800488\6222f9fc-cba8-4eff-b664-e32fc1edcddd.jpg" />. We solve also a problem where the instantaneous velocity is given at the bottom interface and at the intermediate point of the interval, <img src="7-2800488\39c15c73-4108-4a0f-abc3-7228c53074ec.jpg" />and<img src="7-2800488\a1d629ff-233b-40b0-869f-5af56945e4c8.jpg" />. These problems are studied both vs. depth and vs. time.</p><p>Appendix E considers the inversion with the RMS velocity specified at the interfaces vs. depth or time with a single parameter unknown, either <img src="7-2800488\6c5338ed-7e3a-49da-80b1-50b2e58113ec.jpg" /> or<img src="7-2800488\26f794ce-289e-4702-af6b-b6fcb44ca21c.jpg" />. We consider also a problem with the traveltime specified vs. the interval thickness, also with a single parameter unknown. Finally, we consider the RMS velocity specified vs. both depth and time, with the two parameters unknown, <img src="7-2800488\3c5b17d6-c452-4122-abbc-711e8649855e.jpg" />and<img src="7-2800488\218acff0-4793-4dfd-8dcf-b721184a4a2e.jpg" />.</p><p>In Appendix F we study the two-interval inversion. The RMS velocity is given vs. depth or time at the two interfaces and at an internal point of the interval. Alternatively, depth can be specified vs. traveltime at the three points. Both parameters of the velocity profile are unknown. This is a so-called three-point or two-interval inversion.</p></sec><sec id="s8"><title>8. Ray Trajectories</title><p>In this section we establish the trajectories of non-vertical rays. Due to Snell’s law, in 1D medium the horizontal slowness <img src="7-2800488\ec5cc889-1e78-46e6-813a-d7a64091a37a.jpg" /> is constant, and the ray angle <img src="7-2800488\f0910b65-44ac-4e98-a3a8-f44dff642988.jpg" /> (measured from the vertical axis) becomes</p><disp-formula id="scirp.33370-formula133243"><label>(54)</label><graphic position="anchor" xlink:href="7-2800488\baad946c-c010-4ffb-9ee9-4ce16bf9b44b.jpg"  xlink:type="simple"/></disp-formula><p>Introduce the ray parameter m,</p><disp-formula id="scirp.33370-formula133244"><label>(55)</label><graphic position="anchor" xlink:href="7-2800488\ea079da6-8401-4346-853c-b24225a97061.jpg"  xlink:type="simple"/></disp-formula><p>where Q and R are the physical parameters of the Hyperbolic velocity profile, <img src="7-2800488\9f98a51c-dd57-40cd-b32a-12983a6df2d6.jpg" />is the normalized ray slowness, and m is its inverse value. We call parameter m “eccentricity of the ray trajectory” as it is very similar to the eccentricity of the hyperbolic and elliptic rays of the Conic velocity model [<xref ref-type="bibr" rid="scirp.33370-ref13">13</xref>]. With Equation (17), the sine of the ray angle becomes</p><disp-formula id="scirp.33370-formula133245"><label>(56)</label><graphic position="anchor" xlink:href="7-2800488\6c106e55-363a-4425-8e33-73a8077ab768.jpg"  xlink:type="simple"/></disp-formula><p>so that the tangent of this angle is</p><disp-formula id="scirp.33370-formula133246"><label>(57)</label><graphic position="anchor" xlink:href="7-2800488\8246ea66-e7e6-4b5d-9d74-dc6087fb9045.jpg"  xlink:type="simple"/></disp-formula><p>where<img src="7-2800488\49ff234a-0df4-44dd-bd12-2e9db20340e1.jpg" />. Parameter <img src="7-2800488\2480d1f4-038a-404f-9a5a-d93f9f463067.jpg" /> (the conjugate eccentricity squared) may be positive or negative. Introduce the dimensionless coordinates,</p><disp-formula id="scirp.33370-formula133247"><label>(58)</label><graphic position="anchor" xlink:href="7-2800488\dea163d6-f9ea-4534-b192-115e640605b5.jpg"  xlink:type="simple"/></disp-formula><p>The tangent of the ray angle becomes</p><disp-formula id="scirp.33370-formula133248"><label>(59)</label><graphic position="anchor" xlink:href="7-2800488\15ff501d-60f3-4f4d-9f54-b87fe9ffcc9c.jpg"  xlink:type="simple"/></disp-formula><p>Integrating Equation (59), we obtain</p><disp-formula id="scirp.33370-formula133249"><label>(60)</label><graphic position="anchor" xlink:href="7-2800488\1c21a0ae-4d3b-4192-b156-81381f6ccb06.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\24db21fe-2b5e-486f-8b92-910d6d577abb.jpg" /> is the constant of integration. This integral can be reduced to</p><disp-formula id="scirp.33370-formula133250"><label>(61)</label><graphic position="anchor" xlink:href="7-2800488\1069d4fb-1932-4789-900a-a92266d5c58a.jpg"  xlink:type="simple"/></disp-formula><p>To obtain the integral on the right side of Equation (61), we consider two cases, or two ranges of the eccentricity: m &gt; 1 (pre-critical rays) and m &lt; 1 (post-critical rays),</p><disp-formula id="scirp.33370-formula133251"><label>(62)</label><graphic position="anchor" xlink:href="7-2800488\bbbfb297-abbe-444f-8408-25633bcf3b89.jpg"  xlink:type="simple"/></disp-formula><p>For a limiting case <img src="7-2800488\122979e7-ec8e-4bbd-a6e7-b28bd970520f.jpg" /> (critical rays),</p><disp-formula id="scirp.33370-formula133252"><label>(63)</label><graphic position="anchor" xlink:href="7-2800488\9b8860d4-1953-4249-9711-d03dc3f6ab06.jpg"  xlink:type="simple"/></disp-formula><p>We emphasize that two kinds of rays exist for any monotonously increasing and asymptotically bounded velocity model, and in particular, for the Hyperbolic model. The pre-critical rays that may start on the earth surface, propagate to the infinite depth, and their curvature asymptotically vanishes. The post-critical rays have a limited propagation depth. Their arc-like trajectories have a finite minimum curvature at the turning point, and these rays return to the earth surface. Note that at any point of the trajectory, the ray path curvature <img src="7-2800488\80a3017f-85ed-4fa3-9387-1e55858f8481.jpg" /> depends on the velocity gradient k only,</p><disp-formula id="scirp.33370-formula133253"><label>(64)</label><graphic position="anchor" xlink:href="7-2800488\fe67f999-c5fd-4be8-b7b4-4079270f0e42.jpg"  xlink:type="simple"/></disp-formula><p>In particular, the linear velocity model with a constant velocity gradient leads to ray trajectories of constant curvatures, i.e. to the circular arcs.</p><p>The critical rays with the unit eccentricity <img src="7-2800488\4f0067f5-1258-499f-8f18-f215dca78ada.jpg" /> are the limit case between the two types of rays. Their takeoff angle (the ray angle at the upper interface) is called the critical angle<img src="7-2800488\264558ca-c63d-4d68-a772-4bab83fb7011.jpg" />. It follows from Equations (54) and (55) that the critical take-off angle is</p><disp-formula id="scirp.33370-formula133254"><label>(65)</label><graphic position="anchor" xlink:href="7-2800488\e4329b28-fc0f-4e20-a62f-9bdcd107f9f7.jpg"  xlink:type="simple"/></disp-formula><p>It follows from Equations (61) and (62) that the trajectories of the pre-critical and post-critical rays are</p><disp-formula id="scirp.33370-formula133255"><label>(66)</label><graphic position="anchor" xlink:href="7-2800488\44b54e56-1bbe-4fe0-88fd-fa2fd3810337.jpg"  xlink:type="simple"/></disp-formula><p>At infinite depth, pre-critical rays become asymptotically straight. Equation (57) leads to</p><disp-formula id="scirp.33370-formula133256"><label>(67)</label><graphic position="anchor" xlink:href="7-2800488\44d62521-efd4-475e-9d0f-bb6f7277e5be.jpg"  xlink:type="simple"/></disp-formula><p>However, although the slope of these rays converges to a constant value and their curvature becomes infinitesimal, the pre-critical rays of the Hyperbolic model have no asymptotic straight line, unlike the pre-critical rays of the EAB and the Conic models. The pre-critical, critical and post-critical rays are plotted in <xref ref-type="fig" rid="fig4">Figure 4</xref> for the Hyperbolic, the Conic and the Exponential (EAB) models. Parameters of the velocity profile are the same</p><p>as above. The three columns of numbers to the right of the plot area are velocities for the three models at the specified depth levels.</p></sec><sec id="s9"><title>9. Maximum Penetration Depth</title><p>Pre-critical rays penetrate to infinite depth. The maximum penetration depth of post-critical rays follows from Equation (59). At the turning point, the ray angle<img src="7-2800488\1ff589d6-dd35-4fef-928e-432084d2d34a.jpg" />, and thus, its tangent becomes infinite. This leads to a quadratic equation with a single positive root,</p><disp-formula id="scirp.33370-formula133257"><label>(68)</label><graphic position="anchor" xlink:href="7-2800488\e1383fa9-9514-4fe5-beb7-848dcdbb66ca.jpg"  xlink:type="simple"/></disp-formula><p>Recall that <img src="7-2800488\73a2432f-8e0a-4a91-b2c4-b0b7c851d1d7.jpg" /> is the dimensionless depth measured from the absolute origin (above the upper interface). The maximum penetration depth in units of length, measured from the upper interface reads</p><disp-formula id="scirp.33370-formula133258"><label>(69)</label><graphic position="anchor" xlink:href="7-2800488\3393ab99-fec9-4311-8ce4-ee8b98865cd4.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s10"><title>10. Lateral Propagation, Traveltime and Arc Length</title><p>In a 1D medium, it is convenient to express the lateral propagation distance<img src="7-2800488\70d84a74-e80c-4f00-b99a-4834d56e0a5b.jpg" />, traveltime <img src="7-2800488\1e477a13-a9da-4b2d-a552-482a53b271dc.jpg" /> and arc length <img src="7-2800488\c2b1440d-a46b-432a-ba92-c2eb20c68387.jpg" /> through the ray angle <img src="7-2800488\0abb5487-b36f-425e-ab10-093a1d538f0f.jpg" /> and angle-dependent gradient<img src="7-2800488\48e26c42-485e-4766-80af-5da0f7e81cae.jpg" />. These relationships are [12,16] (Kaufman, 1953; Ravve and Koren, 2006)</p><disp-formula id="scirp.33370-formula133259"><label>(70)</label><graphic position="anchor" xlink:href="7-2800488\a82c212a-6aa8-43ba-87df-34ed5eb106ae.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\bde405ab-c605-445b-8f06-7233e03ef3c0.jpg" /> and <img src="7-2800488\3203fe5f-fd35-44dc-ac3b-96360dbbfa41.jpg" /> are ray angles at the departure and the destination points, respectively. Equations (17) and (19) make it possible to eliminate depth and to express the gradient through the velocity,</p><disp-formula id="scirp.33370-formula133260"><label>(71)</label><graphic position="anchor" xlink:href="7-2800488\b7374b0c-1173-454f-a8b4-6c502c4546ab.jpg"  xlink:type="simple"/></disp-formula><p>Next we apply Snell’s law and obtain the vertical gradient vs. the ray angle,</p><disp-formula id="scirp.33370-formula133261"><label>(72)</label><graphic position="anchor" xlink:href="7-2800488\8eb44a5d-c254-4e11-96bd-743d4e1cc58d.jpg"  xlink:type="simple"/></disp-formula><p>Note that</p><disp-formula id="scirp.33370-formula133262"><label>(73)</label><graphic position="anchor" xlink:href="7-2800488\f10e4e8f-a698-4c92-a12b-42adede297a6.jpg"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.33370-formula133263"><label>(74)</label><graphic position="anchor" xlink:href="7-2800488\21ba0a9e-fb01-4aa6-90de-f69205f2a87f.jpg"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.33370-formula133264"><label>(75)</label><graphic position="anchor" xlink:href="7-2800488\c38605a5-8d66-4f9b-976c-1212e3e05656.jpg"  xlink:type="simple"/></disp-formula><p>The indefinite integral on the right side of this equation essentially depends on the range of the eccentricity m, resulting in</p><disp-formula id="scirp.33370-formula133265"><label>(76)</label><graphic position="anchor" xlink:href="7-2800488\94f777a8-b1d3-42b3-b45d-b027be2461a6.jpg"  xlink:type="simple"/></disp-formula><p>For the critical ray, <img src="7-2800488\de9120df-2d75-4a6d-a671-5e8f3386a8ca.jpg" /></p><disp-formula id="scirp.33370-formula133266"><label>(77)</label><graphic position="anchor" xlink:href="7-2800488\6932c126-d763-4f0d-b668-181085137ae8.jpg"  xlink:type="simple"/></disp-formula><p>Let <img src="7-2800488\ac9f0575-4cd1-44b6-8da4-91d0d6d6353c.jpg" /> and <img src="7-2800488\60469582-6e92-4b8f-926a-63c138635705.jpg" /> be the ray angles at the start point and the destination point of the ray path, respectively. Equation Set (76) can be re-arranged as follows</p><p>• For the pre-critical rays, <img src="7-2800488\685ab489-9650-488d-b93c-b5529f9c0de6.jpg" /></p><disp-formula id="scirp.33370-formula133267"><label>(78)</label><graphic position="anchor" xlink:href="7-2800488\2da93935-f8d8-4fb4-9536-abf013c6365e.jpg"  xlink:type="simple"/></disp-formula><p>• For the post-critical rays, <img src="7-2800488\bedee4cc-d313-4113-8aa9-3f08819c58db.jpg" /></p><disp-formula id="scirp.33370-formula133268"><label>(79)</label><graphic position="anchor" xlink:href="7-2800488\99de2bd3-fde1-4a95-9a27-5b6a1a1742cf.jpg"  xlink:type="simple"/></disp-formula><p><img src="7-2800488\1b2a0c43-0e60-4a4e-94b8-9a508f74e94f.jpg" />and <img src="7-2800488\cf62728a-c994-4db4-a758-636abcf59f9f.jpg" /> are functions of the ray angles at the endpoints of the path. The following identities were used,</p><disp-formula id="scirp.33370-formula133269"><label>(80)</label><graphic position="anchor" xlink:href="7-2800488\3eab7cf7-fa54-4fc7-b838-5e159acd2f20.jpg"  xlink:type="simple"/></disp-formula><p>To simplify the notations, we introduce one more function of the ray angles at the endpoints,</p><disp-formula id="scirp.33370-formula133270"><label>(81)</label><graphic position="anchor" xlink:href="7-2800488\1777e96f-9003-4568-aad1-145d9ca90f69.jpg"  xlink:type="simple"/></disp-formula><p>The normalized lateral propagation becomes</p><disp-formula id="scirp.33370-formula133271"><label>(82)</label><graphic position="anchor" xlink:href="7-2800488\52a50513-93ee-4c71-8e55-d87d6435e5c8.jpg"  xlink:type="simple"/></disp-formula><p>The normalized traveltime is</p><disp-formula id="scirp.33370-formula133272"><label>(83)</label><graphic position="anchor" xlink:href="7-2800488\274b192c-6428-4418-befc-4e215ccbae01.jpg"  xlink:type="simple"/></disp-formula><p>The normalized arc length is</p><disp-formula id="scirp.33370-formula133273"><label>(84)</label><graphic position="anchor" xlink:href="7-2800488\4d066789-f086-4d11-8048-e9ca057dcee5.jpg"  xlink:type="simple"/></disp-formula><p>For the critical rays, <img src="7-2800488\fa3402ad-072a-4d70-9cc2-b81107c5722f.jpg" />, and the departure angle is critical,<img src="7-2800488\2bda1457-bf38-4824-af26-6e23f131209c.jpg" />. The ray path parameters are,</p><disp-formula id="scirp.33370-formula133274"><label>(85)</label><graphic position="anchor" xlink:href="7-2800488\6612aa65-f63a-4069-b4e2-26f0ebf8d956.jpg"  xlink:type="simple"/></disp-formula><p>The current depth can be also expressed through the ray angle. It follows from Equation (17) that</p><disp-formula id="scirp.33370-formula133275"><label>(86)</label><graphic position="anchor" xlink:href="7-2800488\cd49b621-5404-432c-998c-b5945f54d3e7.jpg"  xlink:type="simple"/></disp-formula><p>Recall that</p><disp-formula id="scirp.33370-formula133276"><label>(87)</label><graphic position="anchor" xlink:href="7-2800488\e288e6aa-8d0d-4308-9249-a9626310562a.jpg"  xlink:type="simple"/></disp-formula><p>and therefore</p><disp-formula id="scirp.33370-formula133277"><label>(88)</label><graphic position="anchor" xlink:href="7-2800488\64a4d78b-b964-4b32-8699-cc5d7c4c34e5.jpg"  xlink:type="simple"/></disp-formula><p>In <xref ref-type="fig" rid="fig5">Figure 5</xref> we plot the graphs for the traveltime vs. ray path arc length for the pre-critical, the critical and the post-critical rays of the Hyperbolic velocity profile.</p><p>The “trigonometric” solution for the lateral propagation and traveltime of the post-critical rays was obtained (in a different form) by Muscat (1937). However, it was not pointed out in this early study that the solution was related to the post-critical rays only, and that the other, “hyperbolic” solution exists for the pre-critical rays (and a “transient” solution for the critical rays, which are the limit case between the two basic types of rays).</p><p>Note that for the vanishing or infinitesimal parameter<img src="7-2800488\e2c33707-3f0f-4a0f-8ac6-4eab76e679fc.jpg" />, the shape of the trajectory, the lateral propagation, the traveltime and the arc length of the Hyperbolic model ray path converge to the corresponding character-</p><p>istics of the linear velocity profile. In this case the asymptotic velocity <img src="7-2800488\f3c4cd9b-8183-4fcf-9a1a-123ecb7e6df0.jpg" /> becomes unbounded, so that the product <img src="7-2800488\094b8d32-353d-4332-b101-2bec4267206e.jpg" /> remains a finite value and converges to a constant gradient of the linear velocity model. The eccentricity m becomes infinitesimal, and</p><disp-formula id="scirp.33370-formula133278"><label>(89)</label><graphic position="anchor" xlink:href="7-2800488\45bf7ed1-4392-4024-865a-28437c6103cf.jpg"  xlink:type="simple"/></disp-formula><p>Functions I and J from Equations (79) and (81) simplify to</p><disp-formula id="scirp.33370-formula133279"><label>(90)</label><graphic position="anchor" xlink:href="7-2800488\d5ee7dc5-dbfe-4163-9a24-84b0784e1d36.jpg"  xlink:type="simple"/></disp-formula><p>Equation (66) comes to</p><disp-formula id="scirp.33370-formula133280"><label>(91)</label><graphic position="anchor" xlink:href="7-2800488\694321d1-e30c-4f66-9ace-98ec26d25ec9.jpg"  xlink:type="simple"/></disp-formula><p>This is an equation for the circular arc of radius <img src="7-2800488\eda2d63e-1ddd-403d-bbfe-c726e0d04341.jpg" /></p><p>whose center is located at <img src="7-2800488\adede741-2428-4be1-b0f7-274700d58497.jpg" /> where <img src="7-2800488\89b937f9-f476-4076-bc6b-cae8fc3d2087.jpg" /> is the ray slowness. The lateral propagation, Equation (82), becomes</p><disp-formula id="scirp.33370-formula133281"><label>(92)</label><graphic position="anchor" xlink:href="7-2800488\52d89b89-6ceb-46df-ba3c-529cf0f910fc.jpg"  xlink:type="simple"/></disp-formula><p>Equation (83) yields the traveltime for this limiting case,</p><disp-formula id="scirp.33370-formula133282"><label>(93)</label><graphic position="anchor" xlink:href="7-2800488\84b9068c-5291-480f-8e8d-608129005617.jpg"  xlink:type="simple"/></disp-formula><p>and finally, Equation (84) for the arc length converges to</p><disp-formula id="scirp.33370-formula133283"><label>(94)</label><graphic position="anchor" xlink:href="7-2800488\1b147174-3a58-440d-bf96-a849ce17a67e.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s11"><title>11. Full Arc of Post-Critical Ray</title><p>Consider two points on the earth surface, the transmitter and the receiver, located <img src="7-2800488\511ecf64-b5cb-438a-ae5f-7518b04de0a0.jpg" /> distance apart. The goal is to trace the full arc of the post critical turning ray that connects the two points. Note that due to the symmetry of the arc, the ray angle at the destination point <img src="7-2800488\54e98107-e4b2-4cfd-91d7-06e5ed0e4186.jpg" /> is related to the take-off angle <img src="7-2800488\320814b7-1148-48aa-8bda-a1aa9b716e35.jpg" /> ,</p><disp-formula id="scirp.33370-formula133284"><label>(95)</label><graphic position="anchor" xlink:href="7-2800488\f860d052-1f5a-4502-8eae-d1c882243fee.jpg"  xlink:type="simple"/></disp-formula><p>Applying Equations (79), (81) and (82), we obtain</p><disp-formula id="scirp.33370-formula133285"><label>(96)</label><graphic position="anchor" xlink:href="7-2800488\c0c88933-724e-4f19-b330-6022c5743c54.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\8f3e83ec-9014-462b-8267-61769d8da61e.jpg" /> is the conjugate eccentricity of the post-critical ray path. Recall that</p><disp-formula id="scirp.33370-formula133286"><label>(97)</label><graphic position="anchor" xlink:href="7-2800488\c47e8513-749d-4a77-bdaf-bd75a9e4fb5d.jpg"  xlink:type="simple"/></disp-formula><p>Equation (96) simplifies to</p><disp-formula id="scirp.33370-formula133287"><label>(98)</label><graphic position="anchor" xlink:href="7-2800488\47f75247-1914-482d-93b9-1c0462b7e482.jpg"  xlink:type="simple"/></disp-formula><p>Equation (98) should be solved numerically for the unknown eccentricity m. To obtain the initial guess, we assume that the distance <img src="7-2800488\f959c5ac-5cc2-478c-b31a-801ee6ba726a.jpg" /> is small. Then the take-off angle <img src="7-2800488\ac66d2c8-0bb6-4eef-b4dd-aed8d33a9d5e.jpg" /> approaches<img src="7-2800488\17be2ffc-58c3-4f0c-9730-0b56d49466ad.jpg" />, and according to Equation (97), the eccentricity exceeds the sine of the critical angle only slightly. We assume</p><disp-formula id="scirp.33370-formula133288"><label>(99)</label><graphic position="anchor" xlink:href="7-2800488\66193770-ef3c-43cc-abf5-1c18183c4802.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\c11af11c-5f76-4af8-a646-2cd7f644bd08.jpg" /> is a small positive value. Next we expand Equation (98) into the Taylor series and neglect the high order terms,</p><disp-formula id="scirp.33370-formula133289"><label>(100)</label><graphic position="anchor" xlink:href="7-2800488\58ed75f1-74a6-4cc9-a6de-311ba47322dd.jpg"  xlink:type="simple"/></disp-formula><p>The cubic Equation (100) has a single positive root. For example, for the velocity profile<img src="7-2800488\c39443af-052b-4e90-8c5c-e168c2983934.jpg" />, <img src="7-2800488\21656980-8214-4902-9373-980c8aa63b00.jpg" />and<img src="7-2800488\18ef145e-1dc3-4d0f-b81a-f6366f4f7a43.jpg" />, and the offset<img src="7-2800488\48e8ee9c-3fb6-460c-af71-51037a89c5b7.jpg" />, the critical angle becomes<img src="7-2800488\558c6548-2c20-4e37-af55-30704b64e8f0.jpg" />. Equation (100) leads to<img src="7-2800488\86429681-8082-4caf-bfa6-efbf13a7a5a5.jpg" />, and Equation (99) yields the initial guess<img src="7-2800488\f9559888-732f-4f36-aad6-ad065d929dbf.jpg" />. Solving Equation (98) with the Newton method, we obtain the eccentricity<img src="7-2800488\d4500a0e-103c-42e1-925e-8d67b96a5dcd.jpg" />. The take-off angle becomes<img src="7-2800488\b1217040-6fe8-4f36-a5e4-242803c28a3d.jpg" />. The arcs are plotted in <xref ref-type="fig" rid="fig6">Figure 6</xref> for the three asymptotically bounded velocity models. In the shallow region, the Hyperbolic model has a smaller vertical gradient (and thus, a smaller curvature) than the Conic and the EAB models, and thus, the Hyperbolic model yields a smaller take-off angle. The ray path arc of the Hyperbolic model passes above the Conic and the EAB arcs.</p></sec><sec id="s12"><title>12. Boundary Value Ray Tracing</title><p>Given data are the departure point <img src="7-2800488\9a08e0a3-9e45-4ae4-adb0-745e455e3d45.jpg" /> and the arrival point<img src="7-2800488\a828c673-4908-4c83-9c3b-c3b762decba1.jpg" />, and the goal is to trace the ray path. The ray path is an explicit function of the eccentricity m, and this parameter is so far unknown. Without any loss of generality, we assume here that<img src="7-2800488\d233d164-c5bd-4e45-bb6a-c05be7f220bf.jpg" />, i.e. that the lateral distance <img src="7-2800488\41f96560-8b4b-4db7-a536-da066ef5a29c.jpg" /> and the horizontal ray slowness</p><p>p are positive. Assume also<img src="7-2800488\a4147ef2-be2a-430c-a158-a40a67cb9322.jpg" />, which is also not a limitation (one can reverse the endpoints otherwise). Since the ray tracing equations depend on the type of ray, we need to determine, whether the ray is pre-critical or post-critical. For this, one can plot a critical path that starts at the departure point at the critical take-off angle<img src="7-2800488\fb57ebeb-8e4e-4829-873e-c45daef9009f.jpg" />. If the destination point lays to the left from the critical trajectory, then the ray path is pre-critical. The ray path is post-critical if the destination point lays to the right. The critical lateral propagation <img src="7-2800488\800cb3d9-70a5-4f8b-9e43-6d96d9c1a15b.jpg" /> is delivered by Equation (63), which can be rearranged as</p><disp-formula id="scirp.33370-formula133290"><label>(101)</label><graphic position="anchor" xlink:href="7-2800488\92826e8a-eef4-4d59-baac-32744384e4b0.jpg"  xlink:type="simple"/></disp-formula><p>Given the vertical coordinates of the source and the receiver, <img src="7-2800488\51e25389-2cf5-4644-b496-9b933b302ee6.jpg" />and<img src="7-2800488\f87af52b-35c1-46db-9747-4c8d8bddccd0.jpg" />, we calculate the critical lateral propagation, and then apply the criterion</p><disp-formula id="scirp.33370-formula133291"><label>(102)</label><graphic position="anchor" xlink:href="7-2800488\60a38020-eff4-4faf-84a8-018712e16479.jpg"  xlink:type="simple"/></disp-formula><p>The velocities at the end points of the trajectory <img src="7-2800488\efcc1735-ee53-4441-aec0-728b1d526f0d.jpg" /> and <img src="7-2800488\2fcd2aa5-caa4-469e-94df-76054a533ecb.jpg" /> are known values. It follows from Snell’s law that the ray angles at the end points of the trajectory are the functions of the eccentricity alone,</p><disp-formula id="scirp.33370-formula133292"><label>(103)</label><graphic position="anchor" xlink:href="7-2800488\45004191-0729-4570-9f09-4d3f3fa8d0ba.jpg"  xlink:type="simple"/></disp-formula><p>Note that for the pre-critical rays and for the post critical rays before the turning point, the ray angle is acute, while for the turning rays after the turning point the ray angle is obtuse,</p><disp-formula id="scirp.33370-formula133293"><label>(104)</label><graphic position="anchor" xlink:href="7-2800488\15626317-2cf8-4986-a5b5-f8c002f6d525.jpg"  xlink:type="simple"/></disp-formula><p>Equation (82) relates the lateral propagation <img src="7-2800488\15a6694e-ec5b-40d6-bd9c-629bb7fb855e.jpg" /> to the ray angles at the endpoints, which, in turn, depend on the eccentricity according to Equations (103) and (104),</p><disp-formula id="scirp.33370-formula133294"><label>(105)</label><graphic position="anchor" xlink:href="7-2800488\b4f08c35-0aa7-4ca9-9fe0-d534fcd803ae.jpg"  xlink:type="simple"/></disp-formula><p>where</p><disp-formula id="scirp.33370-formula133295"><label>(106)</label><graphic position="anchor" xlink:href="7-2800488\a1214c7c-d832-4ac2-b184-4fc5a898078c.jpg"  xlink:type="simple"/></disp-formula><p>Function</p><disp-formula id="scirp.33370-formula133296"><label>(107)</label><graphic position="anchor" xlink:href="7-2800488\229c3707-5182-4bb9-8fcf-5d310e3080c2.jpg"  xlink:type="simple"/></disp-formula><p>is delivered by Equations (78) and (79). It was initially defined as a function of the endpoints’ ray angles, but due to Equations (103) and (104) it can be considered as a function of the eccentricity alone. Next we solve nonlinear Equation (105) numerically for the unknown eccentricity m. Then the ray angles at the endpoints can be established, and the ray path can be plotted with Equation (66). Numerical examples for the boundary value ray tracing with the Hyperbolic velocity profile are presented in Appendix G.</p></sec><sec id="s13"><title>13. Conclusion</title><p>The Hyperbolic asymptotically bounded exponential velocity model has been studied and compared to other asymptotically bounded models, in particular, the Exponential and the Conic. The forward and the inverse velocity transforms are derived. The Hyperbolic model allows a better representation of the vertical velocity variations in compacted sediments, especially in the case of thick layers. An advantage of the Hyperbolic model is that the instantaneous velocity reaches the asymptotic value in a more slow and gradual fashion, as compared to other asymptotically bounded models. Ray tracing equations have been derived. The ray trajectories, traveltimes and arc lengths have been studied analytically, and the boundary value ray tracing problem have been solved. We have tried to present a complete theory for both vertical and non-vertical rays propagating through the Hyperbolic model. Application of the Hyperbolic velocity distribution enables us to present realistic geological models using fewer parameters, as compared to the classical linear velocity function. We showed that the linear velocity function is a limiting particular case of the Hyperbolic model.</p></sec><sec id="s14"><title>14. Acknowledgements</title><p>We are grateful to Paradigm Geophysical for the financial and technical support of this study and for the permission to publish its results.</p></sec><sec id="s15"><title>REFERENCES</title></sec><sec id="s16"><title>Appendix A. Gradient-Velocity Diagrams</title><p>In this appendix we derive the gradient-velocity diagrams for the five asymptotically bounded velocity models. In all cases we pass to a shifted frame<img src="7-2800488\f3fbdd6e-2e32-4102-9806-ddbc252d3cc3.jpg" />, in which the governing equations are essentially simplified. The value of the vertical shift h is different for all models. For all models the “absolute” origin corresponds to a point of maximum gradient. For all models except the Exponential slowness, this is also the point of a vanishing instantaneous velocity. As we show below, for the Exponential slowness model, the absolute origin corresponds to the half-limiting velocity<img src="7-2800488\99a02beb-41ba-4858-9aae-6ed374ae96a7.jpg" />.</p>A.1. The Hyperbolic Muscat Model<p>The velocity profile is given by</p><disp-formula id="scirp.33370-formula133297"><label>(A-1)</label><graphic position="anchor" xlink:href="7-2800488\61a63c03-5f60-4b8b-be5d-52dfa5e680a3.jpg"  xlink:type="simple"/></disp-formula><p>Establish the depth level where the velocity vanishes. This point is located above the earth surface,</p><disp-formula id="scirp.33370-formula133298"><label>(A-2)</label><graphic position="anchor" xlink:href="7-2800488\14952d47-575c-41b3-b24a-cbb0a58d8f87.jpg"  xlink:type="simple"/></disp-formula><p>Introduce the shifted frame,<img src="7-2800488\264cc207-c7af-40a2-a313-ca50d7fb9164.jpg" />. The velocity profile becomes</p><disp-formula id="scirp.33370-formula133299"><label>(A-3)</label><graphic position="anchor" xlink:href="7-2800488\babab174-fcc9-483d-8f63-179563e9407a.jpg"  xlink:type="simple"/></disp-formula><p>The vertical gradient is</p><disp-formula id="scirp.33370-formula133300"><label>(A-4)</label><graphic position="anchor" xlink:href="7-2800488\d8843462-4966-4083-a053-2c982d7a58eb.jpg"  xlink:type="simple"/></disp-formula><p>At the absolute origin<img src="7-2800488\762feffe-7992-4de5-9a9a-d33678e12c81.jpg" />, the gradient is maximal,</p><disp-formula id="scirp.33370-formula133301"><label>(A-5)</label><graphic position="anchor" xlink:href="7-2800488\7438f5d1-a645-4664-971b-1f06fd762abf.jpg"  xlink:type="simple"/></disp-formula><p>Introduction of Equation (A-5) into (A-3) and (A-4) leads to</p><disp-formula id="scirp.33370-formula133302"><label>(A-6)</label><graphic position="anchor" xlink:href="7-2800488\8e1c18e1-bb97-422b-9d33-0bfa563c07f3.jpg"  xlink:type="simple"/></disp-formula><p>Finally, elimination of depth <img src="7-2800488\dafcf487-1079-4746-be6a-5f34afd928a9.jpg" /> from the two equations of Equation Set (A-6) results in</p><disp-formula id="scirp.33370-formula133303"><label>(A-7)</label><graphic position="anchor" xlink:href="7-2800488\b432b121-8e62-4c19-9e3d-c5df8f0f58be.jpg"  xlink:type="simple"/></disp-formula>A.2. The Exponential Muscat Model<p>The velocity model is described by</p><disp-formula id="scirp.33370-formula133304"><label>(A-8)</label><graphic position="anchor" xlink:href="7-2800488\e4e8d00d-1f51-4002-8dce-a3c87c190d26.jpg"  xlink:type="simple"/></disp-formula><p>The vertical shift is<img src="7-2800488\be5e4da3-4e49-4d24-9ed2-eebea28f7c5a.jpg" />, and in the shifted frame, <img src="7-2800488\5e9016d0-d834-4bb0-9dde-ba33182b8e09.jpg" />, Equation (A-8) simplifies to</p><disp-formula id="scirp.33370-formula133305"><label>(A-9)</label><graphic position="anchor" xlink:href="7-2800488\5b808c78-2cfe-4650-b0ec-6f888d6bfcd9.jpg"  xlink:type="simple"/></disp-formula><p>The velocity gradient is</p><disp-formula id="scirp.33370-formula133306"><label>(A-10)</label><graphic position="anchor" xlink:href="7-2800488\aa4b1d36-687e-4bfa-a10e-c407f657f665.jpg"  xlink:type="simple"/></disp-formula><p>with<img src="7-2800488\89f00eac-0fef-4ee6-ae6c-9fb851a44d66.jpg" />, so that</p><disp-formula id="scirp.33370-formula133307"><label>(A-11)</label><graphic position="anchor" xlink:href="7-2800488\1e264fee-cf2b-40e4-ada1-1be764bf3970.jpg"  xlink:type="simple"/></disp-formula><p>Eliminate the absolute depth from Equations (A-9) and (A-11) and obtain the gradient-velocity relationship,</p><disp-formula id="scirp.33370-formula133308"><label>(A-12)</label><graphic position="anchor" xlink:href="7-2800488\96c9b316-0db1-4201-a461-80291badbbbf.jpg"  xlink:type="simple"/></disp-formula>A.3. The Exponential Slowness Model<p>The profile equation reads</p><disp-formula id="scirp.33370-formula133309"><label>(A-13)</label><graphic position="anchor" xlink:href="7-2800488\936bf908-7fce-4f59-8881-4ffbc72f0dc8.jpg"  xlink:type="simple"/></disp-formula><p>Unlike the other asymptotically bounded models mentioned in the introduction, the velocity in the Exponential slowness model does not vanish at a finite negative depth. The velocity vanishes at <img src="7-2800488\e3a2c3fa-4a6a-49a9-934c-4569f2121307.jpg" /> and approaches to the asymptotic value <img src="7-2800488\cd73ed35-1f1d-46c7-ba48-f21350696fec.jpg" /> at<img src="7-2800488\71c3dd3c-6eb3-4149-b9f6-f55db2aed0eb.jpg" />. The gradient of the velocity is</p><disp-formula id="scirp.33370-formula133310"><label>(A-14)</label><graphic position="anchor" xlink:href="7-2800488\92190ead-c6b4-4ed5-9805-339c04ab1b93.jpg"  xlink:type="simple"/></disp-formula><p>The gradient <img src="7-2800488\a4d9af58-3e55-4477-a7f6-6e66773e3fdb.jpg" /> vanishes at both remote ends, <img src="7-2800488\aa8bea55-7495-4279-a12a-67fb70bc2d28.jpg" />, and <img src="7-2800488\ba525371-50f4-4b93-bfb5-af2190f5bda7.jpg" /> has a single critical point: the maximum of the gradient occurs at<img src="7-2800488\8f916357-2eb2-45d5-8528-6a92282d483a.jpg" />,</p><disp-formula id="scirp.33370-formula133311"><label>(A-15)</label><graphic position="anchor" xlink:href="7-2800488\4e7a6b8c-3d2d-4692-a59d-74683e5ee2d5.jpg"  xlink:type="simple"/></disp-formula><p>We emphasize that the logarithm in Equation (A-15) may prove to be both positive and negative. At the point<img src="7-2800488\1b8c487c-763b-435b-aad4-5dd6ecba32c9.jpg" />, the maximum gradient and the velocity are</p><disp-formula id="scirp.33370-formula133312"><label>(A-16)</label><graphic position="anchor" xlink:href="7-2800488\616f6d95-ffa5-4d9d-a1f0-f9e7052cf276.jpg"  xlink:type="simple"/></disp-formula><p>Note that in case when the depth of the maximum gradient is positive, <img src="7-2800488\3657d82b-c0fd-4641-8e11-c41d9682e82d.jpg" />, this point really exists underground, and the gradient first increases, then accepts the maximum value</p><disp-formula id="scirp.33370-formula133313"><label>(A-17)</label><graphic position="anchor" xlink:href="7-2800488\b32c55e0-257f-4dff-a36f-b6abfdfac0e4.jpg"  xlink:type="simple"/></disp-formula><p>Below this point, the gradient begins to decay, and eventually vanishes at the infinite depth. In case when the depth <img src="7-2800488\8a651333-24db-47f4-bd6c-b21c9e13ae42.jpg" /> of the maximum gradient is negative, this point is above the earth surface, and throughout the whole depth range <img src="7-2800488\c43ebd82-d352-4356-a555-7710beffd939.jpg" /> the velocity gradient <img src="7-2800488\c87e48ab-9055-446e-be68-108fdc8029a7.jpg" /> is actually a monotonously decreasing function. Note that</p><disp-formula id="scirp.33370-formula133314"><label>(A-18)</label><graphic position="anchor" xlink:href="7-2800488\1c623457-f41a-4fe3-80d7-4cc3b50ea7a0.jpg"  xlink:type="simple"/></disp-formula><p>Next we assume the shift<img src="7-2800488\8be60689-64fd-4887-87d0-8f9364bc8747.jpg" />, and pass to the shifted frame,<img src="7-2800488\836b7b71-45cd-4162-b8bd-93a3bfae8814.jpg" />. The gradient accepts now a maximum value at the origin. Rearrange Equation (A- 13),</p><disp-formula id="scirp.33370-formula133315"><label>(A-19)</label><graphic position="anchor" xlink:href="7-2800488\f24c4c5b-d3bb-4ccf-881c-6080861b339e.jpg"  xlink:type="simple"/></disp-formula><p>Note that the velocity profile in Equation (A-19) can be set in an alternative way,</p><disp-formula id="scirp.33370-formula133316"><label>(A-20)</label><graphic position="anchor" xlink:href="7-2800488\94634f2f-4ee7-4a6b-a9f8-45621eabcc3f.jpg"  xlink:type="simple"/></disp-formula><p>where</p><disp-formula id="scirp.33370-formula133317"><label>(A-21)</label><graphic position="anchor" xlink:href="7-2800488\507715bf-38a4-4f2a-9f5d-66d17409bdd8.jpg"  xlink:type="simple"/></disp-formula><p>so that</p><disp-formula id="scirp.33370-formula133318"><label>(A-22)</label><graphic position="anchor" xlink:href="7-2800488\616f8973-ef5b-42ea-a11b-e2642b7021e6.jpg"  xlink:type="simple"/></disp-formula><p>Finally, we eliminate depth from Equation (A-22) and obtain</p><disp-formula id="scirp.33370-formula133319"><label>(A-23)</label><graphic position="anchor" xlink:href="7-2800488\d5eb38ae-e9fb-4e45-8369-a7265e8df4e1.jpg"  xlink:type="simple"/></disp-formula>A.4. The Exponential Asymptotically Bounded Velocity Model (EAB)<p>In this case the velocity profile is</p><disp-formula id="scirp.33370-formula133320"><label>(A-23)</label><graphic position="anchor" xlink:href="7-2800488\d466b44a-0296-4b1f-8728-f900dfe93714.jpg"  xlink:type="simple"/></disp-formula><p>The velocity vanishes above the earth surface at<img src="7-2800488\502fc4a0-f0a9-402e-892e-d474be2c6a6d.jpg" />,</p><disp-formula id="scirp.33370-formula133321"><label>(A-24)</label><graphic position="anchor" xlink:href="7-2800488\419362ea-73ac-44e8-8504-6f86edde5524.jpg"  xlink:type="simple"/></disp-formula><p>In the shifted frame<img src="7-2800488\9d410b6c-8e4f-4302-a144-21c40cc74a72.jpg" />, the velocity profile simplifies to</p><disp-formula id="scirp.33370-formula133322"><label>(A-25)</label><graphic position="anchor" xlink:href="7-2800488\2b6c8fe4-829b-4ae7-afdb-cd463feb5a7a.jpg"  xlink:type="simple"/></disp-formula><p>At the shifted origin the gradient is maximal,</p><disp-formula id="scirp.33370-formula133323"><label>(A-26)</label><graphic position="anchor" xlink:href="7-2800488\cac36328-fdbf-4a2c-b313-204ca6f9ecd3.jpg"  xlink:type="simple"/></disp-formula><p>Introduce Equation (A-26) into (A-25),</p><disp-formula id="scirp.33370-formula133324"><label>(A-27)</label><graphic position="anchor" xlink:href="7-2800488\781d0226-92f5-490f-a27d-9c1bd660d83a.jpg"  xlink:type="simple"/></disp-formula><p>Finally, we eliminate depth from Equation (A-27) and obtain the governing equation,</p><disp-formula id="scirp.33370-formula133325"><label>(A-28)</label><graphic position="anchor" xlink:href="7-2800488\81a9d877-5717-438e-98c0-5b8e46a632f8.jpg"  xlink:type="simple"/></disp-formula><p>Note that only for the EAB velocity model the diagram Equation (A-28) is linear.</p>A.5. Conic Velocity Model<p>For the Conic profile, the velocity and its gradient in the absolute frame are given by</p><disp-formula id="scirp.33370-formula133326"><label>(A-29)</label><graphic position="anchor" xlink:href="7-2800488\2bf9c4d0-4b23-47fb-8c9f-b55d94ab8194.jpg"  xlink:type="simple"/></disp-formula><p>This equation can be rearranged as</p><disp-formula id="scirp.33370-formula133327"><label>(A-30)</label><graphic position="anchor" xlink:href="7-2800488\ba4ad7e0-805d-4824-9dbe-c059830770bd.jpg"  xlink:type="simple"/></disp-formula><p>Next we eliminate the absolute depth <img src="7-2800488\c066a498-5df5-44cd-8510-afaed8a444e8.jpg" /> from Equation (A-29) and get the governing differential equation of the Conic velocity model,</p><disp-formula id="scirp.33370-formula133328"><label>(A-31)</label><graphic position="anchor" xlink:href="7-2800488\3cfe3db1-8230-4875-9e29-53eb023b2b74.jpg"  xlink:type="simple"/></disp-formula><p>The Conic velocity profile, Equation (A-30), can be also set in an equivalent form, through a hyperbolic and an inverse hyperbolic function,</p><disp-formula id="scirp.33370-formula133329"><label>(A-32)</label><graphic position="anchor" xlink:href="7-2800488\f31033f2-0443-4427-b325-b146ae644715.jpg"  xlink:type="simple"/></disp-formula>A.6. Comments on Diagrams<p>Summarize the gradient-velocity diagrams for the five asymptotically bounded velocity models. The governing differential equations are</p><disp-formula id="scirp.33370-formula133330"><label>(A-33)</label><graphic position="anchor" xlink:href="7-2800488\cd95ca09-b508-45fa-b2c3-e4197f17e9a9.jpg"  xlink:type="simple"/></disp-formula><p>The gradient-velocity diagrams for the five asymptotically bounded models are plotted in <xref ref-type="fig" rid="fig7">Figure 7</xref>. Note that in the original frame of reference the asymptotically bounded models are described by the three parameters. As we mentioned, in the shifted frame where the velocity vanishes at the origin (or the vertical gradient accepts a maximum value at the origin), only two parameters are needed. These two parameters may be the maximum gradient <img src="7-2800488\72dbabd6-7517-446d-9a49-b7c0ecf8cfe1.jpg" /> and the asymptotic velocity <img src="7-2800488\1d36547d-4fe5-461f-9e91-18a33233af72.jpg" /> as in Equation Set (A-33). The constant value that appears upon the integration of each equation is not a new parameter as it should be adjusted to match the maximum values <img src="7-2800488\d184b827-d31f-479a-a6fc-d87ab303bceb.jpg" /> and<img src="7-2800488\bac06f95-2f3c-412b-9d91-271eb230236d.jpg" />.</p><p>We emphasize that only for the EAB model the gradient-velocity relationship is linear: Derivative of an exponent is proportional to the same exponent.</p><p>For all models except the Exponential slowness [<xref ref-type="bibr" rid="scirp.33370-ref8">8</xref>], the gradient decreases with the increase of velocity (and depth). In case of the Exponential slowness, the vertical gradient increases along with the velocity, until the velocity reaches one half of the asymptotic value<img src="7-2800488\a2afc9f7-d5d9-4b28-aa2d-e1054036f6b4.jpg" />. At this point the gradient reaches its maximum value <img src="7-2800488\cb362fe8-aec4-4af1-8263-a2a048cea022.jpg" /> and then begins to decrease with depth. The point of maximum gradient in the Exponential slowness model may really exist in the subsurface, or it may be an imaginary point located above the earth surface (or above the upper interface of a layer). This point is real in case when the initial velocity <img src="7-2800488\0d2d322e-9c32-429c-a245-ae3025596351.jpg" /> does not exceed the halflimiting value,<img src="7-2800488\60fab754-0e90-4f65-9f33-9f37f148a107.jpg" />. Furthermore, we comment on the special central symmetry between the two Muscat (1937) models: Hyperbolic (HM) and Exponential (EM), see Equation (A-33) and the two corresponding plots in <xref ref-type="fig" rid="fig7">Figure 7</xref>,</p><disp-formula id="scirp.33370-formula133331"><label>(A-34)</label><graphic position="anchor" xlink:href="7-2800488\b650c985-07b6-4c94-ac19-34967267e27a.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\1a3220b6-dcdf-4642-9626-c6b83e6d1f46.jpg" /> and <img src="7-2800488\704c0e4c-85eb-4caf-8066-40ade6d4cfe9.jpg" /> are the corresponding gradientvelocity functions in Equation (A-33) for these two models. Although these two models are described by essentially different vertical velocity profiles, there is an apparent similarity in the gradient-velocity diagrams.</p></sec><sec id="s17"><title>Appendix B. Lambert Function</title><p>The Lambert function [<xref ref-type="bibr" rid="scirp.33370-ref17">17</xref>] <img src="7-2800488\16309e2c-1466-4a6a-958f-75d63f4acd3b.jpg" />delivers the solution of the transcendent equation</p><disp-formula id="scirp.33370-formula133332"><label>(B-1)</label><graphic position="anchor" xlink:href="7-2800488\37e9a877-82fa-4c83-b7a1-e94dcd4ef163.jpg"  xlink:type="simple"/></disp-formula><p>Its graph is plotted in <xref ref-type="fig" rid="fig8">Figure 8</xref> and consists of two branches: branch zero <img src="7-2800488\444eac19-05cb-48c1-82c7-a43168371b1c.jpg" /> and branch minus one<img src="7-2800488\9b136d58-0613-469e-8d60-200ca338b40e.jpg" />. The argument range is <img src="7-2800488\c7e0c168-597c-465c-9c3b-ab596dc7e9c9.jpg" /> for branch zero and <img src="7-2800488\0ccfe27f-34b2-49d8-9258-d419f600315e.jpg" /> for branch minus one. The value range is <img src="7-2800488\aa6fd932-e00f-454b-9217-b2ddcb78fed2.jpg" /> for branch zero and <img src="7-2800488\5a33ee71-245a-4e7d-85ad-b1e8188bfdf3.jpg" /> for branch minus one. In particular, this</p><p>means that for a positive argument x only branch zero exists, while for a negative argument both branches do exist. Therefore, in the latter case, the branch index should be specified to avoid ambiguity. The derivative of the Lambert function is</p><disp-formula id="scirp.33370-formula133333"><label>(B-2)</label><graphic position="anchor" xlink:href="7-2800488\91fed177-7c34-4c4b-9330-5afaa00a7dad.jpg"  xlink:type="simple"/></disp-formula><p>and for the infinitesimal argument</p><disp-formula id="scirp.33370-formula133334"><label>(B-3)</label><graphic position="anchor" xlink:href="7-2800488\f44b7b74-cce8-46cc-a2cf-8acfa739f2e5.jpg"  xlink:type="simple"/></disp-formula><p>Comment. A general comment is related to Appendices C to F. The transform equations are formulated in the dimensionless form, with the unknown top and bottom asymptotic factors, <img src="7-2800488\bac18b38-bf00-4535-82a3-3af965bd9a4e.jpg" />and<img src="7-2800488\f6cac40f-370b-47e5-bcae-80c42695b352.jpg" />. After the transform equation or equation set is resolved, we apply Equation (27) to find the top and bottom instantaneous velocities, <img src="7-2800488\df20cd95-c39d-49f1-9d25-4b107ac0bd28.jpg" />and<img src="7-2800488\f56b284f-91d5-4626-a1ea-7041d88faa10.jpg" />. If the transform is formulated in depth (i.e., the interval thickness <img src="7-2800488\d3d66e7f-ee29-4f5d-b836-7e17164bc443.jpg" /> is specified), we apply Equation (31) to find the top and bottom gradients of velocity, <img src="7-2800488\c73283f4-7f3e-437b-9548-12fac0ecfd85.jpg" />and<img src="7-2800488\cd2a6e3d-9e6a-4858-889f-2a12eab41c06.jpg" />. If the transform is formulated in time (i.e., the interval traveltime <img src="7-2800488\760ad9b6-7770-4d0c-a0f4-82189eaeffa4.jpg" /> is specified), then we first apply Equation (37) to establish the interval thickness<img src="7-2800488\0b3204ff-d244-4452-8b89-ad65df2512bc.jpg" />, and then Equation (31) to find the top and bottom gradients.</p></sec><sec id="s18"><title>Appendix C. Swapping Interfaces</title><p>In this appendix, we find the instantaneous velocity and its gradient at the bottom interface, given these parameters at the top interface, and vice versa, and consider these problems both vs. depth and vs. time.</p><p>Problem C1. Given the velocity <img src="7-2800488\dc251b12-01ac-4a11-9102-29687fdb1bea.jpg" /> and its gradient <img src="7-2800488\ce4b4972-fa3a-423b-93a0-c602c34b01d8.jpg" /> at the top interface and the layer thickness<img src="7-2800488\ad38fc38-a4e3-4239-bbb4-a52156cda770.jpg" />, one can establish the corresponding parameters at the bottom interface. For this, we calculate the top asymptotic factor <img src="7-2800488\9d9f02cb-9ba6-4555-8649-45755a35c0df.jpg" /> with the first equation of Equation Set (26). The bottom asymptotic factor <img src="7-2800488\95193d65-b0ec-424d-9e7a-e6f93c1cbf49.jpg" /> can be obtained with the first equation of Equation Set (32).</p><p>Problem C2. The instantaneous velocity and its gradient are specified at the bottom interface and the interval thickness <img src="7-2800488\84471250-0fa3-48bb-a58b-6cb23d24fcc9.jpg" /> is given. Velocity and gradient should be found at the top interface. Thus, parameters <img src="7-2800488\4b1ed768-ee77-4d51-992c-4f808549d67a.jpg" /> are given, and parameters <img src="7-2800488\1257dd7c-28d5-4ecb-ad5c-4e6d239bf94b.jpg" /> are to be found. In this case calculate the bottom asymptotic factor <img src="7-2800488\b834850f-5f7d-4f16-9d09-889b70ebd051.jpg" /> with the second equation of Equation Set (26) and apply the second equation of Equation Set (32) to get the top get<img src="7-2800488\85133bc7-1cd3-45ef-b635-f9a5074f8909.jpg" />.</p><p>Problem C3. The velocity and its gradient at the top interface, <img src="7-2800488\ac6139c4-f43d-4306-8c11-7c928f4321b8.jpg" />and <img src="7-2800488\ea746e0f-a8bd-4edf-bfa0-06effa43dd02.jpg" /> are given, the interval traveltime <img src="7-2800488\b890de7b-7081-4061-9125-6075212223cd.jpg" /> is known, and the bottom interface parameters <img src="7-2800488\2f34a84f-cc72-484d-a122-e5d29c6ca0fc.jpg" /> and <img src="7-2800488\405b5a34-125e-4ee2-83cd-f43d4f77863e.jpg" /> should be found. Combining the first equation of Equation Set (32) and Equation (36), we eliminate the interval thickness <img src="7-2800488\f2ee3556-1cca-484a-b6c2-f337dac06f10.jpg" /> and obtain</p><disp-formula id="scirp.33370-formula133335"><label>(C-1)</label><graphic position="anchor" xlink:href="7-2800488\253985dc-837f-41cd-b192-96c849944d9e.jpg"  xlink:type="simple"/></disp-formula><p>where the top asymptotic factor <img src="7-2800488\25aaa836-e730-4fed-962f-67f06b95e7bf.jpg" /> is known from Equation (26). Equation (C-1) should be solved for the unknown bottom asymptotic factor<img src="7-2800488\65544c6c-8873-4ca8-8838-6dd1aa504668.jpg" />. We use a cubic approximation for Equation (C-1) to get the initial guess, assuming the increment of the asymptotic factor <img src="7-2800488\2b1b5660-39ad-47ee-80cb-c7d841d684d2.jpg" /> is small,</p><disp-formula id="scirp.33370-formula133336"><label>(C-2)</label><graphic position="anchor" xlink:href="7-2800488\c6c29adb-63f8-45ef-ba76-30df9fc2b3d0.jpg"  xlink:type="simple"/></disp-formula><p>Problem C4. The velocity and its gradient are specified at the bottom interface, along with the interval traveltime, and the profile parameters should be found at the top interface. Thus, parameters <img src="7-2800488\c504662c-2a72-48e5-8884-5f8a61cb3f66.jpg" /> and <img src="7-2800488\c5bc93fc-dcb1-481a-8ac0-8ee7e403c03a.jpg" /> are given, while parameters <img src="7-2800488\43dac1bc-e822-4041-9e84-c3539305db3b.jpg" /> and <img src="7-2800488\84faa846-88f7-494b-b2b2-62ae758e4d06.jpg" /> are to be established. For this, we combine the second equation of Equation Set (32) and Equation (36),</p><disp-formula id="scirp.33370-formula133337"><label>(C-3)</label><graphic position="anchor" xlink:href="7-2800488\e5bedf7a-c24a-4ee3-9d3c-d553bbf3eea8.jpg"  xlink:type="simple"/></disp-formula><p>The bottom asymptotic factor <img src="7-2800488\cbe0a33e-59d0-40a1-8cd8-1902be56c3ee.jpg" /> is known from Equation (26), and Equation (C-3) should be solved for the unknown top asymptotic factor<img src="7-2800488\00ee2c0c-64dd-422c-aaeb-37c779cb44b5.jpg" />. The initial guess for <img src="7-2800488\2e12ac25-8467-408b-9167-c4f309bf1626.jpg" /> can be found from</p><disp-formula id="scirp.33370-formula133338"><label>(C-4)</label><graphic position="anchor" xlink:href="7-2800488\46628717-9ceb-455e-8e01-2d3ebe63a156.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s19"><title>Appendix D. Inversion with Instantaneous Velocity</title><p>In this appendix we consider inversion problems that do not involve the effective models (average and RMS velocity). In this inversion group, one or both parameters at the top interface, <img src="7-2800488\43ef551d-a2b6-4c03-9677-903f128e66d9.jpg" />and <img src="7-2800488\46c1d802-fdce-486d-ac12-4d8da75ffd9d.jpg" /> are unknown, with the other data given instead. The group includes four problems vs. depth (interval thickness) and four similar problems vs. interval traveltime.</p><p>Problem D1. Instantaneous velocities vs. depth. Given data are the top and bottom interface instantaneous velocities, <img src="7-2800488\0de75cbd-3e2e-46a3-974c-58db17d7e7e2.jpg" />and<img src="7-2800488\82c7a19f-feca-4730-a074-055e649c8cf1.jpg" />, the asymptotic velocity <img src="7-2800488\04f0a138-e9c3-4a2d-8e73-83f24529a4a3.jpg" /> and the interval thickness<img src="7-2800488\ed3c2bb4-d976-4b15-b5a4-a6b19ea5db04.jpg" />. Find the top interface gradient<img src="7-2800488\60e83d38-332f-481f-9367-95adcc2cb1b1.jpg" />. Solution. Apply Equation (26) to calculate the top and bottom asymptotic factors, <img src="7-2800488\6973e70c-6b41-48d8-9534-15c23119c331.jpg" />and<img src="7-2800488\d0e1ba9d-1ff6-40f4-bf19-fa23ec8d1036.jpg" />.</p><p>Problem D2. Instantaneous velocities vs. time. Given data are the top and bottom interface instantaneous velocities, <img src="7-2800488\13917a2c-db57-46c6-bd1c-f511b5ba04de.jpg" />and<img src="7-2800488\4b558530-cd3d-45dd-bec7-4e56a52897c9.jpg" />, the asymptotic velocity <img src="7-2800488\7bd6ef47-42c9-49ab-a485-660857f74a82.jpg" /> and the interval traveltime<img src="7-2800488\0cf59b98-25bc-499f-8468-781fa4648a43.jpg" />. Find the top interface gradient<img src="7-2800488\e181ba32-ce74-4663-b630-b4e973187d80.jpg" />. Solution. Apply Equation (26) to calculate the top and bottom asymptotic factors, <img src="7-2800488\990434a8-2a81-4213-92ea-e019efaf60ca.jpg" />and<img src="7-2800488\d25a5476-0fb6-40be-ba67-bb4c3667baf2.jpg" />.</p><p>Problem D3. Gradients vs. depth. Given data are the top and bottom interface vertical gradients, <img src="7-2800488\c074ed0a-a6f8-4b42-8b50-60ef5a271593.jpg" />and<img src="7-2800488\23d88c2a-49be-43ad-896c-b18512d5b41b.jpg" />, the asymptotic velocity <img src="7-2800488\190ca97d-710c-49f7-8869-6d773894c211.jpg" /> and the interval thickness<img src="7-2800488\23a43848-e39f-4a22-96bc-cc81a4641ea4.jpg" />. Find the top interface instantaneous velocity<img src="7-2800488\19c205e6-7660-4af3-8557-c41fb6e13beb.jpg" />. Solution. Solve Equation Set (32) for the unknown asymptotic factors, <img src="7-2800488\49b3a570-6e4e-4061-82d6-ea82d2af10cd.jpg" />and<img src="7-2800488\182f3caa-6861-4b58-8936-0516febcbadf.jpg" />,</p><disp-formula id="scirp.33370-formula133339"><label>(D-1)</label><graphic position="anchor" xlink:href="7-2800488\76ee3d4b-1fec-43fc-92c8-679db6aebb3d.jpg"  xlink:type="simple"/></disp-formula><p>Problem D4. Gradients vs. time. Given data are the top and bottom interface vertical gradients, <img src="7-2800488\93e3a967-acc9-413f-9f38-f4ec55b194a3.jpg" />and<img src="7-2800488\fe73a30b-6ca7-42ce-adb1-9d2f4ca660d0.jpg" />, the asymptotic velocity <img src="7-2800488\a577752f-3033-4035-a7a4-89322aae4a0f.jpg" /> and the interval traveltime<img src="7-2800488\512cd283-db45-4021-8b30-0c736f8a9e1d.jpg" />. Find the top interface instantaneous velocity<img src="7-2800488\c76f98cf-0b56-4caa-8c28-4ecfde74c179.jpg" />. Solution. Introduce solution (D-1) into the traveltime Equation (36). This leads to a nonlinear equation vs. the unknown interval thickness <img src="7-2800488\36c7a7e6-a756-4cf9-9c74-66b6658ce960.jpg" /></p><disp-formula id="scirp.33370-formula133340"><label>(D-2)</label><graphic position="anchor" xlink:href="7-2800488\becbe9e0-085c-4963-b081-4e2b93a671b1.jpg"  xlink:type="simple"/></disp-formula><p>Equation (D-2) should be solved numerically. It is suitable to normalize the gradients and the interval thickness,</p><disp-formula id="scirp.33370-formula133341"><label>(D-3)</label><graphic position="anchor" xlink:href="7-2800488\11279294-fa73-43eb-b3d8-1687897dc4e8.jpg"  xlink:type="simple"/></disp-formula><p>The normalized equation becomes</p><disp-formula id="scirp.33370-formula133342"><label>(D-4)</label><graphic position="anchor" xlink:href="7-2800488\686c481c-6918-4d1e-83eb-5c26cd5a01f3.jpg"  xlink:type="simple"/></disp-formula><p>To get an initial guess, we expand Equation (D-4) into a power series and obtain a cubic approximation,</p><disp-formula id="scirp.33370-formula133343"><label>(D-5)</label><graphic position="anchor" xlink:href="7-2800488\22870ca0-e2df-4fe7-8330-153992e18a46.jpg"  xlink:type="simple"/></disp-formula><p>After the interval thickness is found, apply solution (D-1).</p><p>Problem D5. Velocity and gradient vs. depth at different interfaces. Given data are the top interface velocity<img src="7-2800488\323106a3-fa8f-4b35-8189-70284aa95b68.jpg" />, the bottom interface vertical gradient<img src="7-2800488\ae61cf08-85e7-4ebf-8e33-9f668d412e42.jpg" />, the asymptotic velocity <img src="7-2800488\b97aaa4c-70ea-462a-a406-10afa40f1abe.jpg" /> and the interval thickness<img src="7-2800488\ae8144d0-e859-4fda-80fe-eaa21a293e80.jpg" />. Find the top interface gradient<img src="7-2800488\01d72ddf-d8b3-4713-939f-07b69f67d6f3.jpg" />. Solution. Apply Equation (26) to calculate the top asymptotic factor<img src="7-2800488\b4c7cc94-1fa1-4e6b-80e2-ceb0eb33fd9e.jpg" />. Introduce the normalized bottom gradient,</p><disp-formula id="scirp.33370-formula133344"><label>(D-6)</label><graphic position="anchor" xlink:href="7-2800488\5ac49586-918a-40c7-8a30-70d752f36a81.jpg"  xlink:type="simple"/></disp-formula><p>With this notation, the second equation of Equation Set (32) becomes</p><disp-formula id="scirp.33370-formula133345"><label>(D-7)</label><graphic position="anchor" xlink:href="7-2800488\fea65c15-8f0b-4465-a43d-d0ef0aa74eb3.jpg"  xlink:type="simple"/></disp-formula><p>Taking into account that for an interval of vanishing thickness <img src="7-2800488\10f326e6-8b82-45be-90b4-abfa8908be21.jpg" /> the top and bottom asymptotic factors coincide<img src="7-2800488\53fe8ada-423d-4e9b-bb3e-d2d8aa69171d.jpg" />, one can establish the single physical root of the quadratic equation,</p><disp-formula id="scirp.33370-formula133346"><label>(D-8)</label><graphic position="anchor" xlink:href="7-2800488\0270d9ee-1e3a-4710-b2f1-417e08429956.jpg"  xlink:type="simple"/></disp-formula><p>Problem D6. Velocity and gradient vs. depth at different interfaces. Given data are the top interface gradient<img src="7-2800488\02930df0-fa52-4ef0-a77a-b8acf8d229fc.jpg" />, the bottom interface instantaneous velocity<img src="7-2800488\0afa2357-2519-4572-929b-88e7a5f5a423.jpg" />, the asymptotic velocity <img src="7-2800488\c5b67f93-f9a5-4bb5-9f75-0254ec98af79.jpg" /> and the interval thickness<img src="7-2800488\0e46497e-644e-4589-9c28-7c360dff5660.jpg" />. Find the top interface velocity<img src="7-2800488\fe0f22c9-1e21-46cc-baac-b015a330729d.jpg" />. Solution. Calculate the bottom asymptotic factor <img src="7-2800488\aa41380e-a7d0-4436-86e7-c52095fbee5d.jpg" /> with equation 26. Normalize the top gradient,</p><disp-formula id="scirp.33370-formula133347"><label>(D-9)</label><graphic position="anchor" xlink:href="7-2800488\ddb68fa0-af3e-444a-ac0b-bf55746b88ef.jpg"  xlink:type="simple"/></disp-formula><p>Get the top asymptotic factor</p><disp-formula id="scirp.33370-formula133348"><label>(D-10)</label><graphic position="anchor" xlink:href="7-2800488\1bfa153d-7725-4394-951d-fac48708d205.jpg"  xlink:type="simple"/></disp-formula><p>Problem D7. Velocity and gradient vs. time at different interfaces. Given data are the top interface velocity<img src="7-2800488\f61295d9-b9a4-449e-85f5-bb0a2c343ec3.jpg" />, the bottom interface vertical gradient<img src="7-2800488\4f36d2cb-f423-4559-aa56-7332b19f0873.jpg" />, the asymptotic velocity <img src="7-2800488\accc254e-34ab-4a8e-b5fd-c05e89720f3b.jpg" /> and the interval traveltime<img src="7-2800488\f9b80e2a-8f9e-4d83-b593-4c7fd13485ef.jpg" />. Find the top interface gradient<img src="7-2800488\800a3fe1-6f05-4b56-a788-7fc085bdb8f3.jpg" />. Solution. Apply Equation (26) to calculate the top asymptotic factor<img src="7-2800488\93f60865-ae50-4c26-8757-76fc734a453d.jpg" />. Then solve the nonlinear Equation (C-3) for the unknown bottom asymptotic factor<img src="7-2800488\29224cf3-ea8a-49b5-a267-2d349a432699.jpg" />. To get the initial guess, we assume<img src="7-2800488\c9b043bd-8aa3-405c-97a1-6a289a876665.jpg" />. Expand Equation (C-3) for a small increment of the asymptotic factor <img src="7-2800488\2bb55ff9-6867-4d88-803d-ddc419f360e1.jpg" /> to get a cubic approximation,</p><disp-formula id="scirp.33370-formula133349"><label>(D-11)</label><graphic position="anchor" xlink:href="7-2800488\1026fc2b-a8b1-45d2-b518-4ab7750fe45e.jpg"  xlink:type="simple"/></disp-formula><p>Problem D8. Given data are the top interface gradient<img src="7-2800488\9b125ea2-8007-40b7-a5bd-59688e70cef2.jpg" />, the bottom interface instantaneous velocity<img src="7-2800488\40669f18-bc1d-45bb-8a35-1d9c92b4b941.jpg" />, the asymptotic velocity <img src="7-2800488\5c2a7999-d94d-494d-8e2e-d2e50842d312.jpg" /> and the interval traveltime<img src="7-2800488\c420dafb-543b-4ebe-b86d-0aea65548f7d.jpg" />. Find the top interface velocity<img src="7-2800488\9b1d11eb-7b22-4374-8122-11b6742db296.jpg" />. Solution. Apply Equation (26) to calculate the bottom asymptotic factor<img src="7-2800488\2cbf05e8-53a7-42ab-9ca6-7209f23130a5.jpg" />. To calculate the unknown top asymptotic factor, we solve the nonlinear Equation (C-1). To get the initial guess, assume<img src="7-2800488\1c738344-85d0-47ae-8bca-108a4d01fcbe.jpg" />. This leads to</p><disp-formula id="scirp.33370-formula133350"><label>(D-12)</label><graphic position="anchor" xlink:href="7-2800488\a5d48f5c-3901-4932-8caf-73604fc2e634.jpg"  xlink:type="simple"/></disp-formula><p>Problem D9. Given data are the instantaneous velocity <img src="7-2800488\c169c999-7d05-46e9-9339-2715c26fd7ba.jpg" /> at the bottom interface, and at an intermediate level inside the interval, <img src="7-2800488\0f14c024-08e5-4f7b-af2c-57a139e1c19d.jpg" />, and the asymptotic velocity<img src="7-2800488\5a53e582-dedd-44d3-8c90-74c10346d32f.jpg" />. Two vertical distances are specified: the full interval thickness <img src="7-2800488\bfb481a1-687b-4605-adac-4a13f1b4c87c.jpg" /> (the distance between the top and bottom interfaces) and the partial interval thickness <img src="7-2800488\03b97c68-5306-422f-b65f-adc6695e44d1.jpg" /> (the distance between the top interface and the intermediate level). Find the top interface velocity and gradient, <img src="7-2800488\3074dffc-ac8d-4808-9400-05bcd0867bb3.jpg" />and<img src="7-2800488\7529101c-32fc-4e08-902f-37d5b7bef862.jpg" />. Solution. Use Equation (26) to calculate the bottom asymptotic factor <img src="7-2800488\14514cc2-1f43-4054-b3b0-0b14885d9341.jpg" /> and the intermediate asymptotic factor<img src="7-2800488\d1df64c6-7f1d-488d-bdcb-de5f742a42cc.jpg" />. Apply Equation (29) for the full interval and for the partial interval,</p><disp-formula id="scirp.33370-formula133351"><label>(D-13)</label><graphic position="anchor" xlink:href="7-2800488\0b62553c-95c9-47bd-92d9-d5c7101d9e88.jpg"  xlink:type="simple"/></disp-formula><p>Solve Equation (D-13) for the top asymptotic factor<img src="7-2800488\685ee9a6-2a5c-4189-a172-0be23d8100e2.jpg" />,</p><disp-formula id="scirp.33370-formula133352"><label>(D-14)</label><graphic position="anchor" xlink:href="7-2800488\bd0852a6-487c-4098-8e67-c28c655eba0e.jpg"  xlink:type="simple"/></disp-formula><p>Problem D10. Given data are the instantaneous velocity <img src="7-2800488\e9cbbeef-aaa9-4972-b220-77598bbe521f.jpg" /> at the bottom interface, and at an intermediate level <img src="7-2800488\ddd2aa52-f31d-4925-9838-f21dcb773a4c.jpg" /> inside the interval, and the asymptotic velocity<img src="7-2800488\8552c4a7-0ef1-4002-bdd5-317a6907e09e.jpg" />. Two vertical traveltimes are specified: the full interval traveltime <img src="7-2800488\dd6f9494-3c95-4d9a-a03a-ab8dac79c563.jpg" /> (the traveltime between the top and bottom interfaces) and the partial traveltime <img src="7-2800488\99580003-ba8a-4d7f-9a6f-19422a8eeae5.jpg" /> (the traveltime between the top interface and the intermediate level). Find the top interface velocity and gradient, <img src="7-2800488\af61cc99-c57d-4eb0-80d6-9ea560d397b8.jpg" />and<img src="7-2800488\2a972a17-db91-4f3d-aed0-a189417e0e08.jpg" />. Solution. Use Equation (26) to calculate the bottom asymptotic factor <img src="7-2800488\7824bc23-5383-4653-b5d5-46b02b7b984f.jpg" /> and the intermediate asymptotic factor<img src="7-2800488\26627a7f-82e2-4f01-9bb7-fe8bcdbf8895.jpg" />. Apply Equation (28) for the full interval and for the partial interval, parameter <img src="7-2800488\ae6872d0-ad8b-4490-8cb2-e975ae1348aa.jpg" /> becomes,</p><disp-formula id="scirp.33370-formula133353"><label>(D-15)</label><graphic position="anchor" xlink:href="7-2800488\23718b34-0d7a-4194-9bdd-5d7fced58306.jpg"  xlink:type="simple"/></disp-formula><p>Introduce parameter<img src="7-2800488\b9df3827-4f3f-4dc5-b330-23a4f98994bb.jpg" />, Equation (D-15) becomes</p><disp-formula id="scirp.33370-formula133354"><label>(D-16)</label><graphic position="anchor" xlink:href="7-2800488\d8bbc537-18ff-4f9a-a916-7c2d6baf64ee.jpg"  xlink:type="simple"/></disp-formula><p>Equation (D-16) can be solved with the Lambert function, branch zero,</p><disp-formula id="scirp.33370-formula133355"><label>(D-17)</label><graphic position="anchor" xlink:href="7-2800488\f8302cec-3e74-4740-9b0f-982f94e4ccb7.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s20"><title>Appendix E. Two-Point Effective Model Inversion</title><p>In this appendix we consider the two-point (single-interval) inversion where the RMS velocity is specified at the interfaces of an interval vs. depth or traveltime, or alternatively, depth is specified vs. traveltime instead of the RMS velocity. One of the two parameters at the top interface-either the top velocity<img src="7-2800488\bd2fc184-6478-4b76-bbce-c61518e57d7a.jpg" />, or the top gradient <img src="7-2800488\419a16a3-4b1b-4431-b10e-21538cfa4e4a.jpg" />-is a known value, while the other one is unknown and should be established. In all cases, the asymptotic velocity <img src="7-2800488\b564b962-28f6-4fee-b8fe-fc36fd1047f6.jpg" /> and the top interface absolute traveltime <img src="7-2800488\64d59369-8393-4cb3-8c64-5706bce728e5.jpg" /> are assumed known values. We consider also a special case when the RMS velocity is specified vs. both depth and time, and both parameters, <img src="7-2800488\558683c3-7fbd-4921-b3e9-d1a21d1500e9.jpg" />and<img src="7-2800488\891aa141-132b-416a-b8e7-e4c22807e72e.jpg" />, are unknown.</p><p>Problem E1. RMS vs. depth with unknown gradient. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\94ca3cb7-34d5-4f05-8a6d-43848d039bf9.jpg" />and<img src="7-2800488\2ba46ee0-543b-4e8c-881c-0a937f1b1b77.jpg" />, the interval thickness <img src="7-2800488\2b8e5cb3-c34b-4a70-a7d1-260490f12f74.jpg" /> and the top interface velocity<img src="7-2800488\93e182b9-5903-4567-a5b9-3b68e0b96990.jpg" />. Find the top gradient<img src="7-2800488\67c3374b-fd69-4a84-8d4c-f4f35307056e.jpg" />. Solution. It follows from the definition of the hyperbolic parameter, Equation (44),</p><disp-formula id="scirp.33370-formula133356"><label>(E-1)</label><graphic position="anchor" xlink:href="7-2800488\170e6a5a-66c4-47ec-9945-4168e2be2498.jpg"  xlink:type="simple"/></disp-formula><p>Recall that <img src="7-2800488\6cdbd900-04b1-44ba-a63a-46288271ca0d.jpg" /> and <img src="7-2800488\da15026d-6a45-4afc-9df1-5f0ccb20f7d8.jpg" /> are one-way absolute top and bottom interface traveltimes (measured from the earth surface), <img src="7-2800488\94070d81-1261-4879-af73-d9816ec594ba.jpg" />is the one-way interval traveltime, and W is the hyperbolic parameter through the interval. Equation (E-1) can be arranged as</p><disp-formula id="scirp.33370-formula133357"><label>(E-2)</label><graphic position="anchor" xlink:href="7-2800488\1611ccdd-a818-4735-8a55-3ecba1c8ef0c.jpg"  xlink:type="simple"/></disp-formula><p>Introduction of Equation (37) for the traveltime <img src="7-2800488\a760d4d0-c29c-49aa-bb88-c16639670508.jpg" /> and Equation (47) for the hyperbolic parameter W into Equation (E-2) results in</p><disp-formula id="scirp.33370-formula133358"><label>(E-3)</label><graphic position="anchor" xlink:href="7-2800488\4438f62e-f634-451b-bb7c-4929425eadbb.jpg"  xlink:type="simple"/></disp-formula><p>where A and B are known dimensionless parameters,</p><disp-formula id="scirp.33370-formula133359"><label>(E-4)</label><graphic position="anchor" xlink:href="7-2800488\df14253e-67e9-416f-9415-b0f778b996c2.jpg"  xlink:type="simple"/></disp-formula><p>The top asymptotic factor <img src="7-2800488\97d67f46-6b45-4fb8-9fab-c1e079446199.jpg" /> is delivered by Equation (26), and the nonlinear Equation (E-4) should be solved for the unknown bottom asymptotic factor<img src="7-2800488\ebacccf6-ba4e-498e-920e-d6aeb7dc1120.jpg" />. To get the initial guess, we assume a small increment of the asymptotic factor on the interval, <img src="7-2800488\7abcb1ef-ce5c-4c2a-8b11-2b70a2b62a62.jpg" />, and expand Equation (E-3) into a power series. The cubic approximation reads</p><disp-formula id="scirp.33370-formula133360"><label>(E-5)</label><graphic position="anchor" xlink:href="7-2800488\78af8642-ff81-44fc-a028-92f64f5f65cf.jpg"  xlink:type="simple"/></disp-formula><p>where</p><disp-formula id="scirp.33370-formula133361"><label>(E-6)</label><graphic position="anchor" xlink:href="7-2800488\244b29ae-c8e1-454e-96e5-bfa0fa267181.jpg"  xlink:type="simple"/></disp-formula><p>Equation (E-3) should be solved for<img src="7-2800488\c03b7ed8-f02b-493a-a61e-fd61be118176.jpg" />.</p><p>Problem E2. RMS vs. depth with unknown velocity. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\655fc71e-1ab2-47bb-825c-07330d160aa2.jpg" />and<img src="7-2800488\4c38431c-bd30-4d2c-a5cb-0fd3cfb05446.jpg" />, the interval thickness <img src="7-2800488\0a765347-67c8-4d7d-9529-ba6f8cf9bbf9.jpg" /> and the top interface gradient<img src="7-2800488\82043c8b-d6de-46d4-97d9-c379e973cd36.jpg" />. Find the top interface velocity<img src="7-2800488\848b0110-5f3f-4b0e-b714-ce06ab239775.jpg" />. Solution. Use Equation (E-3) and the first equation of Equation Set (32),</p><disp-formula id="scirp.33370-formula133362"><label>(E-7)</label><graphic position="anchor" xlink:href="7-2800488\f8918b99-fbb8-489c-8dcd-1b4e2dd5e22c.jpg"  xlink:type="simple"/></disp-formula><p>We solve Equation Set (E-7) for the unknown asymptotic factors <img src="7-2800488\ca9f8974-3c8c-4dba-bde2-14e0b96b39e2.jpg" /> and<img src="7-2800488\2f928d3a-f112-4c0c-86a8-262906f547ba.jpg" />. To obtain the initial guess for<img src="7-2800488\bb9df6ca-d4d3-477f-96fc-f0edfe5ca6b6.jpg" />, assume that the increment of the asymptotic factor <img src="7-2800488\0d61b40a-1940-43bf-a147-7ac1733e5797.jpg" /> is small, and linearize Equation Set (E-7). This leads to</p><disp-formula id="scirp.33370-formula133363"><label>(E-8)</label><graphic position="anchor" xlink:href="7-2800488\737b0c42-0213-4d2d-9f1b-15aab327b50d.jpg"  xlink:type="simple"/></disp-formula><p>Problem E3. RMS vs. time with unknown gradient. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\69d95a48-dbaa-4157-a1f7-595a44c09490.jpg" />and<img src="7-2800488\99859960-0e68-435c-8fed-74aebcf7cdce.jpg" />, the interval traveltime <img src="7-2800488\8348dd7d-09bb-416e-bc98-77ed135a179a.jpg" /> and the top interface velocity<img src="7-2800488\c4da6cc6-5da4-4b4f-bfcb-425fc7a0aa3f.jpg" />. Find the top gradient<img src="7-2800488\13bf92ea-d2a0-4f9e-aab1-9e342b28218b.jpg" />. Solution. First we apply Equation (E-1) and calculate the hyperbolic parameter W. At this time, W is a known value. Next we apply Equation (48),</p><disp-formula id="scirp.33370-formula133364"><label>(E-9)</label><graphic position="anchor" xlink:href="7-2800488\02163b86-28b8-499c-b03e-a2d24228a917.jpg"  xlink:type="simple"/></disp-formula><p>where C is a known dimensionless parameter, the normalized local RMS velocity,</p><disp-formula id="scirp.33370-formula133365"><label>(E-10)</label><graphic position="anchor" xlink:href="7-2800488\dc3733e1-a060-4b68-9626-352ff3f0c2f9.jpg"  xlink:type="simple"/></disp-formula><p>and U is the non-normalized local RMS velocity on the interval. The top asymptotic factor <img src="7-2800488\858bae28-a2f8-498c-bda0-0b67b565bd0c.jpg" /> is delivered by Equation (26), and the bottom asymptotic factor <img src="7-2800488\ba30342c-8a5b-4d34-b084-64e6a59b6be3.jpg" /> is established from Equation (E-9). To solve this nonlinear equation, an initial guess is needed. Assume that the increment of the asymptotic factor <img src="7-2800488\aceb464d-7270-4bc6-a55b-3de9b2650b67.jpg" /> on the interval is small, and expand Equation (E-9) into a power series. The cubic approximation reads</p><disp-formula id="scirp.33370-formula133366"><label>(E-11)</label><graphic position="anchor" xlink:href="7-2800488\73dfb60b-530c-4ac6-bed3-95a8e48dd7e6.jpg"  xlink:type="simple"/></disp-formula><p>Problem E4. RMS vs. time with unknown velocity. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\92331163-86d7-4640-96a8-a40c5e307d36.jpg" />and<img src="7-2800488\176d2a04-0c44-4bea-a3b8-d5089a3748c7.jpg" />, the interval traveltime <img src="7-2800488\3abc6802-8583-41c6-814b-ccfde9845a01.jpg" /> and the top interface gradient<img src="7-2800488\095faedc-db9f-4efd-9793-74147086f3b7.jpg" />. Find the top interface velocity<img src="7-2800488\612e0dc9-be2d-43b9-a7c4-5eead891ba5c.jpg" />. Solution. We solve a set consisting of two equations: the first is Equation (E-9) combined with Equation (C-1), and the second is (C-1) itself,</p><disp-formula id="scirp.33370-formula133367"><label>(E-12)</label><graphic position="anchor" xlink:href="7-2800488\6ba0b5b4-42cd-4421-a5d7-3cc9b2e2a6a2.jpg"  xlink:type="simple"/></disp-formula><p>To get the initial guess, we linearize Equation Set (E- 12) for a small increment of the asymptotic factor <img src="7-2800488\81ab7db2-ed72-43f3-b468-d4d10d9671ad.jpg" /> and obtain</p><disp-formula id="scirp.33370-formula133368"><label>(E-13)</label><graphic position="anchor" xlink:href="7-2800488\adff5c4c-38e0-4fee-b42d-19590fcedeac.jpg"  xlink:type="simple"/></disp-formula><p>Problem E5. Depth vs. time with unknown gradient. Given data are the interval thickness<img src="7-2800488\437b2453-1a7d-40cc-9930-15c6d7b03692.jpg" />, the traveltime <img src="7-2800488\6184e8ea-4060-4bf2-a4c2-160db5c82b80.jpg" /> and the top interface velocity<img src="7-2800488\99295a05-d8f3-407c-a647-d4a9ae0e30d4.jpg" />. Find the top gradient<img src="7-2800488\4f5d5dd6-6b11-4c1a-8942-d0bef6a5817d.jpg" />. Solution. Use Equation (26) to find the top asymptotic factor<img src="7-2800488\f7fb8a0d-a96e-4f2b-a128-0c4a83e57692.jpg" />. Next we apply Equation (37) to establish the bottom asymptotic factor <img src="7-2800488\8d0109f8-bf2b-4a53-9118-32ae87272f6e.jpg" /></p><disp-formula id="scirp.33370-formula133369"><label>(E-14)</label><graphic position="anchor" xlink:href="7-2800488\3006aa05-dcdf-4d18-9eda-7e52ababf024.jpg"  xlink:type="simple"/></disp-formula><p>where D is a known dimensionless parameter—the normalized interval velocity,</p><disp-formula id="scirp.33370-formula133370"><label>(E15)</label><graphic position="anchor" xlink:href="7-2800488\d12d6ec6-fb0a-4818-afcc-4f59c6ea7498.jpg"  xlink:type="simple"/></disp-formula><p>To get the initial guess for Equation (E-14), we expand it into a power series for a small increment of the asymptotic factor<img src="7-2800488\49e7cfae-e442-4baf-8909-6e0b8651b26a.jpg" />,</p><disp-formula id="scirp.33370-formula133371"><label>(E-16)</label><graphic position="anchor" xlink:href="7-2800488\75569a77-9dee-4271-8051-2d7c3208456d.jpg"  xlink:type="simple"/></disp-formula><p>Equation (E-14) should be solved for the bottom asymptotic factor<img src="7-2800488\d25deab4-a627-49dd-90e7-e0e1e3c70e88.jpg" />.</p><p>Problem E6. Depth vs. time with unknown velocity. Given data are the interval depth<img src="7-2800488\ee0222d0-36bf-4a05-91a1-29c36acfb940.jpg" />, the interval traveltime <img src="7-2800488\b8d138e0-fc4c-4df8-a97c-65f4403f1fb2.jpg" /> and the top interface gradient<img src="7-2800488\caf72745-da83-435d-b76f-82613643bf3c.jpg" />. Find the top interface velocity<img src="7-2800488\94ec9e23-1221-43ba-a305-a74d239eab7a.jpg" />. Solution. Apply Equation (E-14) and the first equation of Equation Set (32),</p><disp-formula id="scirp.33370-formula133372"><label>(E-17)</label><graphic position="anchor" xlink:href="7-2800488\c759033e-b6e1-45e6-bb9c-04b9fef3bda1.jpg"  xlink:type="simple"/></disp-formula><p>Next we solve Equation Set (E-17) for the unknown asymptotic factors <img src="7-2800488\6e418daf-5f9a-4529-b55a-a685a710c2db.jpg" /> and<img src="7-2800488\530a905d-4dbb-4fa0-b6f5-0e9cc749e861.jpg" />. To obtain the initial guess, we linearize Equation Set (E-17) for a small increment of the asymptotic factor<img src="7-2800488\0d4c3d85-5153-4143-9a97-8adf4e4d56b6.jpg" />, and consider the first equation of the set,</p><disp-formula id="scirp.33370-formula133373"><label>(E-18)</label><graphic position="anchor" xlink:href="7-2800488\30519ff3-8b83-45ae-809e-f145a28289dc.jpg"  xlink:type="simple"/></disp-formula><p>Hence we obtain the initial guess for the top asymptotic factor<img src="7-2800488\f5b5d908-d5e3-45a3-8f56-96fc0b470b99.jpg" />,</p><disp-formula id="scirp.33370-formula133374"><label>(E-19)</label><graphic position="anchor" xlink:href="7-2800488\ceaaf2d0-39ad-4bf5-987e-a0d5e639166c.jpg"  xlink:type="simple"/></disp-formula><p>Problem E7. RMS vs. depth and time with unknown velocity and gradient. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\7024bf1d-f3cc-4fd3-b9d0-8cc74813ae4f.jpg" />and<img src="7-2800488\2ac08fa5-793a-4d9a-83c3-12370dd5da87.jpg" />, the interval traveltime <img src="7-2800488\6d9d0d81-ab85-4faf-9d27-6b096b4b8a1d.jpg" /> and the interval thickness<img src="7-2800488\6a7e089f-2f93-46c3-878f-fa97b87f4f01.jpg" />. Find the top interface velocity <img src="7-2800488\cb920afd-e8bf-49b7-b3a5-1e92bd351534.jpg" /> and gradient<img src="7-2800488\4623fa20-18bc-4d45-8ebe-00ed6d783cdc.jpg" />. Solution. The resolving set follows from Equations (E-9) and (E-14),</p><disp-formula id="scirp.33370-formula133375"><label>(E-20)</label><graphic position="anchor" xlink:href="7-2800488\c311374a-caaa-4d38-8f4e-2a524dceb5fe.jpg"  xlink:type="simple"/></disp-formula><p>where A and B are known dimensionless parameters,</p><disp-formula id="scirp.33370-formula133376"><label>(E-21)</label><graphic position="anchor" xlink:href="7-2800488\29aa39a2-9b29-4ce4-80c1-5e4994dc6ed2.jpg"  xlink:type="simple"/></disp-formula><p>To obtain the initial guess, we assume that the top and bottom values of the asymptotic factor, <img src="7-2800488\dc15ed20-1197-4e6d-b64b-0a8bf29ea78c.jpg" />and<img src="7-2800488\07f0af87-e7a3-4e23-a514-66b555454d14.jpg" />, are close, and solve the two equations of Equation Set (E-20) apart. Each equation yields a root; the smaller root is the top asymptotic factor<img src="7-2800488\eed18680-7502-4c7b-849b-a4ffd2bf09cd.jpg" />, and the larger root is the bottom asymptotic factor<img src="7-2800488\2fc2e79e-8828-41e0-ab42-bea183272ebf.jpg" />. The initial guess becomes</p><disp-formula id="scirp.33370-formula133377"><label>(E-22)</label><graphic position="anchor" xlink:href="7-2800488\e017d36a-dc32-48b9-89b8-fc0eb6989dfb.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s21"><title>Appendix F. Three-Point Inversion</title><p>In this appendix we consider three problems where the RMS velocity is given at the interfaces and at an intermediate (inner) point of the interval vs. depth or time, or depth is given vs. time at the interfaces and at an intermediate point, and both parameters of the velocity profile, <img src="7-2800488\eb06a1b5-9d27-4888-8001-0900717fdfc6.jpg" />and<img src="7-2800488\db31117a-b12c-4525-8f72-e445e85cf646.jpg" />, are unknown.</p><p>Problem F1. RMS vs. depth with the unknown top interface velocity <img src="7-2800488\3bccdf03-76b8-434f-9957-13f7156ec377.jpg" /> and top gradient<img src="7-2800488\e8f924e9-0ca4-418a-a5e7-fe77f9a54e1f.jpg" />. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\e9b2ed5d-aa5b-4514-b9b3-acb73bdae2cb.jpg" />and<img src="7-2800488\0acd5474-6f7f-4e5c-9562-b3e6d6d9acd0.jpg" />, and the RMS velocity at the inner point of the interval, <img src="7-2800488\df6df435-aaf1-4ac8-aa0b-b1cfbd2535a5.jpg" />, the full interval thickness <img src="7-2800488\1d5014af-801e-4cbd-910a-162cdc59b203.jpg" /> (between the top and bottom interfaces) and the partial thickness <img src="7-2800488\8c6c8738-6c9d-4bbf-b949-4df09a3d22c4.jpg" /> (between the top interface and the intermediate level). Find the top velocity <img src="7-2800488\c6f82e48-9c8f-4ec2-9de0-d339f3843cb2.jpg" /> and the gradient<img src="7-2800488\3ca55030-cfe0-404c-a19e-b6c7bb162c73.jpg" />. Solution. The resolving equation set follows from Equation (E-3),</p><disp-formula id="scirp.33370-formula133378"><label>(F-1)</label><graphic position="anchor" xlink:href="7-2800488\117c458e-2f2b-4e08-a95f-ec4074d77ee9.jpg"  xlink:type="simple"/></disp-formula><p>Coefficients <img src="7-2800488\372f428b-1fd8-432c-9d17-4cb7a8541c5b.jpg" /> and <img src="7-2800488\abe75f83-ccf9-4206-9e52-adb5a103e673.jpg" /> are known values; they follow from Equation (E-4),</p><disp-formula id="scirp.33370-formula133379"><label>(F-2)</label><graphic position="anchor" xlink:href="7-2800488\05449b84-d7e3-440f-bece-1ff4ae45a85f.jpg"  xlink:type="simple"/></disp-formula><p>where the asymptotic factors <img src="7-2800488\942dc758-877e-4e9d-a800-54640f1ec179.jpg" /> and <img src="7-2800488\473e563a-c86a-4d59-8b87-e482bbc624ea.jpg" /> are to be found,</p><disp-formula id="scirp.33370-formula133380"><label>(F-3)</label><graphic position="anchor" xlink:href="7-2800488\fd72d459-1345-4f15-ab4a-52a6546577f4.jpg"  xlink:type="simple"/></disp-formula><p>It follows from Equation (32),</p><disp-formula id="scirp.33370-formula133381"><label>(F-4)</label><graphic position="anchor" xlink:href="7-2800488\1570ac4f-573e-4be2-a52a-e4babeff0a1f.jpg"  xlink:type="simple"/></disp-formula><p>Divide the second equation of Equation Set (F-4) over its first equation,</p><disp-formula id="scirp.33370-formula133382"><label>(F-5)</label><graphic position="anchor" xlink:href="7-2800488\e837f211-5042-48c1-a40e-1c9bb0e0b904.jpg"  xlink:type="simple"/></disp-formula><p>Thus, we solve Equation Set (F-1) together with Equation (F-5), to obtain the three unknown asymptotic factors. To obtain the initial guess, we assume that the layer is thin, i.e. that the differences in the asymptotic factors <img src="7-2800488\8abacdbb-4fea-4c25-b854-24a0959e2282.jpg" /> and <img src="7-2800488\68098460-ebb8-42e3-ac49-efc7f7599394.jpg" /> are small. This assumption allows linearization of Equation Set (F-1), which, in turn, results in</p><disp-formula id="scirp.33370-formula133383"><label>(F-6)</label><graphic position="anchor" xlink:href="7-2800488\c707aa5d-83f6-45f0-a155-956fb4a37d06.jpg"  xlink:type="simple"/></disp-formula><p>Introduction of solution (F-6) into Equation (F-5) leads to a fourth order polynomial equation for the top interface asymptotic factor<img src="7-2800488\e300d791-5ab4-4ab1-a7e2-6fdcf0cce7f6.jpg" />,</p><disp-formula id="scirp.33370-formula133384"><label>(F-7)</label><graphic position="anchor" xlink:href="7-2800488\71980e55-b807-45ea-bb54-63f63c5f0655.jpg"  xlink:type="simple"/></disp-formula><p>We solve Equation (F-7), choose a proper root, and this yields the initial guess for<img src="7-2800488\8ac79973-18ad-4235-8da4-ba991332378d.jpg" />. Then we use Equation (F-6) to obtain the initial guess for <img src="7-2800488\d8e3fd3a-cf3c-43d3-86b9-47954ed95001.jpg" /> and<img src="7-2800488\a8bda17d-d78d-41c4-988c-8fd8829edb42.jpg" />. Next we solve Equation Set (F-1), (F-5) numerically.</p><p>Problem F2. RMS vs. time with the unknown top interface velocity <img src="7-2800488\ca6ad67a-bf3b-449d-8809-93a8cd181eab.jpg" /> and top gradient<img src="7-2800488\c29faa81-0547-4f3b-ac55-bfe1fa921df6.jpg" />. Given data are the RMS velocities at the top and bottom interfaces, <img src="7-2800488\d108391b-b074-4c67-9791-cb0f4cd703e6.jpg" />and<img src="7-2800488\3511026d-0dde-482a-9812-0f14c3f8a5fd.jpg" />, and at the inner point of the interval, <img src="7-2800488\3f6da529-1ea7-41cd-ae23-523b5fc46bfa.jpg" />, the full interval traveltime <img src="7-2800488\ec1f981e-9a1d-40e7-bdc1-9e493c84afdf.jpg" /> (between the top and bottom interfaces) and the partial traveltime <img src="7-2800488\0970c0ac-809a-49e0-b3cf-52cda3dad7c9.jpg" /> (between the top interface and the intermediate level). Find the top velocity <img src="7-2800488\e209ae40-9067-4a17-992b-a51340b35317.jpg" /> and the gradient<img src="7-2800488\da942711-6b43-434b-8a94-7f328286eff8.jpg" />. Solution. The resolving equation set follows from Equation (E-8),</p><disp-formula id="scirp.33370-formula133385"><label>(F-8)</label><graphic position="anchor" xlink:href="7-2800488\0d60da1a-74fd-471d-bf7a-e749beee8d6a.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\7545ce43-6b00-4d53-bfb2-72bdcbabde3d.jpg" /> and <img src="7-2800488\e5753344-a916-4c73-9b3b-89e1991d9d1b.jpg" /> are the normalized local RMS velocities, for the partial interval and the full interval, respectively. These are the known dimensionless values,</p><disp-formula id="scirp.33370-formula133386"><label>(F-9)</label><graphic position="anchor" xlink:href="7-2800488\a563ba5f-5c05-4813-bd09-486be3d783a6.jpg"  xlink:type="simple"/></disp-formula><p>We make use of Equation (D-14),</p><disp-formula id="scirp.33370-formula133387"><label>(F-10)</label><graphic position="anchor" xlink:href="7-2800488\5e2769a9-cab6-44e0-88c6-82dfcb8f5627.jpg"  xlink:type="simple"/></disp-formula><p>and solve Equation Set (F-8) numerically along with Equation (F-10). To obtain the initial guess, we assume that the layer is thin, and thus, we linearize Equation Set (F-8) for the small variations of the asymptotic factor, <img src="7-2800488\e76da735-a569-435c-8701-5b5c093d6949.jpg" />and<img src="7-2800488\0ed38fca-34d1-40ee-a777-6e71c442355f.jpg" />,</p><disp-formula id="scirp.33370-formula133388"><label>(F-11)</label><graphic position="anchor" xlink:href="7-2800488\bb5c1c7e-508f-4d55-a53a-b8550feda191.jpg"  xlink:type="simple"/></disp-formula><p>Note that for the small increments of the asymptotic factor</p><disp-formula id="scirp.33370-formula133389"><label>(F-12)</label><graphic position="anchor" xlink:href="7-2800488\583337c2-b7ff-4399-8b06-b4c5ebe4bb95.jpg"  xlink:type="simple"/></disp-formula><p>Linearization of Equation (F-10) leads to</p><disp-formula id="scirp.33370-formula133390"><label>(F-13)</label><graphic position="anchor" xlink:href="7-2800488\b7f64680-ba13-4a16-acdf-e36a714ffcd6.jpg"  xlink:type="simple"/></disp-formula><p>Equation (F-13) is similar to (F-5); however, (F-5) is exact and valid for any layer thickness, while (F-13) is an approximation for a thin layer only. Introduction of (F-13) into (F-11) results in a quadratic equation,</p><disp-formula id="scirp.33370-formula133391"><label>(F-14)</label><graphic position="anchor" xlink:href="7-2800488\cee9a95c-3b12-43d1-9a92-9172a43fed56.jpg"  xlink:type="simple"/></disp-formula><p>The equation has two positive roots, but only one of them exceeds 1. The solution is</p><disp-formula id="scirp.33370-formula133392"><label>(F-15)</label><graphic position="anchor" xlink:href="7-2800488\252c4c06-945e-47c3-93df-820c13c31f88.jpg"  xlink:type="simple"/></disp-formula><p>Next we apply Equation (F-11) to obtain the initial guess for <img src="7-2800488\25198fc9-cba3-4e99-9ab8-d63d025cc40d.jpg" /> and<img src="7-2800488\e14c8eeb-6eb5-4e51-83c7-3a7cdcc973f9.jpg" />. Then we solve Equation Set (F-8), (F-10) numerically and deliver the three asymptotic factors.</p><p>Problem F3. Depth vs. time with the unknown top interface velocity <img src="7-2800488\d7157e4d-550e-47e5-a87c-4f29b287324e.jpg" /> and top gradient<img src="7-2800488\ff97f533-2e24-4d72-8c8b-5c69c0d58a8b.jpg" />. Given data are the traveltime and layer thickness for the full and the partial intervals, respectively: <img src="7-2800488\e2495846-34be-4a41-ad8a-278b4628aafb.jpg" />and<img src="7-2800488\7f19f03d-80df-4300-baee-59b29ec26128.jpg" />. Find the top velocity <img src="7-2800488\458aa0b0-554c-4e22-91df-c626fb248ed4.jpg" /> and the gradient<img src="7-2800488\93c82793-4092-4cf7-834f-b10db376187b.jpg" />. Solution. The resolving equation set follows from Equation (E-14),</p><disp-formula id="scirp.33370-formula133393"><label>(F-16)</label><graphic position="anchor" xlink:href="7-2800488\4386bcff-9e67-41ed-af28-b3f1fdf7c8c3.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="7-2800488\407192c6-fdb3-4f68-a03e-c690220d90d7.jpg" /> and <img src="7-2800488\6ffc777d-a8a3-4033-8c7e-a57dae02fd59.jpg" /> are the normalized interval velocities for the full and the partial intervals,</p><disp-formula id="scirp.33370-formula133394"><label>(F-17)</label><graphic position="anchor" xlink:href="7-2800488\9c89e5fc-03c4-454b-afbf-7681ec12fc5f.jpg"  xlink:type="simple"/></disp-formula><p>Equation Set (F-16) should be solved numerically along with Equation (F-5). To obtain the initial guess, we linearize Equation Set (F-16) for the small increments of the asymptotic factors,</p><disp-formula id="scirp.33370-formula133395"><label>(F-18)</label><graphic position="anchor" xlink:href="7-2800488\158d6950-3ab0-4d56-a2ff-3a2b4e3eaf5e.jpg"  xlink:type="simple"/></disp-formula><p>Introduction of Equation Set (F-18) into Equation (F-5) results in</p><disp-formula id="scirp.33370-formula133396"><label>(F-19)</label><graphic position="anchor" xlink:href="7-2800488\f1763f09-4a16-4bd8-a762-8b41f4fe8f28.jpg"  xlink:type="simple"/></disp-formula><p>Equation (F-19) yields the initial guess for the top asymptotic factor<img src="7-2800488\cdee5366-2db0-4311-9fc4-728bdc78fc15.jpg" />,</p><disp-formula id="scirp.33370-formula133397"><label>(F-20)</label><graphic position="anchor" xlink:href="7-2800488\b28376c8-580a-40e8-b118-b7834c0e74d4.jpg"  xlink:type="simple"/></disp-formula><p>Equation (F-18) yields the initial guess for the bottom and the inner asymptotic factors, <img src="7-2800488\552bd994-c90a-44d8-a87f-26f0b4339946.jpg" />and<img src="7-2800488\5a2a7328-94f9-4825-9024-1f4627d4e727.jpg" />. Then we solve Equation Set (F-16) numerically, along with Equation (F-5).</p></sec><sec id="s22"><title>Appendix G. Numerical Examples of BVRT</title><p>In this appendix, we present three examples of the boundary value ray tracing, <xref ref-type="fig" rid="fig9">Figure 9</xref>. The parameters of the velocity profile are the same as above. For each case, the source point <img src="7-2800488\45ce1402-e60e-4ea9-8173-ac44b5492d1f.jpg" /> is located at the origin of the frame.</p><p>The destination point is different for each case: B<sub>1</sub> (x = 2 km, z = 3 km), B<sub>2</sub> (x = 4 km, z = 2 km), and B<sub>3</sub> (x = 8 km, z = 2 km). As we will show, the first case corresponds to the pre-critical ray path, the second corresponds to the post-critical path that does not include the turning point, and the last case leads to the post-critical path with the turning point. First we calculate the critical lateral propagation with Equation (101): Δx<sub>C</sub> = 1.587 km for the destination point depth z<sub>b</sub> = 2 km, and Δx<sub>C</sub> = 2.646 km for z<sub>b</sub> = 3 km. Next we compare the horizontal offset <img src="7-2800488\681eeeeb-7399-4b95-8c5a-73eecc957d59.jpg" /> to the critical lateral propagation and apply the criterion in Equation (102): <img src="7-2800488\21256da8-50b9-4b2b-bf8d-9fb26c9e2149.jpg" />for the destination point B<sub>1</sub> and <img src="7-2800488\330e02e6-62ba-4262-8057-b99422c3f63f.jpg" /> for the destination points B<sub>2</sub> and B<sub>3</sub>. We conclude that ray <img src="7-2800488\9078c952-2469-4500-8d2b-c0b015b5f27f.jpg" /> is pre-critical, while rays AB<sub>2</sub> and AB<sub>3</sub> are post-critical.</p><p>We solve Equation (105) for pre-critical ray <img src="7-2800488\1f4578b2-922e-43b7-8a23-01c5a5c5e4ab.jpg" /> and establish its eccentricity:<img src="7-2800488\75cf9c18-3e7a-4afb-969f-19dbdb724242.jpg" />. The ray angles at the departure and the destination points are: <img src="7-2800488\de153b89-da2a-443a-b221-84156ed0e934.jpg" /><img src="7-2800488\e18f68b2-b939-42be-9c83-1e439bd5c001.jpg" />and<img src="7-2800488\ff13403d-b243-4e31-8f5d-1c26acac6e6e.jpg" />.</p><p>Next we figure out whether the post-critical rays <img src="7-2800488\9710f4ee-e9ca-403b-a9ad-0d99140731bf.jpg" /> and <img src="7-2800488\1615b640-abe6-440a-b89f-ec52e463ae22.jpg" /> include the turning point or not. If the postcritical ray includes a turning point, then the ray angle at the destination is obtuse, and this should be taken into account in Equation (104). For this we establish an auxiliary post-critical ray, whose maximum penetration depth is equal to the destination depth of points B<sub>1</sub> and<img src="7-2800488\ab308ed9-7f4c-43ef-92a9-8e2b3fa98f56.jpg" />. We solve Equation (68) for the eccentricity,</p><disp-formula id="scirp.33370-formula133398"><label>(G-1)</label><graphic position="anchor" xlink:href="7-2800488\25633d02-f55e-4485-b728-c9d820de3862.jpg"  xlink:type="simple"/></disp-formula><p>Compare Equation (G-1) with Equation (22). It is interesting to note that the eccentricity of a post-critical ray with the turning point at the given depth is equal to the normalized velocity at this depth. We obtain the eccentricity of the auxiliary ray<img src="7-2800488\ab90a87f-e02e-483b-b82d-79042c473cac.jpg" />, and the take-off angle<img src="7-2800488\a4d0b743-560f-4868-bc9e-88a032a7bc3f.jpg" />. Calculate the half-chord of this ray with Equation (98),<img src="7-2800488\0a8a10b5-be91-48f2-b006-db98c8a6d0b0.jpg" />. Thus, we see that for the destination point<img src="7-2800488\23250716-1c8b-4e8e-9996-180c859d4b6a.jpg" />, the offset is less than the half-chord of the auxiliary ray, <img src="7-2800488\655ed082-5859-4916-8b11-05fe8fe760a0.jpg" />, while for the destination point B<sub>3</sub>,<img src="7-2800488\09d2fb9d-528c-4f9e-8e58-f715f58069c5.jpg" />. Hence we conclude that ray <img src="7-2800488\5b0068f1-9329-41d4-90e0-00eddbdcea93.jpg" /> does not include the turning point, while ray <img src="7-2800488\c0f442ea-2324-4398-b6e4-0d453aa75c89.jpg" /> includes the turning point. We solve Equation (105) for ray <img src="7-2800488\67d20ebb-3753-4e9b-aed0-2e1014aec75c.jpg" /> and obtain the eccentricity, <img src="7-2800488\1d17c14b-949f-48b2-be30-6c85aaf37362.jpg" />, and the ray angles at the endpoints, <img src="7-2800488\a84e200c-1804-424d-b4e7-d5a4b9349d03.jpg" />For ray AB<sub>3</sub> the results are: <img src="7-2800488\21a02957-ed50-4003-9295-0406f1d7e9ac.jpg" />and <img src="7-2800488\7642ce4b-b589-46fa-8870-673aa67fa08b.jpg" /> Note that the last angle is obtuse. The three traced rays, along with the auxiliary ray (grey line) and the critical ray (green line) are plotted in <xref ref-type="fig" rid="fig9">Figure 9</xref>.</p></sec></body><back><ref-list><title>References</title><ref id="scirp.33370-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">M. Muskat, “A Note on Propagation of Seismic Waves,” Geophysics, Vol. 2, No. 4, 1937, pp. 319-328.  
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