学术会议poster模板
国际学术会议海报(poster)模板(英文)9
non-distress vocalizations 48%
other 38%
Berlin Los Angeles Beijing
38 20 17 36
gaze 10%
smile 4%
Delhi
Reactions to non-distress vocalizations
neutral vocalizations of low or middle intensity
Contingency toward infant signals in mother-infant dyads from Culture & different cultural environments development
Joscha Kärtner & Heidi Keller
Percentages of child events
SAMPLES
Child N Girls 47.4% 61.9% 64.7% 47.1% 57.7% Firstborn** * 73.7% 71.4% 100.0% 40.0% 26.9%
12
Mother Age*** 34.0a (3.0) 34.5a (3.0) 27.9b (2.8) 29.0b (3.4) 30.2 (6.2) 29.0b (8.4) Education* ** 15.2a (3.4) 17.0a (1.6) 15.2a/b (3.0) 15.5a (1.4) 12.9b (1.8) 6.6c (1.9)
THEORETICAL BACKGROUND • To react contingently toward a baby’s signals is part of the universal intuitive parenting repertoire (Papoušek & Papoušek, 1991). In two recent studies vocalizing was the dominant modality followed by touching (Hsu & Fogel, 2003; VanEgeren et al., 2001) • Furthermore, there are culture-specific modulations: • Gusii mothers from rural Kenya predominantly reacted by holding and touching whereas Boston middle-class mothers reacted primarily by looking and vocalizing (Richman et al., 1992) • Japanese mothers reacted more by touching as compared to Euro-American mothers who used facial expressions and vocalizing more often (Fogel et al.,1988) Our study addresses the general occurrence of contingent responsiveness as well as the specificity of reactions using a multicultural design with mothers who differ with respect to their interactional preferences: • Mothers with an independent model of parenting (Berlin and Los Angeles) should use distal modalities more often, • Mothers with an interdependent model of parenting (rural Nso) should use proximal modalities more often, and • Mothers with an autonomous relational model of parenting (Beijing, Delhi, urban Nso) should use both distal and proximal modalities equally often PROCEDURE • Families were visited at home • 10 minutes free play interaction between the caretaker and her 3-month old baby was videotaped METHODS – modalities for contingent responsiveness: 1.Body contact (holding) 2.Body stimulation (touching) 3.Gaze (looking) 4.Smile 5.Facial expression (raised eyebrows, mouth open) 6.Vocalization (talking) 7.Object stimulation (toys) 8.Acoustical stimulation (flipping, rattling)
国际学术会议海报(poster)模板(英文)9
contingency rate in %
Similarities • Our study confirmed that contingent responsiveness is a pancultural parenting disposition • The dominant modalities were vocalization followed by body stimulation in all samples • There were significantly more reactions to non-distress vocalizations than to nonverbal events in all samples • In response to nonverbal child events as compared to responses to non-distress vocalizations the contingency rates of reactions that the child can see (gaze, smile, and facial expression) increased • At the same time the contingency rates of reactions that the child can feel (body stimulation and body contact) or hear (vocalizations and acoustical stimulation) decreased → still vocalizations were the dominant response Differences There were differences in modalities that correspond to different models of parenting: • In response to non-distress vocalizations mothers with an independent model of parenting addressed the baby’s sense of sight more often • Mothers with an interdependent model of parenting used the modalities body stimulation and body contact more often than did mothers from all other samples • Scores of mothers with an autonomous-relational orientation lay somewhere in between scores for the other two orientations Idiosyncrasies • Individual samples showed unexpected idiosyncrasies, e.g. mothers from Los Angeles used more body stimulation and mothers from Beijing vocalized more than expected
国际学术会议海报(poster)模板(英文)10
Method
▪Participants
Fifty-one 12-month-old infants and their mothers participated in a larger 3-year longitudinal study.
▪Procedure & Measures
At 12 months
Results
The quantity and quality of infants’ looking during interaction
▪ Twelve-month-olds were more likely to look at task objects than at their mother during teaching interactions.
▪ The infants who more frequent and longer look to mother’s face in the interaction showed high emotional recognition in toddlerhood.
▪Findings from this longitudinal study suggest that infants’ social looking to their mothers during interactions may provide an opportunity to explore and percept others’ emotions.
▪ However, longer looks to objects during social-oriented tasks were related to lower scores in recognizing highintensity emotions.
原创国际学术会议海报(poster)模板(英文)
原创国际学术会议海报(poster)模板(英文)原创国际学术会议海报(poster)模板(英文)Fiber optic characterization using a simulated Optical TimeDomain Reflectometer (OTDR)Robb P. MerrillDepartment of Electrical and Computer Engineering - University of Utah IntroductionOptical Time Domain Reflectometry (OTDR) is a common technique for detecting damage in fiber optic cables. The process involves transmitting a pulse of light down the optical fiber, analyzing the amount of light reflected back to the source, and displaying the reflection patterns on the OTDR screen.During characterization of short fiber optic cables of approximately 1 meter, Fresnel reflections pose a serious challenge to accurate damage detection. The Fresnel tail obliterates any small reflections that are produced by damaged sections of cable, and the damage is overlooked.Simulation MethodThe Finite Difference Time Domain method [1] was implemented in MATLAB to simulate a pulse of light traveling through the patch and test fibers. The following parameters used in the simulation were obtained from an actual OTDR system: Index of refraction (n) of test fiber = 1.4525, Wavelength (λ) of light pulse = 850 nanometers [3] .Plotting the reflection response patterns from all four connection types shows that the Angled Physical Contact connector produced the lowest reflection (see Figure 6). Though much less expensive, Index Matching Fluid only has a lifetime of 2 years. Most optical fiber applications require 10 years life or more [3].Pulse DurationT o determine the effect of the light pulse duration on the saturation level of the OTDR unit, one period ofa raised cosine pulse was transmitted through the fiber at various frequencies. A pulse duration of 1 microsecond proved to be the most favorably responsive for the parameters of the simulation (see Figure 3). In realworld application, however, the duration must actually be smaller due to the relatively slow simulation speed vs. the physical speed of light.OTDR Saturation at Increased Pulse Durations 0.035 1 second 0.03 2 seconds 3 secondsAbnormalities in the fiber, such as bends, cracks, connectors, and other abrupt changes in the refractive index create reflection spikes called Fresnel ( Fre'-nel ) reflections [2]. After a spike is detected, a significant delay occurs when the reflectometer ‘settles down’ from its saturated state. This delay is called a Fresnel tail (Figure 1).Figure 1: OTDR screenshot showing reflection spike from cable connector, and resulting Fresnel tail (area marked by bracket)0.025Electric Field (V/m)0.020.01510.01Figure 5: Reflection patterns using various connectors (reduced Fresnel magnitudes inside yellow box)0.0050 1 1.5 2 2.5 3 3.5 4 Travel Distance from Source (m) 4.5 5SummaryShort fiber optic cables present many challenges that must be overcome in order to accurately detect fiber damage using OTDR. Pulse durations shorter than 1 microsecond, and Angled Physical Contact (APC) fiber connectors are recommended to provide the greatestreduction in Fresnel reflection. By performing OTDRsimulations, an optical systems engineer could understand the behavior of a fiber network and detect potential problems before actual production.Figure 3: Simulated Fresnel Tail skews, then obliterates, the damage reflection at larger durationsConnector TypeThe index of refraction of the patch vs. the test fiber was allowed differ by up to 10%, which created a mismatch at the junction of the two fibers. Four types of connectors were simulated to determine which produced the lowest reflection magnitude.15x 10-3Ideal Reflection Characteristics (No OTDR Saturation)105Figure 2: Simulated ideal response showing fiber damage (small reflection bumps). Damage is visible because no Fres-nel tail is present.Electric Field (V/m)Figure 4: Common types of fiber optic connectors with relative reflection magnitudes shownReferences[1] Sadiku, N.O. Matthew. Numerical Techniques in Electromagnetics [2] Newton, Steven A. Novel Approaches to Optical Reflectometry [3] Knapp, John. Characterization of FiberOptic Cables Using an Optical Time Domain Reflectometer (OTDR)0 2 2.5 3 Travel Distance from Source (m) 3.5Fiber optic characterization using a simulated Optical TimeDomain Reflectometer (OTDR)Robb P. MerrillDepartment ofElectrical and Computer Engineering - University of UtahIntroductionOptical Time Domain Reflectometry (OTDR) is a common technique for detecting damage in fiber optic cables. The process involves transmitting a pulse of light down the optical fiber, analyzing the amount of light reflected back to the source, and displaying the reflection patterns on the OTDR screen.During characterization of short fiber optic cables of approximately 1 meter, Fresnel reflections pose a serious challenge to accurate damage detection. The Fresnel tail obliterates any small reflections that are produced by damaged sections of cable, and the damage is overlooked.Simulation MethodThe Finite Difference Time Domain method [1] was implemented in MATLAB to simulate a pulse of light traveling through the patch and test fibers. The following parameters used in the simulation were obtained from an actual OTDR system: Index of refraction (n) of test fiber = 1.4525, Wavelength (λ) of light pulse = 850 nanometers [3] .Plotting the reflection response patterns from all four connection types shows that the Angled Physical Contact connector produced the lowest reflection (see Figure 6). Though much less expensive, Index Matching Fluid only has a lifetime of 2 years. Most optical fiber applications require 10 years life or more [3].Pulse DurationTo determine the effect of the light pulse duration on the saturation level of the OTDR unit, one period of a raised cosine pulse was transmitted through the fiber at various frequencies. A pulse duration of 1 microsecond proved to be the most favorably responsive for the parameters of the simulation (see Figure 3). In realworld application, however, the duration must actually be smaller due to the relatively slow simulation speed vs. the physical speed of light.OTDR Saturation at Increased Pulse Durations 0.035 1 second 0.03 2 seconds 3secondsAbnormalities in the fiber, such as bends, cracks, connectors, and other abrupt changes in the refractive index create reflection spikes called Fresnel ( Fre'-nel ) reflections [2]. After a spike is detected, a significant delay occurs when the reflectometer ‘settles down’ from its saturated state. This delay is called a Fresnel tail (Figure 1).Figure 1: OTDR screenshot showing reflection spike from cable connector, and resulting Fresnel tail (area marked by bracket)0.025Electric Field (V/m)0.020.01510.01Figure 5: Reflection patterns using various connectors (reduced Fresnel magnitudes inside yellow box)0.0050 1 1.5 2 2.5 3 3.5 4 Travel Distance from Source (m) 4.5 5SummaryShort fiber optic cables present many challenges that must be overcome in order to accurately detect fiber damage using OTDR. Pulse durations shorter than 1 microsecond, and Angled Physical Contact (APC) fiber connectors are recommended to provide the greatest。
学术会议海报Poster模板1
3. Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxx
4. Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx
Figure #1
国际会议poster模板
Figure 1: Your caption to go here
Figure 2: Your caption to go here
Conclusion
Aliquam nec lacus eget sapien venenatis semper. Donec placerat. Phasellus bibendum semper ligula. Duis vitae massa. Integer suscipit. Donec non elit vel nunc tincidunt iaculis. Nam in urna. Pellentesque eu enim. Nam pellentesque libero nec velit. Aliquam quis sem. Nulla vestibulum vehicula arcu. Vestibulum feugiat eleifend elit. Proin condimentum molestie urna. Etiam ut diam. Quisque viverra lectus ac lectus. Donec ultrices, nisi nec mollis ultricies, quam diam aliquam enim, eu vulputate sem eger pede. Suspendisse lectus. Quisque nibh. Vestibulum ante ipsum primis in faucibus orci luctus et ultrices posuere cubilia Curae; Donec fringilla nunc quis quam. Curabitur quam. Suspendisse vitae libero venenatis mauris blandit volutpat. Class aptent taciti sociosqu ad litora torquent per conubia nostra, per inceptos hymenaeos. Duis consequat. Nunc tempus nonummy nulla. Duis congue scelerisque metus. Morbi vitae metus. Aliquam erat volutpat. Sed mattis odio vitae mi. Integer lectus augue, pretium ac, iaculis et, lacinia vel, orci. Pellentesque tempor tristique velit. Nullam elit ligula, rutrum sodales, ornare ornare, tristique sit amet, purus. Sed rutrum massa sit amet lectus. Pellentesque dapibus sem in ante. Maecenas vitae quam nec leo luctus congue. In at risus ac purus ornare auctor. Fusce vitae neque. Curabitur condimentum nulla. Mauris euismod turpis. Phasellus id risus. Etiam nibh odio, dignissim ut, tincidunt ut, viverra at, nisl. Vestibulum luctus eleifend odio. Duis porta, arcu ac ornare interdum, sapien nibh ultricies dolor, in venenatis justo orci vel est. Vestibulum ante ipsum primis in faucibus orci luctus et ultrices posuere cubilia Curae; Suspendisse sit amet turpis sed est dapibus porta. In augue. Nunc urna ligula, suscipit ac, varius at, rhoncus non, orci. Aenean ultricies, mauris ac rutrum viverra, nulla nisi luctus urna, mattis sagittis pede pede ut massa. Sed sapien dolor, fermentum eget, dignissim pulvinar, euismod eu, massa. Pellentesque luctus. Maecenas auctor tellus et nisl. Nulla sodales.
学术会议 学术交流poster模板
• In hac habitasse platea dictumst. Nullam tellus.
Age (years)
60.9 + 9.2
Parity*
3
Menopausal
17 (100)
Hormone therapy
9 (52.9)
Previous posterior repair
7 (41.2)
Defecatory symptoms
9 (52.9)
Bulge symptoms
15 (88.2)
60
50
40
30
Conscientious
Vulnerability
Dutifulness
20 O
EA
135
135
O Factor
135
1 3* 5
24 6
24 6
*p < .05
Conclusion
Lorem ipsum dolor sit amet, consectetuer adipiscing elit. Nam in diam consectetuer odio blandit elementum. Morbi id ligula ac ligula adipiscing iaculis. Nulla risus lorem, molestie ac, scelerisque quis, gravida eleifend, wisi. Proin sapien ante, faucibus sit amet, mollis eu, molestie a, erat. Donec magna nibh, ultrices facilisis, dignissim at, mollis ut, diam. Nulla facilisi. Cum sociis natoque penatibus et magnis dis parturient montes, nascetur ridiculus mus. Morbi tristique erat at ligula. Curabitur in metus. Donec consequat. Quisque porta. Integer diam. Mauris pellentesque aliquet elit. Curabitur hendrerit metus quis augue. Mauris rhoncus, magna vitae laoreet imperdiet, ligula dolor hendrerit quam, sit amet mollis augue nibh et lorem.
poster,session,模板
竭诚为您提供优质文档/双击可除poster,session,模板篇一:学术装腔poster篇学术会议的交流主要有两种形式:oral和poster,就是所谓的口头和张贴两种。
poster,可以译为“海报”或“展板”,扼要展示自己或团队的工作,以供学术交流。
-------------------------------------------------------分割线-------------------------------------------------------------------假装前言话说我有这么门儿课,“学术写作”。
留了个作业,找篇文献,做一个poster。
2-3人小组作业,这个周日deadline。
话说一开始我没有组,正打算单干呢,昨天课前正好撞见我的俄罗斯同学,她说我也没组呀,咱俩吧;她前一天刚报告了一篇文献,说咱就这个吧,我心想也不错,反正自己也没开始。
昨天晚上大概不到10点的时候,这位俄罗斯妹子发来了她的初稿(见图一),邮件里还说“我在这上面花了1个小时40分钟,公平起见吧,你是不是也得差不多花一样的时间捏?”我暗自思忖,行啊,无所谓。
打开初稿一看,出了一身汗,全tm的工作量啊……不过心想她文章看了至少2遍吧,得嘞,开干吧。
图一.poster初稿从10点大约折腾到凌晨1点找素材,确定模板,然后睡觉去了。
今天早晨8:30起的,起来就断断续续干这件事儿,但累计也得五六个小时了吧。
我在晚上7点时候基本完成了这个poster,妹子给我挑了一些毛病,然后后面说“忽略那些小问题,我非常喜欢这个poster哈!”(你丫敢不喜欢……)8点半左右基本定型了,明天早起再最后看一眼。
闲言少叙,正题吧。
-------------------------------------------------------分割线-------------------------------------------------------------------正文部分先是一些关于poster的基本要点和原则:制作软件-ppt!poster的制作软件是ppt,以前一直以为是什么高级软件,但现在发现ppt这货还真是挺强大的。
国际学术会议海报(poster)模板(英文)9
20 10 0
b a
c
20 10
• Contingent responses are additions, modifications and deletions of specific behaviors • We allow for settings with multiple caretakers to guarantee ecological validity (there were either 1 (11.5%) or 2-3 (4.8%) other persons besides the mother)
80 70
d a b/d
b
80
a a
70
contingency rate in %
60 c/d/e
n.s .
n.s .
b/c a/c a/c a/b b
analysis of caretakers’ behavior
b/d a/b/c/ d a
b/c
Percentages of child events
THEORETICAL BACKGROUND • To react contingently toward a baby’s signals is part of the universal intuitive parenting repertoire (Papoušek & Papoušek, 1991). In two recent studies vocalizing was the dominant modality followed by touching (Hsu & Fogel, 2003; VanEgeren et al., 2001) • Furthermore, there are culture-specific modulations: • Gusii mothers from rural Kenya predominantly reacted by holding and touching whereas Boston middle-class mothers reacted primarily by looking and vocalizing (Richman et al., 1992) • Japanese mothers reacted more by touching as compared to Euro-American mothers who used facial expressions and vocalizing more often (Fogel et al.,1988) Our study addresses the general occurrence of contingent responsiveness as well as the specificity of reactions using a multicultural design with mothers who differ with respect to their interactional preferences: • Mothers with an independent model of parenting (Berlin and Los Angeles) should use distal modalities more often, • Mothers with an interdependent model of parenting (rural Nso) should use proximal modalities more often, and • Mothers with an autonomous relational model of parenting (Beijing, Delhi, urban Nso) should use both distal and proximal modalities equally often PROCEDURE • Families were visited at home • 10 minutes free play interaction between the caretaker and her 3-month old baby was videotaped METHODS – modalities for contingent responsiveness: 1.Body contact (holding) 2.Body stimulation (touching) 3.Gaze (looking) 4.Smile 5.Facial expression (raised eyebrows, mouth open) 6.Vocalization (talking) 7.Object stimulation (toys) 8.Acoustical stimulation (flipping, rattling)
学术会议poster模板
Captions to be set in Times or Times New Roman or equivalent, italic, 18 to 24 points, to the length of the column in case a figure takes more than 2/3 of column width.
Captions to be set in Times or Times New Roman or
equivalent, italic, between 18 and 24 points. Right aligned if it refers to a figure on its right. Caption starts right at the top
Captions to be set in Times or Times New Roman or
光纤传感会议ofs学术poster展示模板 -回复
光纤传感会议ofs学术poster展示模板-回复题目:光纤传感会议(OFS) 学术Poster 展示模板摘要:光纤传感技术在近年来得到了广泛的研究和应用,它在物理、化学、生物等领域都有着重要的应用价值。
本文以光纤传感会议(OFS) 学术Poster 展示模板为主题,详细介绍了光纤传感技术的原理、当前的研究热点以及未来的发展方向。
引言:光纤传感技术是一种通过光纤传输信号和接收反馈信号的技术,它可以实现对各种物理量和化学物质的高精度测量和监测。
光纤传感技术具有传输距离长、响应速度快、抗干扰能力强等优点,因此受到了广泛的关注和研究。
一、光纤传感技术原理光纤传感技术的原理是基于光的传输和散射效应。
通过在光纤中引入一些敏感材料或纳米结构,当光信号通过光纤时,它们与敏感材料或纳米结构相互作用,会发生光的散射、吸收或反射等现象。
通过分析这些散射信号的特性,就可以得到所要测量的物理量或化学物质的信息。
二、当前的研究热点1. 光纤传感技术在生物医学领域的应用光纤传感技术在生物医学领域有着广泛的应用,可以实现对生物组织的显微镜观察、生化分析等。
目前,研究人员正在探索基于光纤传感技术的生物传感器、生物成像等方面的应用。
2. 光纤传感技术在环境监测领域的应用光纤传感技术在环境监测领域也有着重要的应用,可以实现对环境污染物、大气污染物等的快速监测。
研究人员正在研究基于光纤传感技术的水质检测、空气质量监测等方面的应用。
3. 光纤传感技术在工业制造领域的应用光纤传感技术在工业制造领域也有着广泛的应用,可以实现对材料表面缺陷、温度、压力等参数的监测。
研究人员正在研究基于光纤传感技术的无损检测、工业自动化监控等方面的应用。
三、未来的发展方向1. 多模光纤传感技术的研究目前光纤传感技术主要采用单模光纤进行传感,为了提高传感信号的灵敏度和精度,研究人员正在研究多模光纤传感技术。
多模光纤传感技术可以实现对更多物理量和化学物质的测量,有着广阔的应用前景。
【学术会议poster模板】bluegreen_24x48
Insert your text here. You can place your organizations logos on either side of the title of the poster. Remember, you can change template colors to suit your own taste or institution colors. The graphic can be replaced with several smaller graphics.
Fourth finding
4th Qtr
North East West
Conclusion
Put your information here. Remember to size your font accordingly. Point one econd conclusion
▪Sub point Next interesting point
LOGO
in this area.
Insert your informaItinonthreoreduction
Insert your text here. You can place your organizations logos on either side of the title of the poster. Insert your text here. You can place your organizations logos on either side of the title of the poster. Remember, you can change template colors to suit your own taste or institution colors. The graphic can be replaced with several smaller graphics. Insert your text here. You can place your organizations logos on either side of the title of the poster. Remember, you can change template colors to suit your own taste or institution colors. The graphic can be replaced with several smaller graphics.
- 1、下载文档前请自行甄别文档内容的完整性,平台不提供额外的编辑、内容补充、找答案等附加服务。
- 2、"仅部分预览"的文档,不可在线预览部分如存在完整性等问题,可反馈申请退款(可完整预览的文档不适用该条件!)。
- 3、如文档侵犯您的权益,请联系客服反馈,我们会尽快为您处理(人工客服工作时间:9:00-18:30)。
equivalent, italic, between 18 and 24 points. Right aligned if it refers to a figure on its right. Caption starts right at the top
Method
Tips for making a successful poster… ▪ Re-write your paper into poster format ie.
Simplify everything, avoid data overkill. ▪ Headings of more than 6 words should be in upper
space around you text. Don’t overcrowd your poster. ▪ Try using photographs or coloured graphs. Avoid long numerical tables. ▪ Spell check and get someone else to proof-read.
Acknowledgements
Just highlight this text and replace with your own text. Replace this with your text.
edge of the picture (graph or photo).
Notes about graphs… For simple graphs use MS Excel, or do the graph directly in PowerPoint. Graphs done in a scientific graphing s (eg. Sigma Plot, Prism, SPSS, Statistica) should be saved as JPEG or TIFF if possible. For more information see MIU.
Printing and Laminating… Once you have completed your poster, bring it down to MIU for printing. We will produce a A3 size draft print for you to check and proof read. The final poster will then be printed and laminated. Note: Do not leave your poster until the last minute. Allow at least 5 working days before you need to use it. Simply highlight this text and replace.
Captions to be set in Times or Times New Roman or equivalent, italic, between 18 and 24 points. Left aligned if it refers to a figure on its left. Caption starts right at the top edge of the picture (graph or photo).
Captions to be set in Times or Times New Roman or equivalent, italic, between 18 and 24 points. Left aligned if it refers to a figure on its left. Caption starts right at the top edge of the picture (graph or photo).
Introduction
First… Check with conference organisers on their specifications of size and orientation, before you start your poster eg. maximum poster size; landscape, portrait or square. The page size of this poster template is A0 (84x119cm), portrait (vertical) format. Do not change this page size, MIU can scale-to-fit a smaller or larger size, when printing. If you need a different shape start with either a landscape (horizontal) or a square poster template. Bear in mind you do not need to fill up the whole space allocated by some conference organisers (eg. 8ftx4ft in the USA). Do not make your poster bigger than necessary just to fill that given size.
Aim
How to use this poster template… Simply highlight this text and replace it by typing in your own text, or copy and paste your text from a MS Word document or a PowerPoint slide presentation. The body text / font size should be between 24 and 32 points. Arial, Helvetica or equivalent. Keep body text left-aligned, do not justify text. The colour of the text, title and poster background can be changed to the colour of your choice.
Captions to be set in Times or Times New Roman or equivalent, italic, 18 to 24 points, to the length of the column in case a figure takes more than 2/3 of column width.
Title Goes Here Title Goes Here Title Goes Here Title Goes Here Title Goes Here
Author’s Name/s Goes Here, Author’s Name/s Goes Here
Address/es Goes Here, Address/es Goes Here
Captions to be set in Times or Times New Roman or
equivalent, italic, between 18 and 24 points. Right aligned if it refers to a figure on its right. Caption starts right at the top
edge of the picture (graph or photo).
Results
Importing / inserting files… Images such as photographs, graphs, diagrams, logos, etc, can be added to the poster. To insert scanned images into your poster, go through the menus as follows: Insert / Picture / From File… then find the file on your computer, select it, and press OK. The best type of image files to insert are JPEG or TIFF, JPEG is the preferred format. Be aware of the image size you are importing. The average colour photo (13 x 18cm at 180dpi) would be about 3Mb (1Mb for B/W greyscale). Call MIU if unsure. Do not use images from the web.
Cost… For poster-printing and laminating charges contact to MIU
Conclusion
For more information on: Poster Design, Scanning and Digital Photography, and Image / file size.
Captions to be set in Times or Times New Roman or equivalent, italic, 18 to 24 points, to the length of the column in case a figure takes more than 2/3 of column width.