Analyzing Financial Statements answeres Essay Example | Topics and Well Written Essays - 500 words - 1

Analyzing Financial Statements answeres - Essay Example Operating cash flow relates to cash flows that a company accrues from operations to its current debt. It measures how liquidity a firm is in the short run since it relates to current debt and cash flows from operations. (Gregor, 2008) The ratio -0.133 is less than which means Sears Company is not generating enough cash to pay off its short-term debt which is a serious situation in the company. This is a critical concern and a matter of urgency. If it is not dealt with it may lead to liquidation of the company. Therefore, it is possible that the firm may not be able to continue to operate. (Sears, 2013) The price to cash flow ratio is often considered a better indication of a companys value than the price to earnings ratio. It is a really useful ratio for a company to know, particularly if the company is publicly traded. It compares the companys share price to the cash flow the company generates on a per share basis. (Gregor, 2008) This implies that the price to cash flow ratio is quite small and that the ratio price ought to be increased for the shareholders. Ordinarily, share price is usually the closing price of the stock on a particular day and operating cash flow is taken from the Statement of Cash Flows. Some business owners use free cash flow in the denominator instead of operating cash flow. (Gregor, 2008) Normally, Cash flow from Operations/Average total liabilities is a similar ratio to the commonly-used total debt/total assets ratio. Both measure the solvency of a company or its ability to pay its debts and keep its head above water. (Anonymous, 2008) The answer shows how many times over a company can meet its short-term debt and is a measure of the firms liquidity. This ratio means that Sears Company has a low degree of settling its debts by the use of the current assets. (Wood, 2009) The quick ratio, or acid test, is a more specific test of liquidity than the current ratio. It takes inventory out of the equation and measures

Hand-grip :: essays research papers

Hand- Grip Dynamometer   Ã‚  Ã‚  Ã‚  Ã‚  Hand-Grip dynamometer are used to measure the strength and endurance of the muscles in your forearm, and to a lesser extent your hand. Using a handgrip dynamometer will increase your performance at work, improve posture, decrease chances for injury, and prevent low back pain. Endurance is the ability of a muscle to work for long periods of time without extreme fatigue. It prevents unwanted fatigue from daily activities, sport and recreation. For the elderly person, good hand grip strength may prevent a fall down stairs or in bathtubs and may help people from dropping jars. It could help the elderly with opening jars as well.   Ã‚  Ã‚  Ã‚  Ã‚  Three area’s of rationale are used to measure strength-anatomical, physiological, and biochemical. These are all interrelated. The first area Anatomical Rationale-Hand grip strength is mainly a function of the muscles in the forearm, and hand. Eight muscles serve as the prime movers and stabilizers in hand grip strength. Eleven other muscles assist in contraction of the hand.   Ã‚  Ã‚  Ã‚  Ã‚  The second is physiological Rationale which has six categories. Six of the most common measurement terms in physiology are mass, force, work, velocity, power and energy.   Ã‚  Ã‚  Ã‚  Ã‚  The third area is biochemical rationale exercise may be divided into three categories based upon the predominant metabolic pathway. The primary biochemical reaction for strength, or any muscle contraction is ATP ( Adenosine Triphosophate).   Ã‚  Ã‚  Ã‚  Ã‚  The muscular strength is highly affected by the nervous system. Emotional and mental factors play important part in strength testing. If a subject is consistent with motivation strength variability should be minimized. In women a daily variation in strength range is between 2 and 12% and 5 to 9% in men.   Ã‚  Ã‚  Ã‚  Ã‚  Instruments used to measure muscle strength are cable tensiometer, dymameter, free weights, barbells, isokinetics devices and load cells or elechromechanical devices. Strength is usually measured in units of force or torque. Kilogram (kg), and pounds (lb), is the force unit. The torque unit may be expressed as a foot-pounds (fl-lb) or Newton meters (nm).   Ã‚  Ã‚  Ã‚  Ã‚  The procedures for handgrip strength testing are: 1.  Ã‚  Ã‚  Ã‚  Ã‚  The subject should be in the standing position. 2.  Ã‚  Ã‚  Ã‚  Ã‚  The subject’s head should be in the midposition (facing straight ahead). 3.  Ã‚  Ã‚  Ã‚  Ã‚  The grip size should be adjusted so that the middle finger’s midportion is approximatrely at a right angle. 4.  Ã‚  Ã‚  Ã‚  Ã‚  The subject’s forearm may be placed at any angle between 90 degrees and 180 degrees of the upper arm; the upper arm is in a vertical position. 5.  Ã‚  Ã‚  Ã‚  Ã‚  The subject’s wrist and forearm should be at the midprone position.

The Discovery of Electronics

The first practical application of electricity was the telegraph, invented by Samuel F. B. Morse in 1837. The need for electrical engineers was not felt until some 40 years later, upon the invention of the telephone (1876) by Alexander Graham Bell and of the incandescent lamp (1878) by Thomas A. Edison. These devices and Edison's first central generating plant in New York City (1882) created a large demand for men trained to work with electricity. The discovery of the â€Å"Edison effect,† a flow of current through the vacuum of one of his lamps, was the first observation of current in space. Hendrick Antoon Lorentz of The Netherlands predicted the electron theory of electrical charge in 1895, and in 1897 J. J. Thomson of England showed that the Edison effect current was indeed caused by negatively charged particles (electrons). This led to the work of Guglielmo Marconi of Italy, Lee De Forest of the United States, and many others, which laid the foundations of radio engineering. In 1930 the term electronics was introduced to embrace radio and the industrial applications of electron tubes. Since 1947, when the transistor was invented by John Bardeen, William H. Brattain, and William B. Shockley, electronics engineering has been dominated by the applications of such solid-state electronic devices as the transistor, the semiconductor diode, and the integrated circuit. the branch of engineering concerned with the practical applications of electricity in all its forms, including those of the field of electronics. Electronics engineering is that branch of electrical engineering concerned with the uses of the electromagnetic spectrum and with the application of such electronic devices as integrated circuits, transistors, and vacuum tubes. In engineering practice, the distinction between electrical engineering and electronics is based on the comparative strength of the electric currents used. In this sense, electrical engineering is the branch dealing with â€Å"heavy current†-that is, electric light and power systems and apparatuses-whereas electronics engineering deals with such â€Å"light current† applications as wire and radio communication, the stored-program electronic computer, radar, and automatic control systems. The distinction between the fields has become less sharp with technical progress. For example, in the high-voltage transmission of electric power, large arrays of electronic devices are used to convert transmission-line current at power levels in the tens of megawatts. Moreover, in the regulation and control of interconnected power systems, electronic computers are used to compute requirements much more rapidly and accurately than is possible by manual methods Electrical phenomena attracted the attention of European thinkers as early as the 17th century. Beginning as a mathematically oriented science, the field has remained primarily in that form; mathematical predication often precedes laboratory demonstration. The most noteworthy pioneers include Ludwig Wilhelm Gilbert and Georg Simon Ohm of Germany, Hans Christian Orsted of Denmark, Andre-Marie Ampere of France, Alessandro Volta of Italy, Joseph Henry of the United States, and Michael Faraday of England. Electrical engineering may be said to have emerged as a discipline in 1864 when the Scottish physicist James Clerk Maxwell summarized the basic laws of electricity in mathematical form and predicted that radiation of electromagnetic energy would occur in a form that later became known as radio waves. In 1887 the German physicist Heinrich Hertz experimentally demonstrated the existence of radio waves. The first practical application of electricity was the telegraph, invented by Samuel F. B. Morse in 1837. The need for electrical engineers was not felt until some 40 years later, upon the invention of the telephone (1876) by Alexander Graham Bell and of the incandescent lamp (1878) by Thomas A. Edison. These devices and Edison's first central generating plant in New York City (1882) created a large demand for men trained to work with electricity. The discovery of the â€Å"Edison effect,† a flow of current through the vacuum of one of his lamps, was the first observation of current in space. Hendrick Antoon Lorentz of The Netherlands predicted the electron theory of electrical charge in 1895, and in 1897 J. J. Thomson of England showed that the Edison effect current was indeed caused by negatively charged particles (electrons). This led to the work of Guglielmo Marconi of Italy, Lee De Forest of the United States, and many others, which laid the foundations of radio engineering. In 1930 the term electronics was introduced to embrace radio and the industrial applications of electron tubes. Since 1947, when the transistor was invented by John Bardeen, William H. Brattain, and William B. Shockley, electronics engineering has been dominated by the applications of such solid-state electronic devices as the transistor, the semiconductor diode, and the integrated circuit. The functions performed by electrical and electronics engineers include (1) basic research in physics, other sciences, and applied mathematics in order to extend knowledge applicable to the field of electronics, (2) applied research based on the findings of basic research and directed at discovering new applications and principles of operation, (3) development of new materials, devices, assemblies, and systems suitable for existing or proposed product lines, (4) design of devices, equipment, and systems for manufacture, (5) field-testing of equipment and systems, (6) establishment of quality control standards to be observed in manufacture, (7) supervision of manufacture and production testing, (8) postproduction assessment of performance, maintenance, and repair, and (9) engineering management, or the direction of research, development, engineering, manufacture, and marketing and sales.

Ge 117 Itt Tech Video Games and Health - 2111 Words

Video Games and Health ITT Technical Institute It’s easy to see the appeal of the video game. They allow us to do things that most people would never have the chance to experience, or something that’s flat out impossible. From the roar of a massive v-12 engine in a Ferrari, screaming down a straight at 230 miles per hour, to the rat-tat-tat of a heavy machine gun, complete with the imagined scent of cordite and powdery, obliterated dry wall, or even directing stalwart troops across a decimated sci-fi battlefield, there’s nothing quite like the visceral experience of a well-made video game. I’ve plummeted feet-first through Earth’s fiery atmosphere in a vessel no bigger than a phone booth with blue and purple iridescent plasma-bolts†¦show more content†¦Many believe that violent video games in particular are nothing more than interactive murder trainers for those who play them. It’s a known fact that Eric Harris and Dylan Klebold, the disturbed high school seniors responsible for the Columbine High School Shooting, where avid gamers and gun enthusiasts. While there is no proven direct correlation between violent media and actual violent crimes, this can’t be simply dismissed as coincidence. Investigators found computers with the popular game â€Å"Doom† installed in the shooters’ homes, with â€Å"Doom† being somewhat infamous for its brutal, violent content. (Daily News, 2012, Apr. 23) Not all side effects of video game use are bad or disturbing, however. There are even games that are gaining popularity that get you off the couch and onto your feet. For systems like Nintendo’s Wii, there are a plethora of games that promote healthy lifestyles and exercise, most prominent among them Wii Fit. It comes with a â€Å"balance board,† a cheap plastic electronic step that detects your motion and special position. On the software side, there are several minigames with lots of variety, that are all fun but demanding. I†™ve actually sunk a couple of hours into it, and can attest to how fun they can be. The key with this program is that you don’t really realize that you areShow MoreRelatedExploring Corporate Strategy - Case164366 Words   |  658 Pagespharmaceutical industry. TUI – competitive forces in the travel industry. HiFi – how can small players survive changing markets? Amazon (B) – latest developments in a successful dot.com. Formula One – developing the capabilities for competitive success in a hi-tech industry. Manchester United – clash of expectations in the football world. Salvation Army – strategic challenges for a global not-for-profit organisation with a mission. Bayer MS – corporate social responsibility in the international development ofRead MoreDeveloping Management Skills404131 Words   |  1617 PagesReadjustment Rating Scale 109 Sources of Personal Stress 111 SKILL LEARNING 112 Improving the Management of Stress and Time 112 The Role of Management 113 Major Elements of Stress 113 Reactions to Stress 114 Coping with Stress 115 Managing Stress 117 Stressors 117 Eliminating Stressors 120 Eliminating Time Stressors Through Time Management 121 Eliminating Encounter Stressors Through Collaboration and Emotional Intelligence 128 Eliminating Situational Stressors Through Work Redesign 130 Eliminating AnticipatoryRead MoreDamodaran Book on Investment Valuation, 2nd Edition398423 Words   |  1594 Pagessubscribe to the bigger fool theory of investing, which argues that the value of an asset is irrelevant as long as there is a bigger fool willing to buy the asset from them. While this may provide a basis for some profits, it is a dangerous game to play, since there is no guarantee that such an investor will still be around when the time to sell comes. A postulate of sound investing is that an investor does not pay more for an asset than its worth. This statement may seem logical and obvious