2011-3-BOOK-A Taxonomy and Survey of Energy-Efficient Data Centers and Cloud Computing Systems

A Taxonomy and Survey of

Energy-Efficient Data Centers

and Cloud Computing Systems

ANTON BELOGLAZOV

Cloud Computing and Distributed Systems(CLOUDS)

Laboratory,Department of Computer Science and

Software Engineering,The University of Melbourne,

Melbourne,VIC3010,Australia

RAJKUMAR BUYYA

Cloud Computing and Distributed Systems(CLOUDS)

Laboratory,Department of Computer Science and

Software Engineering,The University of Melbourne,

Melbourne,VIC3010,Australia

YOUNG CHOON LEE

Centre for Distributed and High Performance

Computing,School of Information Technologies,

The University of Sydney,Sydney,NSW2600,Australia

ALBERT ZOMAYA

Centre for Distributed and High Performance

Computing,School of Information Technologies,

The University of Sydney,Sydney,NSW2600,Australia

Abstract

Traditionally,the development of computing systems has been focused on

performance improvements driven by the demand of applications from con-

sumer,scientific,and business domains.However,the ever-increasing energy

ADVANCES IN COMPUTERS,VOL.8247Copyright?2011Elsevier Inc. ISSN:0065-2458/DOI:10.1016/B978-0-12-385512-1.00003-7All rights reserved.

48 A.BELOGLAZOV ET AL.

consumption of computing systems has started to limit further performance

growth due to overwhelming electricity bills and carbon dioxide footprints.

Therefore,the goal of the computer system design has been shifted to power

and energy efficiency.To identify open challenges in the area and facilitate future

advancements,it is essential to synthesize and classify the research on power-and

energy-efficient design conducted to date.In this study,we discuss causes and

problems of high power/energy consumption,and present a taxonomy of energy-

efficient design of computing systems covering the hardware,operating system,

virtualization,and data center levels.We survey various key works in the area

and map them onto our taxonomy to guide future design and development efforts.

This chapter concludes with a discussion on advancements identified in

energy-efficient computing and our vision for future research directions.

1.Introduction (49)

2.Power and Energy Models (52)

2.1.Static and Dynamic Power Consumption (53)

2.2.Sources of Power Consumption (53)

2.3.Modeling Power Consumption (55)

3.Problems of High Power and Energy Consumption (57)

3.1.High Power Consumption (58)

3.2.High Energy Consumption (60)

4.Taxonomy of Power/Energy Management in Computing Systems (61)

5.Hardware and Firmware Level (65)

5.1.Dynamic Component Deactivation (65)

5.2.Dynamic Performance Scaling (67)

5.3.Advanced Configuration and Power Interface (69)

6.Operating System Level (70)

6.1.The On-Demand Governor(Linux Kernel) (70)

6.2.ECOsystem (73)

6.3.Nemesis OS (73)

6.4.The Illinois GRACE Project (74)

6.5.Linux/RK (75)

6.6.Coda and Odyssey (75)

6.7.PowerNap (76)

7.Virtualization Level (77)

7.1.Virtualization Technology Vendors (78)

7.2.Energy Management for Hypervisor-based VMs (80)

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS49

8.Data Center Level (81)

8.1.Implications of Cloud Computing (82)

8.2.Non-virtualized Systems (85)

8.3.Virtualized Systems (91)

9.Conclusions and Future Directions (100)

Acknowledgments (103)

References (108)

1.Introduction

The primary focus of designers of computing systems and the industry has been on the improvement of the system performance.According to this objective,the performance has been steadily growing driven by more efficient system design and increasing density of the components described by Moore’s law[1].Although the performance per watt ratio has been constantly rising,the total power drawn by computing systems is hardly decreasing.Oppositely,it has been increasing every year that can be illustrated by the estimated average power use across three classes of servers presented in Table I[2].If this trend continues,the cost of the energy consumed by a server during its lifetime will exceed the hardware cost[3]. The problem is even worse for large-scale compute infrastructures,such as clusters and data centers.It was estimated that in2006IT infrastructures in the United States consumed about61billion kWh for the total electricity cost about 4.5billion dollars[4].The estimated energy consumption is more than double from what was consumed by IT in2000.Moreover,under current efficiency trends,the energy consumption tends to double again by2011,resulting in7.4billion dollars annually.

Energy consumption is not only determined by hardware efficiency,but it is also dependent on the resource management system deployed on the infrastructure and the efficiency of applications running in the system.This interconnection of the energy consumption and different levels of computing systems can be seen in Fig.1.Energy efficiency impacts end-users in terms of resource usage costs,which are typically determined by the total cost of ownership(TCO)incurred by a resource provider. Higher power consumption results not only in boosted electricity bills but also in additional requirements to a cooling system and power delivery infrastructure,that is, uninterruptible power supplies(UPS),power distribution units(PDU),and so on. With the growth of computer components density,the cooling problem becomes crucial,as more heat has to be dissipated for a square meter.The problem is

especially important for 1U and blade servers.These types of servers are the most difficult to cool because of high density of the components,and thus lack of space for the air flow.Blade servers bring the advantage of more computational power in less rack space.For example,60blade servers can be installed into a standard 42U rack [5].However,such system requires more than 4000W to supply the resources and cooling system compared to the same rack filled by 1U servers consuming 2500W.Moreover,the peak power consumption tends to limit further performance improve-ments due to constraints of power distribution facilities.For example,to power a

T able I

E STIMATED A VERAGE P OWER C ONSUMPTION PER S ERVER C LASS (W/U)FROM 2000TO 2006[2]

Server class 2000200120022003200420052006Volume 186193200207213219225Mid-range 424457491524574625675High-end

5534

5832

6130

6428

6973

7651

8163

Users Brokers Enterprises

F I

G .1.Energy consumption at different levels in computing systems.

50 A.BELOGLAZOV ET AL.

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS51 server rack in a typical data center,it is necessary to provide about60A[6].Even if the cooling problem can be addressed for future systems,it is likely that delivering current in such data centers will reach the power delivery limits.

Apart from the overwhelming operating costs and the total cost of acquisition (TCA),another rising concern is the environmental impact in terms of carbon dioxide (CO2)emissions caused by high energy consumption.Therefore,the reduction of power and energy consumption has become a first-order objective in the design of modern computing systems.The roots of energy-efficient computing,or Green IT, practices can be traced back to1992,when the U.S.Environmental Protection Agency launched Energy Star,a voluntary labeling program which is designed to identify and promote energy-efficient products in order to reduce the greenhouse gas emissions. Computers and monitors were the first labeled products.This has led to the widespread adoption of the sleep mode in electronic devices.At that time,the term“green computing”was introduced to refer to energy-efficient personal computers[7].At the same time,the Swedish confederation of professional employees has developed the TCO certification program—a series of end-user and environmental requirements for IT equipment including video adapters,monitors,keyboards,computers,peripherals, IT systems,and even mobile https://www.360docs.net/doc/a014714037.html,ter,this program has been extended to include requirements on ergonomics,magnetic and electrical field emission levels,energy consumption,noise level,and use of hazardous compounds in hardware.The Energy Star program was revised in October2006to include stricter efficiency requirements for computer equipment,along with a tiered ranking system for approved products. There are a number of industry initiatives aiming at the development of standardized methods and techniques for the reduction of the energy consumption in computer environments.They include Climate Savers Computing Initiative(CSCI),Green Computing Impact Organization,Inc.(GCIO),Green Electronics Council,The Green Grid,International Professional Practice Partnership(IP3),with membership of com-panies such as AMD,Dell,HP,IBM,Intel,Microsoft,Sun Microsystems,and VMware. Energy-efficient resource management has been first introduced in the context of battery-powered mobile devices,where energy consumption has to be reduced in order to improve the battery lifetime.Although techniques developed for mobile devices can be applied or adapted for servers and data centers,this kind of systems requires specific methods.In this chapter,we discuss ways to reduce power and energy consumption in computing systems,as well as recent research works that deal with power and energy efficiency at the hardware and firmware,operating system(OS),virtualization,and data center levels.The main objective of this work is to give an overview of the recent research advancements in energy-efficient computing,identify common characteris-tics,and classify the approaches.On the other hand,the aim is to show the level of development in the area and discuss open research challenges and direction for future work.The reminder of this chapter is organized as follows:in the next section,power

52 A.BELOGLAZOV ET AL.

and energy models are introduced;in Section3,we discuss problems caused by high power and energy consumption;in Sections4–8,we present the taxonomy and survey of the research in energy-efficient design of computing systems,followed by a conclusion and directions for future work in Section9.

2.Power and Energy Models

To understand power and energy management mechanisms,it is essential to clarify the terminology.Electric current is the flow of electric charge measured in amperes. Amperes define the amount of electric charge transferred by a circuit per second. Power and energy can be defined in terms of work that a system performs.Power is the rate at which the system performs the work,while energy is the total amount of work performed over a period of time.Power and energy are measured in watts(W) and watt-hour(Wh),respectively.Work is done at the rate of1W when1A is transferred through a potential difference of1V.A kilowatt-hour(kWh)is the amount of energy equivalent to a power of1kW(1000W)being applied for one hour.Formally,power and energy can be defined as in(1)and(2):

W;e1T

P?

E?PT;e2Twhere P is power,T is a period of time,W is the total work performed during that period of time,and E is energy.The difference between power and energy is very important because a reduction of the power consumption does not always reduce the consumed energy.For example,the power consumption can be decreased by lowering the CPU performance.However,in this case,a program may require longer time to complete its execution consuming the same amount of energy.On one hand,a reduction of the peak power consumption results in decreased costs of the infrastructure provisioning,such as costs associated with capacities of UPS,PDU,power generators,cooling system, and power distribution equipment.On the other hand,decreased energy consumption leads to a reduction of the electricity bills.The energy consumption can be reduced temporarily using dynamic power management(DPM)techniques or permanently applying static power management(SPM).DPM utilizes the knowledge of the real-time resource usage and application workloads to optimize the energy consumption. However,it does not necessarily decrease the peak power consumption.In contrast, SPM includes the usage of highly efficient hardware equipment,such as CPUs,disk storage,network devices,UPS,and power supplies.These structural changes usually reduce both the energy and peak power consumption.

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS53

2.1Static and Dynamic Power Consumption

The main power consumption in complementary metal-oxide-semiconductor (CMOS)circuits comprises static and dynamic power.The static power consumption, or leakage power,is caused by leakage currents that are present in any active circuit, independently of clock rates and usage scenarios.This static power is mainly deter-mined by the type of transistors and process technology.The reduction of the static power requires improvements of the low-level system design;therefore,it is not in the focus of this chapter.More details regarding possible ways to improve the energy efficiency at this level can be found in the survey by Venkatachalam and Franz[8]. Dynamic power consumption is created by circuit activity(i.e.,transistor switches,changes of values in registers,etc.)and depends mainly on a specific usage scenario,clock rates,and I/O activity.The sources of the dynamic power consumption are short-circuit current and switched capacitance.Short-circuit cur-rent causes only10–15%of the total power consumption and so far no way has been found to reduce this value without compromising the performance.Switched capac-itance is the primary source of the dynamic power consumption;therefore,the dynamic power consumption can be defined as in(3):

P dynamic?aCV2f;e3Twhere a is the switching activity,C is the physical capacitance,V is the supply voltage,and f is the clock frequency.The values of switching activity and capaci-tance are determined by the low-level system design.Whereas the combined reduction of the supply voltage and clock frequency lies in the roots of the widely adopted DPM technique called dynamic voltage and frequency scaling(DVFS).The main idea of this technique is to intentionally downscale the CPU performance, when it is not fully utilized,by decreasing the voltage and frequency of the CPU that in the ideal case should result in a cubic reduction of the dynamic power consump-tion.DVFS is supported by most modern CPUs including mobile,desktop,and server systems.We will discuss this technique in detail in Section5.2.1.

2.2Sources of Power Consumption

According to data provided by Intel Labs[5],the main part of power consumed by a server is accounted for the CPU,followed by the memory and losses due to the power supply inefficiency(Fig.2).The data show that the CPU no longer dominates power consumption by a server.This resulted from the continuous improvement of the CPU power efficiency and application of power-saving techniques(e.g.,DVFS) that enable active low-power modes.In these modes,a CPU consumes a fraction of the total power,while preserving the ability to execute programs.As a result,current

desktop and server CPUs can consume less than 30%of their peak power in low-activity modes,leading to dynamic power range of more than 70%of the peak power

[9].In contrast,dynamic power ranges of all other server’s components are much narrower:less than 50%for dynamic random access memory (DRAM),25%for disk drives,15%for network switches,and negligible for other components [10].The reason is that only the CPU supports active low-power modes,whereas other components can only be completely or partially switched off.However,the perfor-mance overhead of a transition between active and inactive modes is substantial.For example,a disk drive in a spun-down,deep-sleep mode consumes almost no power,but a transition to active mode incurs a latency that is 1000times higher than the regular access latency.Power inefficiency of the server’s components in the idle state leads to a narrow overall dynamic power range of 30%.This means that even if a server is completely idle,it will still consume more than 70%of its peak power.Another reason for the reduction of the fraction of power consumed by the CPU relatively to the whole system is the adoption of multi-core architectures.Multi-core processors are much more efficient than conventional single-core processors.For exam-ple,servers built with recent Quad-core Intel Xeon processor can deliver 1.8teraflops at the peak performance,using less than 10kW of power.To compare with,Pentium processors in 1998would consume about 800kW to achieve the same performance [5].The adoption of multi-core CPUs along with the increasing use of virtualization technologies and data-intensive applications resulted in the growing amount of memory in servers.In contrast to the CPU,DRAM has a narrower dynamic power range and power consumption by memory chips is increasing.Memory is packaged in dual in-line memory modules (DIMMs),and power consumption by these modules varies from 5to 21W per DIMM,for DDR3and fully buffered DIMM (FB-DIMM)

PCI Slots

(25W ×2)Memory

(8W ×8)CPU quadcore

Motherboard

Disk (12W ×1)

Fan (10W ×1)

NIC (4W ×1)

PSU Efficiency Loss F IG .2.Power consumption by server’s components [5].

54 A.BELOGLAZOV ET AL.

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS55 memory technologies[5].Power consumption by a server with eight1G

B DIMMs is about80W.Modern large servers currently use32or64DIMMs that leads to power consumption by memory higher than by CPUs.Most of the power management techniques are focused on the CPU;however,the constantly increasing frequency and capacity of memory chips raise the cooling requirements apart from the problem of high energy consumption.These facts make memory one of the most important server components that have to be efficiently managed.New techniques and approaches to the reduction of the memory power consumption have to be developed in order to address this problem.

Power supplies transform alternating current(AC)into direct current(DC)to feed server’s components.This transformation leads to significant power losses due to the inefficiency of the current technology.The efficiency of power supplies depends on their load.They achieve the highest efficiency at loads within the range of50–75%. However,most data centers normally create a load of10–15%wasting the majority of the consumed electricity and leading to the average power losses of60–80%[5].As a result,power supplies consume at least2%of the US electricity production.More efficient power supply design can save more than a half of the energy consumption. The problem of the low average utilization also applies to disk storages,especially when disks are attached to servers in a data center.However,this can be addressed by moving the disks to an external centralized storage array.Nevertheless,intelligent policies have to be used to efficiently manage a storage system containing thousands of disks.This creates another direction for the research work aimed at the optimiza-tion of the resource,power,and energy usage in server farms and data centers.

2.3Modeling Power Consumption

To develop new policies for DPM and understand their impact,it is necessary to create a model of dynamic power consumption.Such a model has to be able to predict the actual value of the power consumption by a system based on some run-time system characteristics.One of the ways to accomplish this is to utilize power monitoring capabilities that are built-in modern computer servers.This instrument provides the ability to monitor power usage of a server in real time and collect accurate statistics of the power usage.Based on this data,it is possible to derive a power consumption model for a particular system.However,this approach is complex and requires the collection of statistical data for each target system.

Fan et al.[10]have found a strong relationship between the CPU utilization and total power consumption by a server.The idea behind the proposed model is that the power consumption by a server grows linearly with the growth of the CPU utilization from the value of the power consumption in the idle state up to the power consumed when the server is fully utilized.This relationship can be expressed as in(4):

P eu T?P idle teP busy àP idle T?u ;e4T

where P is the estimated power consumption,P idle is the power consumption by an idle server,P busy is the power consumed by the server when it is fully utilized,and u is the current CPU utilization.The authors have also proposed an empirical non-linear model given in (5):

P eu T?P idle teP busy àP idle Te2u àu r T;e5T

where r is a calibration parameter that minimizes the square error and has to be obtained experimentally.For each class of machines of interest,a set of calibration experiments must be performed to fine tune the model.

Extensive experiments on several thousands of nodes under different types of workloads (Fig.3)have shown that the derived models accurately predict the power consumption by server systems with the error below 5%for the linear model and 1%for the empirical model.The calibration parameter r has been set to 1.4for the presented results.These precise results can be explained by the fact that the CPU is the main power consumer in servers and,in contrast to the CPU,other system components (e.g.,I/O,memory)have narrow dynamic power ranges or their activities correlate with the CPU activity .For example,current server processors can reduce power consumption up to 70%by switching to low-power-performance modes

[9].

S y s t e m p o w e r P P CPU utilization

F I

G .3.Power consumption to CPU utilization relationship [10].56 A.BELOGLAZOV ET AL.

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS57 However,dynamic power ranges of other components are much narrower:<50%for DRAM,25%for disk drives,and15%for network switches.

This accurate and simple power model enables easy prediction of the power consumption by a server supplied with CPU utilization data and power consumption values at the idle and maximum CPU utilization states.Therefore,it is especially important that the increasing number of server manufactures publish actual power consumption figures for their systems at different utilization levels[11].This is driven by the adoption of the ASHRAE Thermal Guideline[12]that recommends providing power ratings for the minimum,typical and full CPU utilization. Dhiman et al.[13]have found that although regression models based on just CPU utilization are able to provide reasonable prediction accuracy for CPU-intensive workloads,they tend to be considerably inaccurate for prediction of power consump-tion caused by I/O-and memory-intensive applications.The authors have proposed a power modeling methodology based on Gaussian mixture models that predicts power consumption by a physical machine running multiple virtual machine(VM)instances. To perform predictions,in addition to the CPU utilization,the model relies on run-time workload characteristics such as the number of instructions per cycle(IPC)and the number of memory accesses per cycle(MPC).The proposed approach requires a training phase to perceive the relationship between the workload metrics and the power consumption.The authors have evaluated the proposed model via experimental studies involving different workload types.The obtained experimental results have shown that the model predicts the power consumption with high accuracy(<10% prediction error),which is consistent over all the tested workloads.The proposed model outperforms regression models by a factor of5for specific workload types. This proves the importance of architectural metrics like IPC and MPC as compliments to the CPU utilization for the power consumption prediction.

3.Problems of High Power and Energy

Consumption

The energy consumption by computing facilities raises various monetary, environmental,and system performance concerns.A recent study on the power consumption of server farms[2]has shown that in2005the electricity use by servers worldwide—including their associated cooling and auxiliary equipment—costed7.2billion dollars.The study also indicates that the electricity consumption in that year had doubled compared to the consumption in2000.Clearly,there are environmental issues with the generation of electricity.The number of transistors integrated into today’s Intel Itanium2processor reaches nearly1billion.If this rate

58 A.BELOGLAZOV ET AL.

continues,the heat(per cm2)produced by future processors would exceed that of the surface of the Sun[14],resulting in poor system performance.The scope of energy-efficient design is not limited to main computing components(e.g.,processors,storage devices,and visualization facilities),but it can expand into a much larger range of resources associated with computing facilities including auxiliary equipments,water used for cooling,and even physical/floor space occupied by these resources.

While recent advances in hardware technologies including low-power processors, solid state drives,and energy-efficient monitors have alleviated the energy con-sumption issue to a certain degree,a series of software approaches have significantly contributed to the improvement of energy efficiency.These two approaches(hard-ware and software)should be seen as complementary rather than https://www.360docs.net/doc/a014714037.html,er awareness is another non-negligible factor that should be taken into account when discussing Green https://www.360docs.net/doc/a014714037.html,er awareness and behavior in general considerably affect computing workload and resource usage patterns;this in turn has a direct relation-ship with the energy consumption of not only core computing resources but also auxiliary equipment such as cooling/air conditioning systems.For example,a com-puter program developed without paying much attention to its energy efficiency may lead to excessive energy consumption and may contribute to higher heat emission resulting in increases in the energy consumption for cooling.

Traditionally,power-and energy-efficient resource management techniques have been applied to mobile devices.It was dictated by the fact that such devices are usually battery-powered,and it is essential to apply power and energy management to improve their lifetime.However,due to the continuous growth of the power and energy consumption by servers and data centers,the focus of power and energy management techniques has been switched to these systems.Even though the problems caused by high power and energy consumption are interconnected,they have their specifics and have to be considered separately.The difference is that the peak power consumption determines the cost of the infrastructure required to maintain the system’s operation,whereas the energy consumption accounts for electricity bills.Let us discuss each of these problems in detail.

3.1High Power Consumption

The main reason of the power inefficiency in data centers is low average utilization of the resources.To show this,we have analyzed the data provided as a part of the CoMon project,1a monitoring infrastructure for PlanetLab.2We have used the data of 1https://www.360docs.net/doc/a014714037.html,/

2https://www.360docs.net/doc/a014714037.html,/

the CPU utilization by more than a thousand servers located at more than 500places around the world.The data have been collected in 5minute intervals during the period from 10to 19May 2010.The distribution of the data over the mentioned 10days along with the characteristics of the distribution are presented in Fig.4.The data confirm the observation made by Barroso and Holzle [9]:the average CPU utilization is below 50%.The mean value of the CPU utilization is 36.44%with 95%confidence interval from 36.40%to 36.47%.The main run-time reasons of underutilization in data centers are variability of the workload and statistical effects.Modern service applica-tions cannot be kept on fully utilized servers,as even non-significant workload fluctuation will lead to performance degradation and failing to provide the expected quality of service (QoS).However,servers in a non-virtualized data center are unlikely to be completely idle because of background tasks (e.g.,incremental backups),or distributed data bases or file systems.Data distribution helps to tackle load-balancing problem and improves fault tolerance.Furthermore,despite the fact that the resources have to be provisioned to handle theoretical peak loads,it is very unlikely that all the servers of a large-scale data centers will be fully utilized simultaneously.

Systems where average utilization of resources less than 50%represent huge inefficiency,as most of the time only a half of the resources are actually in use.Although the resources on average are utilized by less than 50%,the infrastructure

CPU utilization First quartile Median Third quartile Maximum 36.40121.00036.743

A -squared

P -value

Mean

SD

Variance

Skewness

Kurtosis

N

Minimum Anderson–Darling normality test

95% confidence interval for mean 95% confidence interval for median 95% confidence interval for SD 21.000

64.000

5.000

0.000

100.000

36.471

21.000

36.79236.43636.7671351.8390.745091-0.9951804270388290412.05< 0.005F IG .4.The CPU utilization of more than 1000PlanetLab nodes over a period of 10days.

A TAXONOMY AND SURVEY OF ENERGY -EFFICIENT DATA CENTERS 59

60 A.BELOGLAZOV ET AL.

has to be built to handle the peak load,which rarely occurs in practice.In such systems,the cost of over-provisioned capacity is very significant and includes expenses on extra capacity of cooling systems,PDU,generators,power delivery facilities,UPS,and so on.The less the average resource utilization in a data center,the more expensive the data center becomes as a part of the TCO,as it has to support peak loads and meet the requirements to the peak power consumption[10].Moreover,the peak power consumption can constrain further growth of power density,as power requirements already reach60A for a server rack[6].If this tendency continues, further performance improvements can be bounded by the power delivery capabilities. Another problem of high power consumption and increasing density of server’s components(i.e.,1U,blade servers)is the heat dissipation.Much of the electrical power consumed by computing resources gets turned into heat.The amount of heat produced by an integrated circuit depends on how efficient the component’s design is,and the voltage and frequency at which the component operates.The heat generated by the resources has to be dissipated to keep them within their safe thermal state.Overheating of the components can lead to a decrease of their lifetime and high error-proneness.Moreover,power is required to feed the cooling system operation.For each watt of power consumed by computing resources,an additional 0.5–1W is required for the cooling system[6].For example,to dissipate1W consumed by a high-performance computing(HPC)system at the Lawrence Liver-more National Laboratory(LLNL),0.7W of additional power is needed for the cooling system[15].Moreover,modern high-density servers,such as1U and blade servers,further complicate cooling because of the lack of space for airflow within the packages.These facts justify the significant concern about the efficiency and real-time adaptation of the cooling system operation.

3.2High Energy Consumption

The way to address high power consumption is the minimization of the peak power required to feed a completely utilized system.In contrast,the energy con-sumption is defined by the average power consumption over a period of time. Therefore,the actual energy consumption by a data center does not affect the cost of the infrastructure.However,it is reflected in the cost of electricity consumed by the system,which is the main component of data center operating costs.Further-more,in most data centers,50%of consumed energy never reaches the computing resources:it is consumed by the cooling facilities or dissipated in conversions within the UPS and PDU systems.With the current tendency of continuously growing energy consumption and costs associated with it,the point when operating costs

exceed the cost of computing resources themselves in few years can be reached soon.Therefore,it is crucial to develop and apply energy-efficient resource man-agement strategies in data centers.

Except for high operating costs,another problem caused by the growing energy consumption is high CO 2emissions,which contribute to the global warming.According to Gartner [16]in 2007,the Information and Communications Techno-logy (ICT)industry was responsible for about 2%of global CO 2emissions,which is equivalent to the aviation.According to the estimation by the U.S.Environmental Protection Agency (EPA),current efficiency trends lead to the increase of annual CO 2emissions from 42.8million metric tons (MMTCO 2)in 2007to 67.9MMTCO 2in 2011.Intense media coverage has raised the awareness of people around the climate change and greenhouse effect.More and more customers start to consider the “green”aspect in selecting products and services.Besides the environmental concern,businesses have begun to face risks caused by being non-environment friendly.The reduction of CO 2footprints is an important problem that has to be addressed in order to facilitate further advancements in computing systems.

4.Taxonomy of Power/Energy Management in

Computing Systems

A large volume of research has been done in the area of power and energy-efficient resource management in computing systems.As power and energy management techniques are closely connected,from this point we will refer to them as power management.As shown in Fig.5,the high-level power management techniques can be divided into static and dynamic.From the hardware point of view,

Power management techniques

Static power management (SPM)Dynamic power management (DPM)

Hardware level Architectural level Single server OS level Virtualization level

Multiple servers, data

centers, and Clouds

Circuit level Logic level Hardware level Software level Software level

F I

G .5.High-level taxonomy of power and energy management.A TAXONOMY AND SURVEY OF ENERGY -EFFICIENT DATA CENTERS 61

62 A.BELOGLAZOV ET AL.

SPM contains all the optimization methods that are applied at the design time at the circuit,logic,architectural,and system levels[17].Circuit level optimizations are focused on the reduction of the switching activity power of individual logic gates and transistor level combinational circuits by the application of a complex gate design and transistor sizing.Optimizations at the logic level are aimed at the switching activity power of logic-level combinational and sequential circuits.Archi-tecture level methods include the analysis of the system design and subsequent incorporation of power optimization techniques in it.In other words,this kind of optimization refers to the process of efficient mapping of a high-level problem specification onto a register-transfer level design.Apart from the optimization of the hardware-level system design,it is extremely important to carefully consider the implementation of programs that are supposed to run in the system.Even with perfectly designed hardware,poor software design can lead to dramatic performance and power losses.However,it is impractical or impossible to analyze power consumption caused by large programs at the operator level,as not only the process of compilation or code generation but also the order of instructions can have an impact on power consumption.Therefore,indirect estimation methods can be applied.For example,it has been shown that faster code almost always implies lower energy consumption[18].Nevertheless,methods for guaranteed synthesizing of optimal algorithms are not available,and this is a very difficult research problem. This chapter focuses on DPM techniques that include methods and strategies for run-time adaptation of a system’s behavior according to current resource require-ments or any other dynamic characteristic of the system’s state.The major assump-tion enabling DPM is that systems experience variable workloads during their operation allowing the dynamic adjustment of power states according to current performance requirements.The second assumption is that the workload can be predicted to a certain degree.As shown in Fig.6,DPM techniques can be distin-guished by the level at which they are applied:hardware or software.Hardware DPM varies for different hardware components,but usually can be classified as dynamic performance scaling(DPS),such as DVFS,and partial or complete dynamic component deactivation(DCD)during periods of inactivity.In contrast, software DPM techniques utilize interface to the system’s power management and according to their policies apply hardware DPM.The introduction of the Advanced Power Management(APM)3and its successor,the Advanced Configuration and Power Interface(ACPI),4has drastically simplified the software power management and resulted in broad research studies in this area.The problem of power-efficient 3https://www.360docs.net/doc/a014714037.html,/wiki/Advanced_power_management

4https://www.360docs.net/doc/a014714037.html,/

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS63

F IG.6.DPM techniques applied at the hardware and firmware levels.

resource management has been investigated in different contexts of device-specific management,OS-level management of virtualized and non-virtualized servers,fol-lowed by multiple-node system such as homogeneous and heterogeneous clusters, data centers,and Clouds.

DVFS creates a broad dynamic power range for the CPU enabling extremely low-power active modes.This flexibility has led to the wide adoption of this technique and appearance of many policies that scale CPU performance according to current requirements,while trying to minimize performance degradation[19].Subse-quently,these techniques have been extrapolated on multiple-server systems providing coordinated performance scaling across them[20].However,due to narrow overall dynamic power range of servers in a data center,it has been found beneficial to consolidate workload to a limited number of servers and switch off or put to sleep/hibernate state idle nodes[21].

Another technology that can improve the utilization of resources,and thus reduce the power consumption,is virtualization of computer resources.The virtualization technology allows one to create several VMs on a physical server and,therefore, reduce the amount of hardware in use and improve the utilization of resources.The concept originated with the IBM mainframe OSs of the1960s,but was commercia-lized for x86-compatible computers only in the1990s.Several commercial compa-nies and open-source projects now offer software packages to enable a transition to virtual computing.Intel Corporation and AMD have also built proprietary virtuali-zation enhancements to the x86instruction set into each of their CPU product lines to facilitate virtualized computing.Among the benefits of virtualization are improved fault and performance isolation between applications sharing the same computer node(a VM is viewed as a dedicated resource to the customer);the ability to relatively easily move VMs from one physical host to another using live or off-line migration;and support for hardware and software heterogeneity.The ability to reallocate VMs at run-time enables dynamic consolidation of the workload,as VMs

64 A.BELOGLAZOV ET AL.

can be moved to a minimal number of physical nodes,while idle nodes can be switched to power-saving modes.

Terminal servers have also been used in Green IT practices.When using terminal servers,users connect to a central server;all of the computing is done at the server level but the end-user experiences a dedicated computing resource.It is usually combined with thin clients,which use up to one-eighth the amount of energy of a normal workstation,resulting in a decrease of the energy consumption and costs. There has been an increase in the usage of terminal services with thin clients to create virtual laboratories.Examples of terminal server software include Terminal Services for Windows,the Aqua Connect Terminal Server for Mac,and the Linux Terminal Server Project(LTSP)for the Linux operating system.Thin clients possibly are going to gain a new wave of popularity with the adoption of the Software as a Service (SaaS)model,which is one of the kinds of Cloud computing[22],or Virtual Desktop Infrastructures(VDI)heavily promoted by virtualization software vendors.5 Traditionally,an organization purchases its own computing resources and deals with the maintenance and upgrades of the outdated hardware and software,resulting in additional expenses.The recently emerged Cloud computing paradigm[22] leverages virtualization technology and provides the ability to provision resources on-demand on a pay-as-you-go https://www.360docs.net/doc/a014714037.html,anizations can outsource their computa-tion needs to the Cloud,thereby eliminating the necessity to maintain own comput-ing infrastructure.Cloud computing naturally leads to power efficiency by providing the following characteristics:

l Economy of scale due to elimination of redundancies.

l Improved utilization of the resources.

l Location independence—VMs can be moved to a place where energy is cheaper.

l Scaling up/down and in/out—the resource usage can be adjusted to current requirements.

l Efficient resource management by the Cloud provider.

One of the important requirements for a Cloud computing environment is providing reliable QoS.It can be defined in terms of service level agreements (SLA)that describe such characteristics as minimal throughput,maximal response time,or latency delivered by the deployed system.Although modern virtualization

5VMware View(VMware VDI)Enterprise Virtual Desktop Management,https://www.360docs.net/doc/a014714037.html,/ products/view/;Citrix XenDesktop Desktop Virtualization,https://www.360docs.net/doc/a014714037.html,/virtualization/desktop/ xendesktop.html;Sun Virtual Desktop Infrastructure Software,https://www.360docs.net/doc/a014714037.html,/software/vdi/

A TAXONOMY AND SURVEY OF ENERGY-EFFICIENT DATA CENTERS65 technologies can ensure performance isolation between VMs sharing the same physical computing node,due to aggressive consolidation and variability of the workload,some VMs may not get the required amount of resource when requested.This leads to performance losses in terms of increased response times,timeouts,or failures in the worst case.Therefore,Cloud providers have to deal with the power-performance trade-off—minimization of the power consumption while meeting the QoS requirements. The following sections detail different levels of the presented taxonomy:in Section5,we discuss power optimization techniques that can be applied at the hardware level.We survey the approaches proposed for power management at the OS level in Section6,followed by the discussion of modern virtualization techno-logies and their impact on power-aware resource management in Section7,and the recent approaches applied at the data center level in Section8.

5.Hardware and Firmware Level

As shown in Fig.6,DPM techniques applied at the hardware and firmware level can be broadly divided into two categories:dynamic component deactivation(DCD) and dynamic performance scaling(DPS).DCD techniques are built upon the idea of the clock gating of parts of an electronic component or complete disabling during periods of inactivity.

The problem could be easily solved if transitions between power states would cause negligible power and performance overhead.However,transitions to low-power states usually lead to additional power consumption and delays caused by the reinitialization of the components.For example,if entering a low-power state requires shutdown of the power supply,returning to the active state will cause a delay consisting of turning on and stabilization of the power supply and clock,reinitializa-tion of the system,and restoring the context[23].In the case of non-negligible transitions,efficient power management turns into a difficult online optimization problem.A transition to low-power state is worthwhile only if the period of inactivity is longer than the aggregated delay of transitions from and into the active state,and the saved power is higher than the required to reinitialize the component.

5.1Dynamic Component Deactivation Computer components that do not support performance scaling and can only be deactivated require techniques that will leverage the workload variability and disable the component when it is idle.The problem is trivial in the case of a negligible transition overhead.However,in reality such transitions lead not only

66 A.BELOGLAZOV ET AL.

to delays,which can degrade performance of the system,but also to additional power draw.Therefore,to be effective,a transition has to be done only if the idle period is long enough to compensate the transition overhead.In most real-world systems,there is a limited or no knowledge of the future workload.Therefore,a prediction of an effective transition has to be done according to historical data or some system model.A large volume of research has been done to develop efficient methods to solve this problem[23,24].As shown in Fig.6,the proposed DCD techniques can be divided into predictive and stochastic.

Predictive techniques are based on the correlation between the past history of the system behavior and its near future.The efficiency of such techniques is highly dependent on the actual correlation between past and future events and the quality of tuning for a particular workload type.A non-ideal prediction can result in an over-or underprediction.An overprediction means that the actual idle period is shorter than the predicted,leading to a performance penalty.However,an underprediction means that the actual idle period is longer than the predicted.This case does not have any influence on the performance;however,it results in reduced energy savings.

Predictive techniques can be further split into static and adaptive.Static techni-ques utilize some threshold of a real-time execution parameter to make predictions of idle periods.The simplest policy is called fixed timeout.The idea is to define the length of time,after which a period of inactivity can be treated as long enough to do a transition to a low-power state.Activation of the component is initiated once the first request to a component is received.The policy has two advantages:it can be applied to any workload type,and over-and under-predictions can be controlled by adjusting the value of the timeout threshold.However,disadvantages are obvious: the policy requires adjustment of the threshold value for each workload,it always leads to a performance loss on the activation,and the energy consumed from the beginning of an idle period to the timeout is wasted.Two ways to overcome the drawbacks of the fixed timeout policy have been proposed:predictive shutdown and predictive wakeup.

Predictive shutdown policies address the problem of the missed opportunity to save energy within the timeout.These policies utilize the assumption that previous periods of inactivity are highly correlated with the nearest future.According to the analysis of the historical information,they predict the length of the next idle period before it actually begins.These policies are highly dependent on the actual workload and the strength of the correlation between past and future events.History-based predictors have been shown to be more efficient and less safe than timeouts[25]. Predictive wakeup techniques aim to eliminate the performance penalty on the activation.The transition to the active state is predicted based on the past history and performed before an actual user request[26].This technique increases the energy consumption but reduces performance losses on wakeups.

溶质的质量分数学案及检测

9—3溶质的质量分数（2）学案 例1：配制450g 质量分数为20%的稀硫酸，需用 98%浓硫酸多少毫升？（浓硫酸的密度1.84g/cm 3） 解：设需用98%浓硫酸的体积为V V ·98%·1.84 g/cm 3=450g ╳ 20% V=49.9mL 答：需用98%浓硫酸的体积为49.9mL 例2：某学生用36.5g 盐酸与一定量的水垢（主要成分是碳酸钙）恰好反应，产生了4.4g 二氧化碳气体，该盐酸溶质质量分数是多少？ 解：设参加反应的盐酸中溶质氯化氢的质量为X CaCO 3 + 2HCl === CaCl 2 + H 2O + CO 2↑ 73 44 X 4.4g X=7.3g 盐酸中溶质质量分数为： 答：该盐酸溶质质量分数为20% 73 X 4 4 4.4g = 7. 3g 36.5g ╳100%=20%

练习：下表是实验室所用盐酸试剂瓶上标签的部分内容，请仔细阅读后计算： （1） 欲配制14.6%的稀盐酸1000g ，需用这种盐 酸多少毫升？（计算结果精确到0.1） （2） 13g 锌与足量的稀盐酸充分反应，理论上可 制得氢气多少克？ 9—3溶质的质量分数（2）课堂检测 1、 用10mL 质量分数为98%的浓硫酸（密度为 1.84g/cm 3），稀释成质量分数为20%的稀硫酸 （密度为1.14 g/cm 3），应加多少毫升水？最后能得到稀硫酸多少毫升？ 2、配制300g 质量分数为10%的稀盐酸，需用质量分数为38%（密度为1.19g/cm 3 ）的浓盐酸和水各

多少毫升？

3、将一定质量的金属锌投入到63.7g 稀硫酸中，恰好完全反应，放出气体的质量与反应时间（t ）的关系如图所示。请你据此分析计算：反应结束后所得溶液中溶质的质量分数。 . . H 2 质量 （g 反应时间（t ）

战神的挑战2——图文流程攻略

战神的挑战2——图?流程攻略 【游戏封?】 游戏名称：P u z z l e Q u e s t2 中?名称：战神的挑战2 游戏发?：N a m c o N e t w o r k s A m e r i c a,I n c. 游戏制作：I n?n i t e I n t e r a c t i v e 游戏语种：英? 游戏类型：R P G??扮演 发??期：2010年8?13?

%{p a g e-b r e a k|游戏介绍|p a g e-b r e a k}% 野蛮?的技能表(括号中学得该技能所需的等级)： 连捶(1)：战场上有多少红宝?，则造成1/2数量的伤害值，需要4的红魔法。 部落的标记(2)：消掉战场上所有的红宝?，每4颗红宝?增加1点头?伤害奖励，该效果?直持续。 狂怒(3)：在战场上随机位置?成14颗红宝?。 部落的守护(4)：消掉战场上所有的绿宝?，没颗绿宝?增加2点防御，效果?直持续。 猛击(5)：减少敌?每种颜?的魔法值各10。 头?粉碎者(6)：消掉所有头?，敌?损失的回合数为1+1/5消掉的头?数。 野蛮咆哮(7)：敌?防御减少75%，持续3回合，本回合未结束。 破坏狂(8)：消掉所有的绿宝?，增加相等数量的红魔法。 反冲(10)：使?后该回合内通过武器攻击造成的伤害增加50%。 战争狂嚎(12)：随机位置增加3颗红?头?，如果当前红魔法值不少于25则本回合未结束。 最后的反击(15)：使?后每损失25点?命值增加1点头?伤害，该技能

践踏(20)：选择?颗宝?，消掉周边3*3区域的宝?并获得所有这些宝?的效果，对敌?造成8的伤害。 残暴(25)：在后6回合内使头?伤害加倍。 猎头者(30)：消掉最上2?的宝?，获得它们的效果。对敌?造成10的伤害。 嗜?(35)：接下来的6个回合，对敌?造成伤害值的25%转化为??的?命值。 毁灭者(40)：增加50点武器攻击点数，本回合未结束。 迷幻之怒(50)：选择?种宝?，战场上所有该颜?的宝?转变为头?，红魔法不少于25则本回合未结束。 战?的?些分析：消宝?增加该颜?魔法，六个?格为装备的武器，拳头形状表?武器攻击点数，消掉战场中的拳头增加该点数，满?武器使?需求后点击武器?格可以释放，图中我?3、3的数值分别标?了?前的头?伤害加成值和防御值，前者增加消掉头?后对敌?的伤害值，后者标?有该数值%的机会使任何敌?对我?造成的伤害减半。左下?为现在装备的五个技能，注意战?中只能装备五个所以需要在战?前在技能选项中先选择好最有利于战?的技能。 野蛮?战?的?些?得： 消4个或以上的宝?能奖励?个回合，单回合连续消掉?批宝?会有更多奖励(?如稀有武器)。 消宝?时注意看看消去后是否会给对?造成机会，如果没有什么好的

溶质的质量分数教学案(习题有答案)

【知识要点】一、溶质的质量分数 溶液的浓稀、有色溶液的颜色都可以粗略的表示一定量的溶液中含有溶质的多少，溶液中溶质的质量分数可以准确地表示一定量的溶液中含有溶质的多少。 1.定义：溶液中溶质的质量分数是溶质质量与溶液质量之比。 数学表达式： 特点：无单位、是个比值、一般不受温度的影响等。 饱和溶液溶质的质量分数的计算： （其中S为该温度下物质的溶解度） 2．配制溶质质量分数一定的溶液 以配制100g溶质质量分数为5%的氯化钠溶液为例分析： （1）计算：计算配制100g溶质质量分数为5%的氯化钠溶液所需氯化钠和水的质量。 （2）称量：用托盘天平称量所需的氯化钠。 （3）量取：用量筒量取所需的水（水的密度近似看作1g/cm3）。 （4）溶解：将量好的水倒入盛有称量好氯化钠的烧杯中，用玻璃棒搅拌，使氯化钠溶解。 （5）装瓶、贴签：把配制好的溶液装入试剂瓶中，盖好瓶塞并贴上标签，备用。 操作示意图可简单表示如下： 说明：如果用液体溶质来配制溶质质量分数一定的溶液，其步骤为：计算→量取→溶解→装瓶、贴签。想一想，这是为什么？ 二、关于溶质的质量分数的计算几种类型1．根据定义式的基本计算 （只要已知其中的两个量，就可以求出第三个量） 例如：20克硝酸钾完全溶解在60克水中，所得溶液中溶质的质量分数是多少？ 解：根据溶质的质量分数的定义可得 ＝＝25% 注意：饱和溶液溶质的质量分数的计算： （其中S为该温度下物质的溶解度） 2．溶液的稀释和浓缩问题的计算 根据稀释前后溶质的质量不变进行运算，无论是用水或用稀溶液来稀释浓溶液，都可计算。 （1）用水稀释浓溶液 设稀释前浓溶液的质量为m，其溶质的质量分数为a%，稀释时加入水的质量为n，稀释后溶质的质量分数为b%。则可得m×a%＝(m＋n)×b% （2）用稀溶液稀释浓溶液 设浓溶液的质量为A，其溶质的质量分数为a%，稀溶液的质量为B，其溶质的质量分数为b%，两溶液混合后所得溶液溶质的质量分数为c%。则可得A×a%＋B×b%=（A＋B）×c% （3）蒸发水进行浓缩 设浓缩前稀溶液的质量为m，其溶质的质量分数为a%，蒸发水的质量为n，浓缩后溶质的质量分数为b%。则可得m×a%＝(m-n)×b% 说明：如果采用加入溶质的方法使溶液中溶质的质量分数增大，那么可以根据：

《战神3》图文流程攻略Chapter 11 -奥林

《战神3》图文流程攻略Chapter 11 -奥林匹亚要塞 跟随赫尔墨斯的脚步，抵达木桥上，桥会被迎空飞来的火球砸断，并且背后会不断燃烧，被火追上便会坠崖而亡，中途桥会更改一起方向，不用搭理摇杆向上推一路按×注意面前的平民会阻挡你的道路，用攻击键杀死他们而不是圆圈，跨上平台，平台上有许多平民，抓住处决可以回血，他们的生杀大权就掌握在你的手中。 一路上连跑带揍也没能追上神使，不过最终这个罗嗦的家伙还是被逼在一个锁头上，去左边触发剧情，不用被赫尔墨斯所干扰，掌握自己的节奏一路上利用跳跃点抵达安全区域，上面拼命、小恶魔、狗仔龙蛇混杂，推荐使用太阳神的头颅△蓄力镇住他们，然后L ?清理。

接着向前走，赫尔墨斯把正门关了没办法，我们只能绕远路了，从门左边的楼梯左右开工跃上房顶，发现点赫尔墨斯已经跑到很远的地方等奎托斯了，无奈ing到圆台下方右侧拉动摇杆，腾出缺口跳上平台，拉动巨型投石车，利用QTE跟随巨石抵达赫尔墨斯所在的雅典娜巨像上，酷毙了～ 跟随赫尔墨斯的血迹到达与赫尔墨斯决战的平台，这家伙的速度非常快，天天跑路可不是 盖的，也许一开始会适应不来，用L ?来攻击命中率会比较大，或者直接重攻击的收尾重击的伤害非常大看准时机可以给予赫尔墨斯很大的伤害，途中会有QTE对抗，无外乎是正转或者是反转半圈摇杆，几下重击周后赫尔墨斯被击倒在地，显然他累了，这家伙临死之前还唧唧歪歪拿斯巴达人的荣耀来说事。

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2、引导分析，溶液的浓稀与溶液组成中的什么有关？ 交流讨论，得出结论，溶液的浓稀与溶质含量多少有关。 3、提出问题：溶液的浓稀与溶剂的量有关吗？能设计实验证明吗？多媒体展示实验内容：将1g 硫酸铜分别溶于5ml、10ml、15ml水中，判断溶液的浓稀。 引导思考，溶液的组成变化与溶液浓度之间的关系是怎样的？ 学生交流自己的设计方案。 根据实验现象得出结论：溶液的浓稀与溶剂的量有关，溶质相同时，溶剂越多，溶液越稀。 讨论小结： ①溶质质量增大，溶剂质量不变，则溶液质量变大，溶液会变浓。 ②溶质质量减少，溶剂质量不变，则溶液质量变小，溶液会变稀。 ③溶质质量不变，溶剂质量增大，则溶液质量变大，溶液会变稀。 ④溶质质量不变，溶剂质量减少，则溶液质量变小，溶液会变浓。 4、设问：对于有色溶液可以根据溶液的颜色来比较溶液的浓稀，如果无色溶液呢？ 学生思考困惑--- 讲述：要准确比较溶液的浓稀就必须准确知道一定量的溶液里究竟含有多少的溶质，即准确知道溶液的组成，表示溶液组成的方法很多，我们介绍溶质的质量分数。 板书：一、溶质的质量分数 （1）定义：溶液中溶质的质量分数是溶质质量与溶液质量之比

人教版初中英语单词全册(直接打印)

七年级上册英语单词表 Starter Unit 1 good /gud/ adj. 好的 morning /'m?:ni?/ n. 早晨；上午Good morning! 早上好！ hi /hai/ interj. (用于打招呼)嗨；喂 hello /h?'l?u/ interj. 你好；喂afternoon /,a:ft?'nu:n/ n. 下午Good afternoon! 下午好！ evening /'i:vni?/ n. 晚上；傍晚Good evening! 晚上好！ how /hau/ adv. 怎样；如何 are /a:/ v. 是 you /ju:/ pron. 你；你们 How are you 你好吗 I /ai/ pron. 我 am /?m/ v. 是 fine /fain/ adj. 健康的；美好的thanks /θ??ks/ interj.&n. 感谢；谢谢 OK /?u'kei/ interj.& adv. 好；可以 Starter Unit 2 what /w?t/ pron.&adj. 什么 is /iz/ v. 是 this /eis/ pron. 这；这个 in /in/ prep. (表示使用语言、材料等)用；以 English /'i?gli?/ n. 英语adj. 英格兰的；英语的 in English 用英语 map /m?p/ n. 地图 cup /k?p/ n. 杯子 ruler /'ru:l?/ n. 尺；直尺 pen /pen/ n. 笔；钢笔 orange /'?rind?/ n. 橙子 jacket /'d??kit/ n. 夹克衫；短上衣 key /ki:/ n. 钥匙 quilt /kwilt/ n. 被子；床罩

人教版化学九年级下册9.3《溶质的质量分数》word学案

一、学习目标 1．掌握溶液组成的表示方法——溶质的质量分数，会进行溶质质量分数的计算。 2．学会配制一定质量分数一定的溶液教学过程 二、课堂检测 1．判断题（正确打“√”，不正确打“×”） (1）在100 g水里加入20 g氯化钠，溶液中氯化钠的质量分数为20%（） (2)“10%的食盐溶液”表示100 g水中溶解了10 g食盐（） (3) 10 g硝酸钾完全溶解于90 kg水中，得到10%的硝酸钾溶液（） (4) 40 g 20％的NaCl溶液等分成四份，则每一份溶液中氯化钠的质量分数为5％（）2．在用固体氯化钠配制一定量一定溶质质量分数的氯化钠溶液的实验中，必须用到的一组仪器是（） A．托盘天平、药匙、烧杯、玻璃棒、酒精灯 B．量筒、烧杯、玻璃棒、药匙、酒精灯 C．量筒、托盘天平、玻璃棒、药匙、烧杯 D．烧杯、药匙、漏斗、玻璃棒 3．60℃时，硝酸钾的溶解度为110 g，该温度下硝酸钾饱和溶液中有关质量关系正确的是（） A．溶质质量∶溶剂质量＝1∶10B．溶剂质量∶溶液质量＝20∶21 C．溶质质量∶溶剂质量＝11∶10D．溶液质量∶溶质质量＝21∶10 4．浓溶液在用水稀释的过程中保持不变的是（） A．溶液质量B．溶液体积C．溶质质量D．溶质的质量分数 5.有40 g 5％的CaCl2溶液，若将其溶质质量分数增加到10％，应采用的方法是（）A．加入40 g 15％的CaCl2溶液B．把溶液倾倒一半 C．加入2 g CaCl2固体D．把溶剂蒸发掉20 g 6．配制一定溶质质量分数的氯化钠溶液的一些操作步骤见下图，正确的操作顺序是（）

A．④⑤①②③B．①②③④⑤ C．③④①②⑤D．②①④③⑤ 7．预防“非典”（SARS），家庭、学校经常使用过氧乙酸（CH3COOOH）作消毒剂，它是一种具有腐蚀性、强烈刺激性气味的无色液体，易分解产生氧气，有杀菌、漂白作用。它的相对分子质量是。市售过氧乙酸溶液的质量分数为20％，若要配制0.1％的该消毒液2 000 g，需20%的过氧乙酸溶液质量为。 8．20 ℃时将60 g NaCl放入150 g水中，充分搅拌，求所得溶液中溶质的质量分数。（20 ℃时NaCl的溶解度为36 g）

九年级全一册人教版初中英语单词表

Unit 1 flashcard/’fl?????????/ n. (有单词或图画的)抽认卡vocabulary/v?’k?bj?l?r?/n. 词汇 aloud /?’la?d/adv. 出声地，大声地pronunciation /pr?,n?ns?’e???n/ n. 发音，发音法 specific /sp?’s?f?k/ adj. 明确的，具体的memorize /’mem?ra?z/ v. 记住，熟记 grammar /’gr?m?(r)/ n. 语法，语法规则differently /’d?f?r?ntl?/ adv. 不同地，有区别地frustrate /’fr?stre?t/ v. 使失望，使沮丧，使厌烦frustrating /’fr?stre?t??/ adj.令人失望，令人沮丧，令人厌烦quickly /’kw?kl?/adv.愉地，迅速地add /?d/ v. 补充，继续说pronounce /pr?’na?ns/ v. 发……音，正确吐字（音）spoken /’sk??k??/ adj. 口语的，口头 slowly/’sk??l?/adv.慢地，缓慢地mistake /m?’ste?k/ n. 错误，过失 make mistakes 犯错，出错comma /’k :m?/,/’k?m?/n. 逗号 challenge/’t?’?l?nd?/n. 挑战solution /s?’lu:??n/ n. 解决，解答 later on 以后，随后realize /’r??a?z/ v. 认识到了，了解到了matter/’m?t?(r)/ v. 重要，要紧，有关系 it doesn't matter 没关系 afraid /?’fre?d/ adj. 害怕的，犯愁的 be afraid to 害怕去做，不敢去做laugh at 嘲笑，取笑 complete/k?m’pli:t/ adj. 完整的，完全的 secret/’si:kr?t/ n. 秘诀；诀巧learner /’l :(r)n?r/ n. 学习者take notes n. 做笔记，做记录term/t :(r)m/v. 学期 impress /?m’press/ n. 使感动，使印象深刻trouble /’trb?l/ adv. 困难，苦恼，忧虑 fast /f?st/ 快地，迅速地 look up adj. （在词典或参考书中）查阅，查找 soft /s :ft/ 软的，柔软的 make up 编造，组成，拼凑成essay/’ese?/ 文章 deal /di:l/ v. 处理，应付 deal with处理，应付 unless/?n’les,?n’les/ conj. 如果不，除非 unfair /,?n’fer/ adj. 不公正的，不公平的 solve /s :lv/ v. 解决，解答 regard /r?’g :(r)d/v. 将……视为duty /’du:t?/ n. 责任，义务easily /’i:z?l?/adv. 容易地，简单地influence /’?nf??ns/ v. 影响，对……起作用