Do You Know the ABCs of Career Change?

Job seekers—if you are seeking to make a significant industry or occupational career change, your resume might be working against you. Read about the ABCs of Career Change and take the fast lane to a new career!

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Making a career change is one of the toughest job-search challenges. For clarification, “career change” means much more than “job change.” A career change means choosing a completely new profession or industry. A “job change” is simply changing employers within the same industry and profession.

Why do people change careers? The two main reasons are:

* The industry or occupation becomes obsolete (or is outsourced overseas)

* Job dissatisfaction (If you dread going to work on Monday morning, you’re probably in this category.)

What makes a career change so difficult? After all, most job seekers attempting a career change know exactly why they would do well in a new profession or industry. The problem comes down to communication. Most job seekers have difficulty communicating in their resume their ability to excel in a new career. Resumes, by definition, focus on career experience (history), but career changers need employers to see their expertise (current skills) in order to be viewed as a viable candidate.

If you are attempting a career change, it becomes easier when you understand the ABC’s of career change:

A: Assess

B: Bridge

C: Communicate

Assess what you want changed.

Before you can make a successful change, you must decide what needs changing. Is it the duties you perform? Your overbearing boss? Your current geographic location? The industry you work in? The size of company you work for? The level of responsibility you hold? Once you pinpoint your exact source of unhappiness, you’re on your way to making the correct choice for change.

Bridge the gap between what you’ve done and what you want to do.

The key to selling yourself based on your expertise rather than your experience is transferable skills. Transferable skills work like bridges to help you cross over from one industry to another or one occupation to another. Transferable skills are those skills you now possess that qualify you as a viable candidate for your career change.

Communicate your ability to excel in your new profession or industry.

Your resume is your front-line communication tool to prospective employers. No matter how well you interview, if your resume doesn’t sell you, there won’t be an opportunity to convince them in person. Use your accomplishments to prove the strength of your transferable skills, and you’ll get interviews faster and with more enthusiasm.

An experienced career coach can help you apply these ABCs to your current resume and your interview skills. Once you practice the ABCs of career change you’ll be on your way to changing your career and changing your life-for the better!

What is the Working of a Bridge Rectifier?

Before we get into the core of working of a bridge rectifier, let us understand what a rectifier is. A rectifier is an electrical circuit that turns an alternating current voltage input into a direct current voltage at the output terminal. In regular parlance, AC voltage is converted into DC voltage by a rectifier. The rectified output voltage is the name given to this output. Rectifiers are primarily used in power supplies, supplying DC voltage to electronic equipment.

Electronic circuits primarily need rectifiers to power electronic components, whereas DC powering happens from the available AC mains supply. Of the rectifiers, bridge rectifiers are known to be the most effective circuits. They fall under the full-wave rectifier category. In the ensuing sections, let us learn more about the working of bridge rectifiers. Besides, the bridge rectifier circuit diagram is also made available for better understanding through an illustration. The article also clearly covers the characteristics of the full-wave bridge rectifier.

So, rectifiers are primarily classified into two categories, based on their operation-

Half Wave Rectifiers
Full-Wave Rectifiers
Full-wave rectifiers are more effective than half-wave rectifiers in increasing the efficiency of the rectification. Full-wave rectifiers generate an output voltage by using both positive and negative half cycles of the input voltage.

Full-wave rectifiers are in turn classified into two types:
Bridge full-wave Rectifier
Centre tap full-wave rectifier
Let us know more about full-wave bridge rectifiers before we attempt to get deeper into learning about bridge rectifiers.

A full wave rectifier is a rectifier that transforms both halves of each alternating wave cycle (alternating current) into a pulsing DC (direct current) signal.

Full-wave rectifiers are used for a smoother and more consistent supply of power. Full-wave rectifiers are used to convert a whole cycle of alternating current voltage (AC) to direct current voltage (DC).

The differentiation between these two types of full-wave rectifiers goes a long way in understanding effectively the full-wave rectifier working

In a center-tapped full-wave rectifier, the system is made up of a center-tapped transformer, two diodes, and a resistive load. Whereas, under a full-wave bridge rectifier, the architecture features four diodes or more, and the resistive load. The diodes are named A, B, C and D, and form a bridge circuit.

A bridge rectifier is a full-wave rectifier that use four diodes to create a close-loop bridge. The diodes operate in pairs during each positive and negative half cycle, resulting in no power waste.

A bridge rectifier does not require a center tap over the transformer’s secondary winding. The input is sent through a transformer to the diode bridge’s diagonal. Unlike the center tap rectifier, which consumes 50% of the transformer, the transformer in this circuit is constantly busy since it delivers power during both cycles of input AC.

Working of Bridge Rectifier
Typically, a bridge rectifier works as follows:
As soon as an AC signal is sent through the bridge rectifier, terminal A turns positive during the positive half cycle, while terminal B changes to negative. Thus, two diodes, D1 and D3 turn into forward bias, while the other two, D2 and D4 operate in reverse bias.

In the case of a negative half-cycle, terminal B transforms into a positive one while terminal A is now negative. In this case, the diodes, D2 and D4 change to forward bias, whereas the diodes, D1 and D3 are now reverse biased.

Thus, a bridge rectifier enables the flow of the electric current during positive as well as negative half cycles of the input AC signal.

Bridge Rectifier Formulae and Characteristics of Bridge Rectifier
Let us understand the characteristics of a bridge rectifier based on the following aspects:

Ripple Factor
The ripple factor is a factor that measures the smoothness of the output DC signal. The output DC with more occasional ripples is referred to as a smooth DC signal, whereas if the output is with more ripples, it is a high-pulsating DC signal. The ripple factor mathematically is defined as the ratio of ripple voltage to pure DC voltage.

Peak Inverse Voltage
A peak inverse voltage is the greatest voltage that a diode can endure when biased in reverse. The diodes D1 and D3 are conducted during the positive half cycle, whereas D2 and D4 are not. Similarly, during the negative half cycle, diodes D2 and D4 current whereas diodes D1 and D3 do not.

Efficiency

The efficiency of a rectifier influences how well it converts Alternating Current (AC) into Direct Current (DC).

Pros and Cons of Bridge Rectifier
Advantages of Full Wave Bridge Rectifier
The efficiency of a bridge rectifier is greater than that of a half-wave rectifier. The rectifier efficiency of the bridge rectifier and the center-tapped full-wave rectifier, on the other hand, is the same.
The bridge rectifier’s DC output signal is smoother than the DC output signal of a half-wave rectifier.
A half-wave rectifier uses just half of the incoming AC signal and blocks the other half. A half-wave rectifier wastes half of the input signal. A bridge rectifier lets electricity flow through both the positive and negative halves. As a result, the output DC signal is almost equivalent to the input AC signal.
Disadvantages of Bridge Rectifier
A bridge rectifier’s circuit is more complicated than that of a half-wave rectifier or a center-tapped full-wave rectifier. Bridge rectifiers require four diodes, whereas half-wave and center-tapped full-wave rectifiers need just two.
As more diodes are utilized, more power is lost. Only one diode is conducted during each half cycle of a center-tapped full-wave rectifier. With a bridge rectifier, on the other hand, two diodes linked in series conduct throughout each half cycle. As a result, the voltage drop is larger with a bridge rectifier.
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VCAP-DCV Design 2024 3V0-21.23 Dumps – VMware vSphere 8.x Advanced Design

The 3V0-21.23 VMware vSphere 8.x Advanced Design exam is mandatory for the VCAP-DCV Design 2024 Certification. Passcert offers the latest VCAP-DCV Design 2024 3V0-21.23 Dumps to help you identify areas of strength and enhance your performance in the actual VMware 3V0-21.23 exam. We highly recommend practicing with our VCAP-DCV Design 2024 3V0-21.23 Dumps, as they include practical and real-time scenario-based questions similar to those you’ll encounter in the actual VMware 3V0-21.23 Certification exam, aiding in your successful completion of the exam.

3V0-21.23: VMware vSphere 8.x Advanced DesignThis exam tests a candidate’s ability to apply design principles to develop a vSphere 8.x conceptual design given a set of customer requirements, determine the business and technical requirements needed to create a logical design, and architect a physical design using these elements. The VMware vSphere 8.x Advanced Design exam (3V0-21.23) which leads to VMware Certified Advanced Professional – Data Center Virtualization Design 2024 (VCAP-DCV Design 2024) certification is a 60-item exam, with a passing score of 300 using a scaled method. Candidates are given an appointment time of 145 minutes, which includes adequate time to complete the exam for non-native English speakers. This exam contains scenario-based single-selection and multipleselection multiple-choice items.

Exam InformationExam 3V0-21.23: VMware vSphere 8.x Advanced DesignLanguage: EnglishNumber of Questions: 60 Format: Single and Multiple Choice, ProctoredDuration: 145 MinutesPassing Score: 300 (100-500)Pricing: $450 USDAssociated Certification: VCAP-DCV Design 2024

Exam SectionsSection 1 – IT Architectures, Technologies, StandardsSection 2 – VMware SolutionSection 3 – Plan and Design the VMware SolutionSection 4 – Install, Configure, Administrate the VMware SolutionSection 5 – Troubleshoot and Optimize the VMware Solution

Share VMware vSphere 8.x Advanced Design 3V0-21.23 Free Dumps1. An architect is redesigning a storage environment to provide simplified management of a VMware environment. The administrators have expressed the need to provision storage and apply a custom set of array features granularly to virtual machines. They will re-use their existing shared storage platform as it does support all modern VMware storage integrations.Which two technologies or features are needed to support the requirements of this project? (Choose two.)A. vStorage APIs for Storage Awareness (VASA)B. vSphere Virtual Volumes (vVols)C. Datastore ClustersD. vSphere Storage DRSE. Raw Device Mappings (RDMs)Answer: A, B 2. An application owner is concerned about their front-end web servers suffering an outage in the event of a host failure. Which functional requirement could the architect include in the application design to mitigate this concern?A. The platform must include configuration rules to separate the web servers.B. The platform must include configuration rules to restart the web servers upon host failure.C. The platform must be configured with resource scheduling in fully automated mode.D. The platform must include configuration rules to reset the web servers when guest heartbeats are not received.Answer: A

3. An architect is designing a solution for an environment with a limited number of operating system licenses. How should the architect design the virtual infrastructure to meet the operating system license requirements?A. Place the hosts into a single cluster and enable automated placement of virtual machines.B. Create rules to restrict placement of virtual machines to specified hosts.C. Create a resource pool and only put the virtual machines that need the operating system licenses within the pool.D. Use standalone ESXi hosts and only apply the operating system licenses to those hosts.Answer: B 4. An architect is assigned to report available capacity of a vSphere platform and is provided with the following:- Read-only access to the platform’s virtualization monitoring tool- Full access to an internally developed and manually updated Configuration Management Database (CMDB) tool- Access to a document repository containing the go-live design documentation for each application- Links to vendor best practice documentation for many of the deployed applications- Access to the company wide in-guest monitoring toolInformation extracted from which two sources will accurately provide the required information? (Choose two.)A. Virtualization monitoring toolsB. Application virtual machine design documentsC. In-guest monitoring toolsD. Application vendor best practice documentationE. Support organizations Configuration Management Database (CMDB) Answer: A, C 5. The DevOps team at an organization is preparing to build and package virtual machine (VM) images that will be added to a content library for a new vSphere environment. Users will deploy virtual machines from the content library.The solutions architect is gathering requirements to help the DevOps team decide between the use of VM templates versus Open Virtualization Format (OVF) templates in the content library.Which requirement would influence the design decision to use OVF templates in the content library?A. Templates must be able to support license agreement acceptance during deployment.B. Templates must be encrypted.C. vSphere Storage DRS must be supported.D. Templates must be automatically migrated to another ESXi host when a host is inaccessible.Answer: A 6. An architect is designing a solution for an environment that has an application consisting of five resource-intensive virtual machines. Which design recommendation should the architect make to avoid resource bottlenecks?A. Create a cluster with three hosts and only run the application virtual machines on this cluster.B. Create a cluster with six hosts and use automated placement rules to keep the application virtual machines together.C. Create a cluster with six hosts and use automated placement rules to keep the application virtual machines apart.D. Create a cluster with four hosts and use rules to prioritize the resources for the application virtual machines.Answer: C